1. CROSS-REFERENCE TO RELATED APPLICATIONS
This application claims the benefit of and priority to U.S. Provisional Application Nos. 63/091,816, filed Oct. 14, 2020; 63/221,334, filed Jul. 13, 2021; 63/221,358, filed Jul. 13, 2021; 63/221,364, filed Jul. 13, 2021; 63/221,366, filed Jul. 13, 2021; 63/221,367, filed Jul. 13, 2021; and 63/221,371, filed Jul. 13, 2021, the disclosures of which are hereby incorporated by reference in their entireties.
2. BACKGROUND
The metabolomes of plants, fungi and other prokaryotic and eukaryotic organisms contain bioactive molecules that can affect physiological and pathophysiological processes if introduced into living human and animal biological systems. Contemporary pharmacological discovery practices analyze these compounds by screening large repositories of thousands of individual compounds to observe putative biological effects, and outcomes in cell lines and model organisms and diseases. The screening and characterization of individual compounds is laborious and costly. Current biopharmaceutical research and development programs are highly inefficient at yielding newly approved drugs for government-regulated, prescription-based markets. Therefore, methods for increasing the efficiency of both drug discovery and the prediction of clinical efficacy of new disease-specific therapies from within contemporary natural product metabolomes are needed.
The bioactive molecules in the metabolomes of plants, fungi, and other prokaryotic and eukaryotic organisms have implicitly been used as the basis for traditional medicines (TM) that incorporate ethno medical beliefs and traditions specific to individual cultures, as well as traditional medical systems practiced in multiple locales. The World Health Organization (WHO) defines traditional medicine as “the sum total of the knowledge, skills, and practices based on the theories, beliefs, and experiences indigenous to different cultures, whether explicable or not, used in the maintenance of health as well as in the prevention, diagnosis, improvement or treatment of physical and mental illness” (World Health Organization, 2013). Each culture has its set of ethno medical beliefs and practices associated with health and illness, which shape diagnosis, treatment, and expected outcome.
Pathways for potentially efficacious medicines to move from contemporary and historical TM systems to government-regulated, prescription-based, medical systems are currently inadequate, relying on either (a) painstaking, high cost, compound-by-compound testing of TM pharmacopeias in pharmaceutical company-sponsored preclinical and clinical efficacy paradigms, or (b) on ‘rediscovery’ of components during high-throughput screening in academic or pharmaceutical industry research settings. Current pathways for medicines to move from TM systems to Western medicine are inefficient and unsatisfactory due to: (1) Over-simplification—the diminution of complex efficacious polypharmaceutical mixtures to a single component results in loss of synergies and interactions between components, and/or (2) Epistemology—TM formulations contain both efficacious bioactive components and chemicals for which the inclusion rationale is anachronistic or pseudoscientific, and these need to be differentiated. There is a need to identify the ‘Goldilocks’ formulation for a particular indication, where the minimal essential complexity that reflects the polypharmacutical nature of the TM is preserved and excess or irrelevant components are omitted.
Moreover, since contemporary and historical TM systems are inherently polypharmaceutical while government-regulated, prescription-based medical system approaches are typically ‘single drug-single target’, simple preclinical or clinical screening will miss compounds that only work when contextualized by other components.
Contemporary and historical TM pharmacopeias are also highly siloed along cultural dividing lines, tending to be examined in isolation by scientists from the originating country. This misses opportunities to identify consonant approaches that are duplicated across pharmacopeias, which could help pre-validate drug-target-indication relationships. In addition, it misses a major opportunity to combine efficacious components across cultural lines to design optimal new polypharmaceutical medicines.
Other challenges exist in modernizing, unlocking, and deconvolving the inherent knowledge in contemporary and historical traditional medical systems. Side-by-side comparisons of databases, for example, performed for Traditional Chinese Medicines (TCM), highlight issues with completeness, redundancy, and inconsistency, especially in the dating (and therefore rapid aging) of the source data on plant-chemical composition linkages. Currency and real-time updating are major data management issues in this field. Unification and integration of databases within TCM have been called for, recognizing the current fractured state of resources. These same issues persist in databases of other TM; therefore, there is a need for unification and integration of databases across multiple TM. There is also currently a missed opportunity for integration with data layers that reflect the wealth of biomedical data available in the era of the ‘omics revolution.
Other salient weaknesses of extant TM databases include a lack of ability to weigh for content (i.e., researchers focus on the chemical composition rather than on the proportion of each compound in a formulation) which limits moves to assign priorities to compounds when assembling novel formulations informed by the traditional medical system. The lack of consideration of the contributions of microorganisms that form stable, associated microbiomes of medicinal plants/fungi is also a weakness of current network pharmacology. These associated microorganisms have their own secondary metabolomes that may contribute to formulations in currently unrecognized ways. They may also pro-biotically, anti-biotically, or pre-biotically, be interacting with the patient's gut-microbiome axis and therefore influencing ADME and pharmacodynamics.
There is a need for an AI/ML-enabled drug discovery platform that would increase the efficiency and accuracy of the discovery of novel multi-component therapies from natural products and that would predict the potential efficacy of these novel multi-component therapies using analyses within an integrated and layered TM dataset with the appropriate applications of machine learning and deep learning modules.
3. SUMMARY
The present invention addresses the following needs in the art: a) to increase efficiency and accuracy of the identification of novel, multi-component therapeutics based on compounds derived from the metabolomes of plants, fungi, and other prokaryotic and eukaryotic organisms; b) to further increase the efficiency and accuracy of the identification of novel, multi-components therapeutics based on the manner that active compounds derived from the metabolomes of plants, fungi, and other prokaryotic and eukaryotic organisms are used in and substantially informed by the epistemology of contemporary and historical TM systems; c) to predict the efficacy of novel multi-component therapeutics based on convergence analysis of drug-target-indication relationships in these multi-component mixtures across multiple contemporary and historical TM systems; d) to unify and integrate the databases from as many contemporary and historical TM systems as possible; e) to layer additional epistemological, translational, ecological, and relative content (% API) information onto the contemporary and historical TM systems; and f) to provide flexibility in the system for queries originating with disease, target, compound, organism, and others that would result in the identification and prediction of efficacy for a novel, multi-compound therapeutic.
Embodiments of the present disclosure may include a method of effectively and rapidly transferring and importing very large traditional medicine datasets, efficiently reducing the size of the data (without losing the integrity of the data), translating, comparing, normalizing, analyzing, and assessing the data, correlating with intradata variables, and metadata, as well as other external datasets, displaying, sorting, ranking and visualizing the data for viewing by the user, using specialized methods and systems designed to manage the large extent of the data. Through multiple interfaces, the system allows the user to interact with the data, tabulate in various ways, and use graphical representations, zoom in or out, re-plot on different axes, re-scale, pick specific data of interest, refine and redefine data queries based on user data interaction with tabular, menu and graphical selections and groupings, as well as graphical gating, to initiate further, and subsequent processing depending on the user's questions, hypotheses and use case.
User choices, algorithmic processing, and machine learning algorithms can be initiated, and utilized to identify; specific patterns of interest, targets for subsequent processing, metadata groupings that correlate with indications across traditional medicines, identification of missing plants, components or compounds from specific plants or across the whole dataset, identification of unknown indications for traditional medicines, identification of toxic and non-toxic components and compounds, identification of plant, component and compound mixtures with ranked therapeutic potential, identification of plant, component and compound combination that would not be obvious, and/or would have greater therapeutic potential, than existing mixtures in isolated traditional medicines.
Additionally, the method may include, in silico processing to simulate and thus predict therapeutic phenotypic results, disease treatment outcomes, that have yet to be assessed in real-world analysis, testing, clinical trials, or laboratory-based experiments. This saves the resources needed to perform real-world assessment and renders tractable pharmaceutical problems that have previously been impossible to address using extant technologies.
Aspects of the present disclosure include a phytomedicine analytics for research optimization at scale (PhAROS) method for discovering and/or optimizing polypharmaceutical medicines. The PhAROS method comprises: analyzing, in a single computational space, data from a plurality of traditional medicine systems (TMS), wherein the analysis uses transcultural dictionaries to allow searches within distinct TMS data sets embodying different epistemologies and terminologies, wherein the analysis uses data returned by a query to identify new polypharmaceutical and/or optimized polypharmaceutical compositions.
In some embodiments, the data from the plurality of TMS comprise at least one of: medical formulations; organisms; medical compound data sets; therapeutic indications; processed and normalized formalized pharmacopeias from one or more geographic regions associated with TMS; therapeutic indication dictionaries related to traditional medical systems that reflect modern and historical terminology; Western and non-Western epistemologies; temporal and geographical data indicating historical and contemporary geographical, cultural and epistemology origins; raw and optionally pre-processed data from a plurality of traditional medicine data sets, plant data sets, and literature-based text documents (corpus).
In some embodiments, the one or more geographic regions is selected from: Japan, China, India, Korea, South East Asia, Middle East, North America, South America, Russia, India, Africa, Europe, and Australia.
In some embodiments, the one or more processed and normalized formalized pharmacopeias comprises at least one of processed data, translated normalized data, individual published datasets, or case reports in the scientific literature that document relationships between medicinal plants and disease indications.
In some embodiments, the one or more processed and normalized formalized pharmacopeias comprises at least one of processed data, curated ethical partnerships, indigenous phytomedical formulations, and cultural (African, Oceanic) phytomedical formulations.
In some embodiments, the one or more processed and normalized formalized pharmacopeias comprises processed contemporary and historical herbologies that document relationships between medicinal plants and disease indications, wherein the herbologies are optionally selected from Hildegard of Bingen, Causae et Curae, and Physica.
In some embodiments, the one or more processed and normalized formalized pharmacopeias comprises processed translations from original languages, wherein the process uses methods selected from one or more of: machine literal translation, natural language processing, multilingual concept extraction or conventional translation, Optical character recognition (OCR) of historical materials, and artificial intelligence (AI)-driven intent translation.
In some embodiments, the medical compound data sets comprise chemical and biological data of medical compounds.
In some embodiments, the chemical and biological data of medical compounds comprise one or more of: chemical structure, physicochemical properties, known and/or algorithmically calculated or predicted PD/PK properties, putative biological effects, data with respect to receptor binding, docking, regulation of signaling pathways, metabolism, drug-target relationships, mechanism of action, CYP interactions, or published studies and clinical trials of the medical compounds.
In some embodiments, the raw and optionally pre-processed data normalized from a plurality of traditional medicine data sets comprises one or more of: meta-pharmacopeia associated temporally, geographical, botanical, climatological, environmental, genomic, metagenomic, and metabolomic data on originating plants, components or other organisms; meta-pharmacopeias with de novo metabolomic data for plants and organisms that are not currently in medicinal use, supplemental metabolomic data secured for known medicinal plants and/or associated organisms; and toxicological and side-effect profile data of medical compound data sets, de novo experimentally-derived data of medical compound data sets, and/or in silico predicted toxicological and side-effect data of medical compound data sets.
In some embodiments, analyzing comprises, first, receiving a user query from a user.
In some embodiments, analyzing comprises, second, using the user query to search the data in the plurality of TMS for data that are associated with the first user query input.
In some embodiments, analyzing comprises, third, processing the searched data to create processed data.
In some embodiments, analyzing comprises, fourth, outputting the processed data for review by the user.
In some embodiments, analyzing comprises, fifth, optionally further processing the processed data if further requested by the user.
In some embodiments, analyzing comprises outputting the processed data returned by the query to the user for review by the user or for further analysis initiated by a second user query to identify the new polypharmaceutical and/or optimized polypharmaceutical compositions.
In some embodiments, processing the searched data comprises performing an in silico convergence analysis to search drug-target-indication relationships associated with the user query input. In some embodiments, processing the searched data comprises performing an in silico convergence analysis comprising identifying commonalities between two or more of: a disease, a therapeutic indication, one or more compounds derived from one or more organisms, and therapeutic approaches from biogeographically and culturally separated locales, coincidence or convergence of one or more compounds across a plurality of TMS, and coincidence or convergence of one or more organisms across a plurality of TMS.
In some embodiments, the in silico convergence analysis further comprises using processed data returned by the query to rank new polypharmaceutical compositions for subsequent preclinical and clinical testing for a given therapeutic indication.
In some embodiments, processing the searched data from the plurality of TMS using the in silico convergence analysis predicts efficacy of the new and/or optimized polypharmaceutical compositions.
In some embodiments, processing the searched data from the plurality of TMS using the in silico convergence analysis identifies minimal essential compounds required for efficacy of the new and/or optimized polypharmaceutical compositions.
In some embodiments, processing the searched data comprises performing an in silico divergence analysis to search drug-target-indication relationships associated with the user query input.
In some embodiments, processing the searched data comprises performing an in silico divergence analysis comprising identifying alternative compounds derived from one or more organisms, and therapeutic approaches from biogeographically and culturally separated locales across the plurality of TMS.
In some embodiments, the in silico divergence analysis further comprises using processed data returned by the query to rank new polypharmaceutical compositions for subsequent preclinical and clinical testing for a given therapeutic indication.
In some embodiments, processing the searched data from the plurality of TMS using the in silico divergence analysis predicts efficacy of the new and/or optimized polypharmaceutical compositions.
In some embodiments, a first user input query comprises one or more user selected clinical indications. In some embodiments, the one or more user selected clinical indications is selected from cancer, cancer pain, and cancer and cancer pain.
In some embodiments, outputting the processed data returned by the query comprises outputting: a list of compounds associated with the user selected clinical indication, a list of prescription formulae for a given TMS, a list of organisms associated with the user selected clinical indication, or a combination thereof.
In some embodiments, the outputting comprises outputting a list of compounds that is associated with a first user selected clinical indication, wherein the list of compounds that is associated with the first user selected clinical indication does not overlap with a list of compounds that is associated with a second user selected indication.
In some embodiments, the new polypharmaceutical and/or optimized polypharmaceutical compositions comprise one or more compounds derived from metabolomes of prokaryotic, Archaea, or eukaryotic organisms.
In some embodiments, the new polypharmaceutical and/or optimized polypharmaceutical compositions comprise one or more compounds derived from metabolomes of plants or fungi.
In some embodiments, the optimized polypharmaceutical compositions comprise one or more substitution compounds of an existing transcultural medicinal formulation.
In some embodiments, the optimized polypharmaceutical composition comprises a reduced number of compounds within the optimized polypharmaceutical composition as compared to an existing transcultural medicinal formulation, wherein the optimized polypharmaceutical composition comprises a minimal number of essential compounds to achieve a therapeutic outcome.
In some embodiments, further analysis includes, after outputting one or more selected from: developing training data sets for one or more machine learning models to optimize the transcultural dictionaries; populating the transcultural dictionaries with additional data developed by a machine learning algorithm; and creating, updating, annotating, processing, downloading, analyzing, or manipulating the data from the plurality of TMS.
In some embodiments, the method further includes iteratively training the one or more machine learning models with the one or more training data sets. In some embodiments, method further includes applying a machine learning model to identify the new polypharmaceutical and/or optimized polypharmaceutical compositions. In some embodiments, the machine learning model is iteratively trained with one or more training data sets. In some embodiments, the machine learned model comprises a set of rules, wherein the set of rules are configured to: identify specific patterns of interest, therapeutic targets for subsequent processing, metadata groupings that correlate with indications across traditional medicines, identify missing plants, components or compounds, identify unknown indications for traditional medicines, identify toxic and non-toxic components and compounds, identify plant, component and compound mixtures with ranked therapeutic potential, identify plant, component and compound combination that would not be obvious or have greater therapeutic potential, than existing mixtures in isolated traditional medicines. In some embodiments, the method includes applying the machine-learned model to identify the new polypharmaceutical and/or optimized polypharmaceutical compositions.
In some embodiments, at least one transcultural dictionary of the transcultural dictionaries comprises a search dictionary that collates Western and non-Western epistemological understanding of migraine and migraine-like patient presentations.
In some embodiments, populating the transcultural dictionaries with additional data developed by the machine learning algorithm comprises generating a therapeutic indication dictionary.
In some embodiments, the first user input query comprises one or more user selected clinical indications.
In some embodiments, the one or more user selected clinical indications is migraine.
In some embodiments, the outputting the processed data returned by the query comprises outputting: a list of compounds associated with the user selected clinical indication, a list of prescription formulae for a given TMS associated with the user selected clinical indication, or a combination thereof.
In some embodiments, the list of compounds is ranked by efficacy with statistical significance.
In some embodiments, the outputting further comprises outputting molecular targets for the list of compounds that are clinically indicated for migraine across one or more TMS.
In some embodiments, the molecular targets comprise: Prelamin-A/C; Lysine-specific demethylase 4D-like; Microtubule-associated protein tau; Microtubule-associated protein tau; Endonuclease 4; Peripheral myelin protein 22; Nonstructural protein 1; Bloom syndrome protein; Bloom syndrome protein; Neuropeptide S receptor; Geminin; Histone-lysine N-methyltransferase, H3 lysine-9 specific 3; Geminin; Thioredoxin reductase 1, cytoplasmic; Acetylcholinesterase; Cholinesterase; Solute carrier organic anion transporter family member 1B1; Solute carrier organic anion transporter family member 1B3 Nuclear factor NF-kappa-B p65 subunit; p53-binding protein Mdm-2; Huntingtin; Ras-related protein Rab-9A; Survival motor neuron protein; Tyrosyl-DNA phosphodiesterase 1; Microtubule-associated protein tau; Microtubule-associated protein tau; Microtubule-associated protein tau; Nuclear receptor ROR-gamma; Aldehyde dehydrogenase 1A1; Thioredoxin glutathione reductase; 4′-phosphopantetheinyl transferase ffp; 4′-phosphopantetheinyl transferase ffp; Nonstructural protein 1; Microtubule-associated protein tau; Microtubule-associated protein tau; Type-1 angiotensin II receptor; Niemann-Pick C1 protein; MAP kinase ERK2; Nuclear receptor ROR-gamma; Alpha-galactosidase A; DNA polymerase beta; Beta-glucocerebrosidase; Nuclear factor erythroid 2-related factor 2; X-box-binding protein 1; Histone acetyltransferase GCN5; G-protein coupled receptor 55; Histone-lysine N-methyltransferase, H3 lysine-9 specific 3; DNA damage-inducible transcript 3 protein; ATPase family AAA domain-containing protein 5; Vitamin D receptor; Vitamin D receptor; Chromobox protein hom*olog 1; Thioredoxin reductase 1, cytoplasmic; DNA polymerase iota; DNA polymerase eta; Regulator of G-protein signaling 4; Beta-galactosidase; Regulator of G-protein signaling 4; Mothers against decapentaplegic hom*olog 3; Geminin; Alpha trans-inducing protein (VP16); ATPase family AAA domain-containing protein 5; ATPase family AAA domain-containing protein 5; ATPase family AAA domain-containing protein 5; DNA dC->dU-editing enzyme APOBEC-3G; Photoreceptor-specific nuclear receptor; Geminin; Ataxin-2; Glucagon-like peptide 1 receptor; ATPase family AAA domain-containing protein 5; ATPase family AAA domain-containing protein 5; ATPase family AAA domain-containing protein 5; ATPase family AAA domain-containing protein 5; Tyrosyl-DNA phosphodiesterase 1; Isocitrate dehydrogenase [NADP] cytoplasmic; Tyrosyl-DNA phosphodiesterase 1; Transcriptional activator Myb; Transcriptional activator Myb; Ubiquitin carboxyl-terminal hydrolase 1; Parathyroid hormone receptor; ATPase family AAA domain-containing protein 5; ATPase family AAA domain-containing protein 5; Telomerase reverse transcriptase; Telomerase reverse transcriptase Survival motor neuron protein; Thyroid hormone receptor beta-1; Arachidonate 15-lipoxygenase; Chromobox protein hom*olog 1; Geminin; Guanine nucleotide-binding protein G(s), subunit alpha; Pregnane X receptor; Nuclear receptor subfamily 1 group I member 2; Nuclear receptor subfamily 1 group I member 3; Pregnane X receptor; Pregnane X receptor; Pregnane X receptor; Pregnane X receptor; Nuclear receptor subfamily 1 group I member 2; Nuclear receptor subfamily 1 group I member 2; Pregnane X receptor; Pregnane X receptor; Nuclear receptor subfamily 1 group I member 2; Nuclear receptor subfamily 1 group I member 2; Nuclear receptor subfamily 1 group I member 3; Nuclear receptor subfamily 1 group I member 3; Nuclear receptor subfamily 1 group I member 3; Nuclear receptor subfamily 1 group I member 3; Nuclear receptor subfamily 1 group I member 3; Nuclear receptor subfamily 1 group I member 3; Nuclear receptor subfamily 1 group I member 3; Nuclear receptor subfamily 1 group I member 3; Nuclear receptor subfamily 1 group I member 3; Nuclear receptor subfamily 1 group I member 3; Nuclear receptor subfamily 1 group I member 3; Nuclear receptor subfamily 1 group I member 3; Nuclear receptor subfamily 1 group I member 3; Nuclear receptor subfamily 1 group I member 3; Nuclear receptor subfamily 1 group I member 3; Nuclear receptor subfamily 1 group I member 3; Nuclear receptor subfamily 1 group I member 3; and Nuclear receptor subfamily 1 group I member 3.
In some embodiments, the second user query input comprises the list of compounds.
In some embodiments, further analysis initiated by the second user query input comprising the list of compounds comprises post-hoc screening for toxicity, chemical activity, or toxicity and chemical activity of the list of compounds.
In some embodiments, further analysis comprises using the second user query input to search the data from the plurality of TMS associated with the second user query input.
In some embodiments, further analysis comprises processing the data associated with the second user query input to create a second processed data returned by the second query user input.
In some embodiments, further analysis comprises processing the data associated with the second user query input to create a second processed data returned by the second query user input, and retrieving the second processed data based on the second query input for review by the user.
In some embodiments, the second processed data comprises a ranked list of potential minimal essential compounds required for efficacy of the new and/or optimized polypharmaceutical compositions.
In some embodiments, the list of compounds is categorized by class, identified as migraine dictionary search results, and are convergent between a plurality of TMS.
In some embodiments, the method further comprises further analysis initiated by a third user query input to identify the new polypharmaceutical and/or optimized polypharmaceutical compositions.
In some embodiments, further analysis comprises processing the data associated with the third user query input to create a third processed data returned by the query, and retrieving and outputting the third processed data based on the third user query input for review by the user.
In some embodiments, the third user query input comprises a query of neurotropic fungi associated with migraines in the plurality of TMS. In some embodiments, the third processed data comprises one or more convergent compounds considered as alternative compounds of an existing transcultural compound with convergence between a plurality of TMS.
In some embodiments, the user query input comprises one or more phytomedical compounds or formulations, and optionally a current source (plant or animal) and supply of the compound or formulation.
In some embodiments, the processed data comprises a list of plant sources, known clinical indications associated with the phytomedical compounds or formulations and the TMS in which each compound was referenced. In some embodiments, the processed data further comprises a relative abundance of the one or more compounds or formulations, wherein the relative abundance is the relative amount of the one or more compounds or formulations available. In some embodiments, the processed data further comprises growing locations of the list of plant sources. In some embodiments, the processed data is cross ranked by one or more of frequency, relative abundance, availability, potency, and supply.
In some embodiments, analyzing comprises outputting the processed data returned by the query to the user for review by the user or for further analysis initiated by a second user query input to identify the new polypharmaceutical and/or optimized polypharmaceutical compositions. In some embodiments, the new polypharmaceutical and/or optimized polypharmaceutical compositions comprise one or more compounds derived from metabolomes of an alternative source of plants or fungi that were not previously identified for a specific use or indication. In some embodiments, the optimized polypharmaceutical compositions comprise one or more substitution compounds of an existing transcultural medicinal formulation, wherein a source origin of the substitution compound is not found in an existing transcultural medicinal formulation.
In some embodiments, populating the transcultural dictionaries with additional data developed by the machine learning algorithm comprises generating a therapeutic indication dictionary. In some embodiments, at least one transcultural dictionary of the transcultural dictionaries comprises a search dictionary that collates Western and non-Western epistemological understanding of pain, pain-like patient symptoms.
In some embodiments, the first user input query comprises a user selected clinical indication. In some embodiments, the user selected clinical indication is pain.
In some embodiments, the processed data returned by the query comprises: a list of compounds associated with pain, a list of prescription formulae associated with pain, a list of organisms associated with pain, a list of chemicals associated with pain, or a combination thereof. In some embodiments, the list of compounds, prescription formulae, organisms, and chemicals are indicated for pain across one or more TMS. In some embodiments, the processed data further comprises: the identity of each TMS identified by an in silico convergent analysis, each TMS linked to one or more of: a number of compounds within the list of compounds associated with pain, a number of prescription formulae within the list of prescription formulae associated with pain, a number of organisms within the list of organisms associated with pain, and a number of chemicals within the list of chemicals associated with pain.
In some embodiments, the list of compounds comprises a list of alkaloids or terpenes. In some embodiments, the list of compounds comprises: a list of opioids and/or alkaloid candidate analgesics, a list of ligands for nociceptive ion channels, a list of compounds with demonstrated neuroactivity, a list of compounds with bioactivity, and a list of compounds with bioactivity associated with pain.
In some embodiments, the second user query input comprises the list of compounds.
In some embodiments, further analysis initiated by the second user query input comprising the list of compounds comprises post-hoc screening for toxicity, chemical activity, or toxicity and chemical activity of the list of compounds. In some embodiments, further analysis comprises using the second user query input to search the data from the plurality of TMS, the data from the plurality of TMS associated with the second user query input. In some embodiments, further analysis comprises processing the data associated with the second user query input to create a second processed data returned by the second query user input, and retrieving the second processed data based on the second query input for review by the user.
In some embodiments, the second processed data comprises a ranked list of potential minimal essential compounds required for efficacy of the new and/or optimized polypharmaceutical compositions for treating pain.
In some embodiments, the second processed data comprises a second list of compounds ranked by one or more of: class, target, pathway, and coincidence or convergence of each of the compounds across specific TMS. In some embodiments, the second processed data comprises a list of convergent compounds within the list of compounds between one or more TMS. In some embodiments, the convergent compounds within the list of convergent compounds is considered as alternative compounds of an existing transcultural compound convergent between or more TMS.
In some embodiments, the list of compounds comprises a list of alkaloids, convergent between two or more TMS and associated with pain. In some embodiments, the list of alkaloids comprises: niacin, berberine, palmatine, trigonelline, jatrorrhizine, d-pseudoephedrine, candicine, protopine, stachydrine, harmane, liriodenine, caffeine, sinoacutine, ephedrine, niacinamide, 3-hydroxytyramine, anonaine, magnoflorine, sanguinarine, cryptopine, piperine, dihydrosanguinarine, papaverine, codeine, narcotoline, higenamine, roemerine, gentianine, xanthine, theophylline, ricinine, morphine, pelletierine, meconine, narceine, xanthaline, harmine, and reserpine.
In some embodiments, the list of compounds comprises a list of terpenes convergent between one or more TMS and associated with pain. In some embodiments, the list of terpenes comprise: alpha-pinene, linalool, terpineol, oleanolic acid, beta-sitosterol, p-cymene, myrcene, beta-bisabolene, beta-humulene, carvacrol, beta-caryophyllene, gamma-terpinene, geraniol, 1,8-cineole, alpha-farnesene, limonene, ursolic acid, beta-selinene, terpilene, spinasterol, beta-eudesmol, citral, sabinene, stigmasterol, limonene, beta-elemenene, d-cadinene, terpinene-4-ol, uralenic acid, borneol, beta-pinene, limonin, camphene, campesterol, citronellal, isocyperol, ruscogenin, crocetin, squalene, brassicasterol, piperitenone, lycopene, toralactone, phytofluene, alpha-carotene, ecdysone, neomenthol, auroxanthin, soyasapogenol-e, cyasterone, neodihydrocarveol, guaiazulene, alpha-pinene, crataegolic acid, violaxanthin, and pathoulene.
In some embodiments, the user input query is pain type. In some embodiments, the processed data returned by the query comprises: a list of pain types across one or more TMS. In some embodiments, the list of pain types comprises: abdominal, cardiac/chest, mouth, muscle, back, inflammation, joint, eye, chronic pain/inflammation, labor/postpartum, skin, throat, limb, bone, breast, ear, pelvic, intestinal, anal, pain sensitivity, rib, neuropathic, bladder, kidney, lung, menstruation, facial, liver, arthritis, fallopian tube, urethra, and vagin*l, pain.
In some embodiments, for each pain type, the processed data comprises a list of TMS referenced from the plurality of TMS, associated with the pain type. In some embodiments, the processed data returned by the query comprises a list of compounds associated with each pain type. In some embodiments, the processed data further comprises a list of organisms for which the compounds within the list of compounds is derived. In some embodiments, the processed data comprises the list of pain types and a list of organisms, wherein one or more pain types is associated with one or more organisms.
In some embodiments, the processed data comprises the list of pain types and a list of compounds, wherein one or more pain types is associated with one or more compounds.
In some embodiments, for each pain type, the processed data comprises identity of a plurality of TMS linked to one or more selected from: the pain type, one or more compounds associated with the pain type, and one or more organisms associated with the pain type.
In some embodiments, at least one transcultural dictionary of the transcultural dictionaries comprises a search dictionary that collates Western and non-Western epistemological understanding of Piper species associated with a therapeutic indication.
In some embodiments, populating the transcultural dictionaries with additional data developed by the machine learning algorithm comprises generating a dictionary for Piper species.
In some embodiments, the therapeutic indication is selected from pain, sedation, anxiety, depression, epilepsy, mood, and sleep. In some embodiments, the therapeutic indication is selected from: hydropisy, gout, acne, coma, generalized hypopigmentation of hair, abnormal intrinsic pathway, abnormal female internal genitalia, pterygium, pain, gout, apoplexy, atony, headache, cancer giddiness, ring worm, epilepsy, otalgia, sciatica, hallucinations, alopecia, leucoderma/vitiligo, paralysis/hemiplegia, quartan fever ichthyosis, arthralgia, ptyriasis alba, congenital deafness alopecia furfuracea, hepatic obstruction, psychosis/insanity/mania, diseases of head and neck, bronchial asthma scrofula/cervical lymphadenitis, paroxysmal fever/intermittent fever bellas palsy, cramp/convulsion/spasm, strangury/dribbling of urine flaccidity, dyspnea, tremor, vertigo, tenesmus, poisoning flatulence, jaundice, toothache, hemorrhage, arthritis, lumbago backache, urinary incontinence, colic, weakness of stomach, sexual debility/anaphrodisia, palpitation, delerium, ptyriasis nigra, gastric dyscrasia, piles/ano rectal mass/haemorrhoids, fever with vata predominance, fatigue, insect bite, phlegmetic cough, splenic obstruction, blurring of vision, night blindness, corneal opacity, indigestion, vata-kaphaja, oedema/inflammation, anemia, chronic obstructive jaundice/chlorosis, cough/bronchitis, emaciation/cachexia, seminal disorders, pulmonary cavitation, gaseous/flatulence, disease with kapha predominance, tubercular cough/cough due to weakness or emaciation, pyrexia, diseases of spleen, dyspepsia/loss of appetite sprue/malabsorption syndrome, urinary disorders/polyuria curable disease of severe nature, obesity, cholera, asthma insomnia, sedative, diarrhea, anorexia, dysentery, dyspepsia, gonorrhea, rheumatism, bronchitis, cholagogue, emmenagogue, abdominal lump, angina pectoris, pleurodynia and intercostal neuralgia, stiffness, dryness of mouth, diseases of the mouth, diseases of head, and disease with vata predominance.
In some embodiments, the user input query comprises a list of Piper species of the family Piperaceae. In some embodiments, outputting the processed data returned by the query comprises outputting: a list of Piper species associated with one or more therapeutic indications.
In some embodiments, the one or more therapeutic indications is selected from pain, sedation, anxiety, depression, epilepsy, mood, and sleep. In some embodiments, the therapeutic indication is selected from: hydropisy, gout, acne, coma, generalized hypopigmentation of hair, abnormal intrinsic pathway, abnormal female internal genitalia, pterygium, pain, gout, apoplexy, atony, headache, cancer giddiness, ring worm, epilepsy, otalgia, sciatica, hallucinations, alopecia, leucoderma/vitiligo, paralysis/hemiplegia, quartan fever ichthyosis, arthralgia, ptyriasis alba, congenital deafness alopecia furfuracea, hepatic obstruction, psychosis/insanity/mania, diseases of head and neck, bronchial asthma scrofula/cervical lymphadenitis, paroxysmal fever/intermittent fever bellas palsy, cramp/convulsion/spasm, strangury/dribbling of urine flaccidity, dyspnea, tremor, vertigo, tenesmus, poisoning flatulence, jaundice, toothache, hemorrhage, arthritis, lumbago backache, urinary incontinence, colic, weakness of stomach, sexual debility/anaphrodisia, palpitation, delerium, ptyriasis nigra, gastric dyscrasia, piles/ano rectal mass/haemorrhoids, fever with vata predominance, fatigue, insect bite, phlegmetic cough, splenic obstruction, blurring of vision, night blindness, corneal opacity, indigestion, vata-kaphaja, oedema/inflammation, anemia, chronic obstructive jaundice/chlorosis, cough/bronchitis, emaciation/cachexia, seminal disorders, pulmonary cavitation, gaseous/flatulence, disease with kapha predominance, tubercular cough/cough due to weakness or emaciation, pyrexia, diseases of spleen, dyspepsia/loss of appetite sprue/malabsorption syndrome, urinary disorders/polyuria curable disease of severe nature, obesity, cholera, asthma insomnia, sedative, diarrhea, anorexia, dysentery, dyspepsia, gonorrhea, rheumatism, bronchitis, cholagogue, emmenagogue, abdominal lump, angina pectoris, pleurodynia and intercostal neuralgia, stiffness, dryness of mouth, diseases of the mouth, diseases of head, and disease with vata predominance.
In some embodiments, outputting the processed data returned by the query comprises outputting: the list of Piper species that are convergent across one or more TMS using the in silico convergent analysis. In some embodiments, the list of Piper species comprises Piper attenuatum, Piper betle, Piper boehmeriaefolium, Piper borbonense, Piper capense, Piper chaba, Piper cubeba, Piper cubeba, Piper cubeba, Piper cubeba, Piper futokadsura, Piper futokadzura, Piper guineense, Piper hamiltonii, Piper kadsura, Piper kadsura, Piper laetispicum, Piper longum, Piper longum, Piper longum, Piper longum, Piper mullesua, Piper nigrum, Piper nigrum, Piper nigrum, Piper nigrum, Piper nigrurml., Piper puberulum, Piper pyrifolium, Piper retrofractum, Piper retrofractum, Piper retrofractum, Piper schmidtii, Piper sylvaticum, Piper sylvestre, and Piper umbellatum.
In some embodiments, each Piper species within the list of Piper species is associated with one or more TMS, therapeutic indications within the one or more TMS, sets of chemical components linked to each Piper species and associated with the therapeutic indication, or a combination thereof.
In some embodiments, the list of chemical components for the list of piper species associated with the therapeutic indication, anxiety, comprises piperine, guineensine, piperlonguminine, unk, arecaidine, arecoline, beta-cadinene, beta-carotene, beta-caryophyllene, carvacrol, chavicol, diosgenin, estragole, eucalyptol, eugenol, gamma-terpinene, p-cymene, 1-triacontanol, 4-allyl-1,2-diacetoxybenzene, 4-allylbenzene-1,2-diol, 4-aminobutyric acid, allylpyrocatechol, calcium, dl-alanine-15n, dl-arginine, dl-asparagine, dl-aspartic acid, dl-valine, glutamate, glycine, hentriacontane, hydrogen oxalate, 1-ascorbic acid, 1-leucine, 1-methionine, l-proline, 1-serine, 1-threonine, malic acid, methyleugenol, nicotinate, octadecanoate, orn, phenylalanine, phytosterols, retinol, riboflavin, tyrosine cation radical, vitamin e, 4-allylcatechol, norcepharadione b, piperolactam a, piperolactam c, unk, unk, piperine, piperlongumine, d-fructose, d-glucose, phytosterols, (+)-sesamin, (−)-hinokinin, (−)-yatein, 1,4-cineole, 1,8-cineol, 1,8-cineole, 1-4-cineol, alpha-cubebene, alpha-pinene, alpha-terpinene, alpha-terpineol, beta-bisabolene, beta-caryophyllene, beta-cubebene, beta-pinene, caryophyllene, cineol, d-limonene, delta-cadinene, dipentene, gamma-terpinene, humulene, ledol, limonene, linalol, linalool, myrcene, ocimene, p-cymene, piperine, sabinene, terpineol, (+)-sabinene, (+)-zeylenol, (−)-clusin, (−)-cubebinin, (−)-cubebininolide, 2,4,5-trimethoxybenzaldehyde, allo-aromadendrene, alpha-muurolene, alpha-phellandrene, alpha-thujene, apiole, asarone, aschantin, azulene, beta-elemene, beta-phellandrene, bicyclosesquiphellandrene, cadinene, calamene, calamenene, copaene, cubebin, cubebinolide, cubebol, cubenol, dillapiole, eo, epicubenol, gamma-humulene, heterotropan, muurolene, nerolidol, piperenol a, piperenol b, piperidine, sabinol, safrole, terpinolene, (+)-4-iso-propyl-1-methyl-cyclohex-1-en-4-ol, (+)-car-4-ene, (+)-crotepoxide “(−)-5-o-methoxy-hinokinin” (−)-cadinene, (−)-cubebinone, (−)-di-o-methyl-thujaplicatin methyl ether, (−)-dihydro-clusin, (−)-dihydro-cubebin, (−)-isoyatein, 1-isopropyl-4-methylene-7-methyl-1,2,3,6,7,8,9-heptahydro . . . , 10-(alpha)-cadinol, “3(r)-3-4-dimethoxy-benzyl-2(r)-3-4-methylenedioxy-benzyl-butyrolactone”, alpha-o-ethyl-cubebin, beta-o-ethyl-cubebin, cadina-1-9(15)-diene, cesarone, cubebic acid, d-delta-4-carene, gum, hemi-ariensin, 1-cadinol, manosalin, resinoids, resins, trans-terpinene, (e)-citral, (z)-citral, citral, dihydroanhydropodorhizol, dihydrocubebin “(8r,8r)-4-hydroxycubebinone”, “(8r,8r,9s)-5-methoxyclusin”, 1-(2,4,5-trimethoxyphenyl)-1,2-propanedione, cubeben camphor, cubebin, ethoxyclusin, heterotropan, magnosalin, (+)-cubenene, (+)-delta-cadinene, 1,4-cineole, arachidic acid, beta-cadinene, dihydrocubebin, docosanoic acid, eucalyptol, hinokinin, oleic acid, palmitic acid, yatein, (+)-piperenol b, (+)-sabinene, (+)-zeylenol, (−)-clusin, (−)-cubebinin, (−)-cubebininolide, (−)-dihydroclusin “(8r,8r)-4-hydroxycubebinone”, “(8r,8r,9s)-5-methoxyclusin” 1-epi-bicyclosesquiphellandrene, 2,4,5-trimethoxybenzaldehyde, alpha-muurolene, calamenene, chemb1501119, chemb1501260, crotepoxide, cubebin, cubebinone, cubebol, cyclohexane, epizonarene, ethoxyclusin, hexadecenoic acid, isohinokinin, isoyatein, 1-asarinin, lignans machilin f, octadeca-9,12-dienoic acid, octadecanoate, picrotoxinum, piperidine, thujaplicatin, unii-5vg84p9unh, zonarene, (+)-deoxy, (+)-piperenol a, acetic acid-((r)-6,7-methylenedioxy-3-piperonyl-1,2-dihydro-2naphthylmethyl ester), cubebinol, hibalactone, isocubebinic ether, podorhizon, unk, unk, unk, unk, kadsurin a, isodihydrofutoquinol b, denudatin b, kadsurenone, elemicin, futoquinol, kadsurin a, sitosterol, î′-sitosterol, stigmasterol, (+)-acuminatin, (e,7s,11r)-3,7,11,15-tetramethylhexadec-2-en-1-ol, phytol, (â±)-galgravin, 4-(2r,3r,4s,5s)-5-(1,3-benzodioxol-5-yl)-3,4-dimethyl-2-tetrahydrofuranyl-2-methoxyphenol, machilin f, asaronaldehyde, asarylaldehyde, chicanine, crotepoxide, futoxide, futoamide, futoenone, futokadsurin a, futokadsurin b, futokadsurin c, galbacin, galbelgin, kadsurenin b, kadsurenin c, kadsurenin k, kadsurenin l, kadsurenin m, machilusin, n-isobutyldeca-trans-2-trans-4-dienamide, piperlactam s, veraguensin, zuonin a, unk, artecanin, unk, piperine, piperitenone, piplartine, pisatin, sesamin, undulatone, 1,2,15,16-tetrahydrotanshiquinone, 1-undecylenyl-3,4-methylenedioxybenzene, guineensine, hexadecane, laurotetanine, lawsone, piperidine, piperlonguminine, sesamol, beta-caryophyllene, p-cymene, piperine, piperlongumine, 2-phenylethanol “4-methoxyacetophenone”, 6,7-dibromo-4-hydroxy-1h,2h,3h,4h-pyrrolol,2-apyrazin-1-one, alpha thujene, aristololactam, diaeudesmin, dihydrocarveol, eicosane, ent-zingiberene, fargesin, guineensine, heneicosane, heptadecane, hexadecane, 1-asarinin, lignans machilin f, methyl 3,4,5-trimethoxycinnamate, nonadecane, octadecane, phytosterols, piperlonguminine, pipernonaline, piperundecalidine, pluviatilol, terpinolene, triacontane, (2e,4e)-n-isobutyl-2,4-decadienamide, isobutyl amide, unk, yangonin, 10-methoxyyangonin, 11-methoxyyangonin, 11-hydroxyyangonin, desmethoxyyangonin, 11-methoxy-12-hydroxydehydrokavain, 7,8-dihydroyangonin, kavain, 5-hydroxykavain, 5,6-dihydroyangonin, 7,8-dihydrokavain, 5,6,7,8-tetrahydroyangonin, 5,6-dehydromethysticin, methysticin, 7,8-dihydromethysticin, (−)-bornyl ferulate, (−)-bornyl-caffeate, (−)-bornyl-p-coumarate, 1-cinnamoylpyrrolidine, 11-hydroxy-12-methoxydihydrokawain, 2,5,8-trimethyl-1-napthol, 3,4-methylene dioxy cinnamic acid, 3a,4a-epoxy-5b-pipermethystine, 5-methyl-1-phenylhexen-3-yn-5-ol, 5,6,7,8-tetrahydroyangonin2, 9-oxononanoic acid, benzoic acid, bornyl cinnamate, caproic acid, cinnamalacetone, cinnamalacetone2, cinnamic acid, desmethoxyyangonin, dihydro-5,6-dehydrokawain, dihydro-5,6-dehydrokawain2, dihydrokavain, dihydrokavain2, dihydromethysticin, flavokawain a, flavokawain b, flavokawain c, glutathione, methysticin2, mosloflavone, octadecadienoic acid methyl ester, p-hydroxy-7,8-dihydrokavain, p-hydroxykavain, phenyl acetic acid, pipermethystine, prenyl caffeate, nectandrin b, neferine, (+)-limonene, 1,8-cineole, alpha-bulnesene, alpha-cubebene, alpha-guaiene, alpha-gurjunene, alpha-humulene, alpha-pinene, alpha-terpinene, alpha-terpineol, alpha-terpineol acetate, alpha-trans-bergamotene, arachidic acid, astragalin, behenic acid, beta-bisabolene, beta-carotene, beta-caryophyllene, beta-cubebene, beta-farnesene, beta-pinene, beta-selinene, beta-sitosterol, borneol, butyric acid, caffeic acid, campesterol, camphene, camphor, carvacrol, caryophyllene, cedrol, cinnamic acid, cis-carveol, citral, d-limonene, delta-cadinene, dl-limonene, eugenol, fat, gamma-terpinene, hexanoic acid, hyperoside, isocaryophyllene, isoquercitrin, kaempferol, l-alpha-phellandrene, 1-limonene, lauric acid, limonene, linalol, linalool, linoleic acid, monoterpenes, myrcene, myristic acid, myristicin, myrtenal, myrtenol, niacin, ocimene, oleic acid, p-coumaric acid, p-cymene, palmitic acid, perillaldehyde, piperine, quercetin, quercitrin, rhamnetin, rutin, sabinene, sesquiterpenes, stearic acid, stigmasterol, trans-carveol, trans-pinocarveol, (−)-cubebin, (z)-ocimenol, 1(7),2-p-menthadien-4-ol, 1(7),2-p-menthadien-6-ol, 1-terpinen-4-ol, 1-terpinen-5-ol, 2,8-p-menthadien-1-ol, 2-methyl-pentanoic acid, 2-undecanone, 3,8(9)-p-menthadien-1-ol, 3-methyl-butyric acid, 4-methyl-triacontane, acetophenone, alpha-bisabolene, alpha-copaene, alpha-linolenic acid, alpha-phellandrene, alpha-santalene, alpha-selinene, alpha-thujene, alpha-tocopherol, alpha-zingiberene, ar-curcumene, ascorbic acid, benzoic acid, beta-bisabolol, beta-caryophyllene alcohol, beta-elemene, beta-phellandrene, beta-pinone, boron, calamene, calamenene, calcium, car-3-ene, carvetonacetone, carvone, caryophyllene alcohol, caryophyllene-oxide, chavicine, chlorine, choline, chromium, cis-nerolidol, cis-ocimene, cis-p-2-menthen-1-ol, citronellal, citronellol, clovene, cobalt, copper, cryptone, cubebine, cuparene, delta-3-carene, delta-elemene, dihydrocarveol, dihydrocarvone, elemol, eo, feruperine, fluoride, gaba, gamma-cadinene, gamma-muurolene, germacrene-b, germacrene-d, globulol, guineensine, heliotropin, hentriacontan-16-ol, hentriacontan-16-one, hentriacontane, hentriacontanol, hentriacontanone, iodine, iron, isochavicine, isopiperine, isopulegol, limonen-4-ol, lipase, magnesium, manganese, methyl-eugenol, n-formylpiperidine, n-hentriacontane, n-heptadecane, n-nonadecane, n-nonane, n-pentadecane, n-tridecane, nerolidol, nickel, oxalic acid, p-cymen-8-ol, p-cymene-8-ol, p-menth-8-en-1-ol, p-menth-8-en-2-ol, p-methyl-acetophenone, pellitorine, phenylacetic acid, phosphorus, phytosterols, piperanine, pipercide, piperettine, pipericine, piperidine, piperitone, piperonal, piperonic acid, piperylin, piperyline, potassium, pyrrolidine, pyrroperine, retrofractamide-a, riboflavin, safrole, sesquisabinene, silica, sodium, spathulenol, starch, sulfur, terpinen-4-ol, terpinolene, thiamin, thujene, tocopherols, trans-nerolidol, trichostachine, ubiquinone, water, zinc, (−)-3,4-dimethoxy-3,4-demethylenedioxy-cubebin, (−)-phellandrene, 1,1,4-trimethylcyclohepta-2,4-dien-6-one, 1,8(9)-p-menthadien-4-ol, 1,8(9)-p-menthadien-5-ol, 1,8-menthadien-2-ol, 1-(2,4-decadienoyl)-pyrrolidine, 1-(2,4-dodecadienoyl)-pyrrolidine, 1-alpha-phellandrene, 1-piperyl-pyrrolidine, 2-trans-4-trans-8-trans-piperamide-c-9-3, 2-trans-6-trans-piperamide-c-7-2, 2-trans-8-trans-piperamide-c-9-2, 2-trans-piperamide-c-5-1, 3,4-dihydroxy-6-(n-ethyl-amino)-benzamide, 4,10,10-trimethyl-7-methylene-bicyclo-(6.2.0)decane-4-car . . . , 4-methyl-tritriacontane, 5,10(15)-cadinen-4-ol, 6-trans-piperamide-c-7-1, 8-trans-piperamide-c-9-1, acetyl-choline, alpha-amorphene, alpha-cis-bergamotene, alpha-cubebine, beta-cubebine, carvone-oxide, caryophylla-2,7(15)-dien-4-beta-ol, caryophylla-2,7(15)-dien-4-ol, caryophylla-3(12),7(15)dien-4-beta-ol, caryophyllene-ketone, cis-2,8-menthadien-2-ol, cis-sabinene-hydrate, cis-trans-piperine, citronellyl-acetate, cumaperine, dihydropipercide, epoxydihydrocaryophyllene, eugenol-methyl-ether, geraniol-acetate, geranyl-acetate, isobutyl-caproate, isobutyl-isovalerate, isochavinic acid, kaempferol-3-o-arabinosyl-7-o-rhamnoside, linalyl-acetate, m-mentha-3(8),6-diene, m-methyl-acetophenone, methyl-caffeic acid-piperidide, methyl-carvacrol, methyl-cinnamate, methyl-cyclohepta-2,4-dien-6-one, methyl-heptanoate, methyl-octanoate, n-(2-methylpropyl)-deca-trans-2-trans-4-dienamide, n-5-(4-hydroxy-3-methoxy-phenyl)-pent-trans-2-dienoyl-piperidine, n-butyophenone, n-heptadecene, n-isobutyl-11-(3,4-methylenedioxy-phenyl)-undeca-trans-2-trans-4-trans-10-trienamide, n-isobutyl-13-(3,4-methylenedioxy-phenyl)-trideca-trans-2-trans-4-trans-12-trienamide, n-isobutyl-eicosa-trans-2-trans-4-cis-8-trienamide, n-isobutyl-eicosa-trans-2-trans-4-dienamide, n-isobutyl-octadeca-trans-2-trans-4-dienamide, n-methyl-pyrroline, n-pentadecene, n-trans-feruloyl-piperidine, nerol-acetate, p-cymene-8-methyl-ether, p-menth-cis-2-en-1-ol, p-menth-trans-2-en-1-ol, phytin-phosphorus, piperolein-a, piperolein-b, piperolein-c, piperoleine-b, polysaccharides, quercetin-3-o-alpha-d-galactoside, rhamnetin-o-triglucoside, terpin-1-en-4-ol, terpinyl-acetate, trans-cis-piperine, trans-sabinene-hydrate, trans-trans-piperine, chavicol, pinocembrin, piperine, piperitenone, piplartine, trans-pinocarveol, 1(7),2-p-menthadien-4-ol, 1(7),2-p-menthadien-6-ol, 1(7),8(10)-p-menthadien-9-ol, 3,8(9)-p-menthadien-1-ol, chavicine, cis-p-2-menthen-1-ol, cryptone, cryptopimaric acid, dihydrocarveol, piperanine, piperettine, piperidine, piperitone, piperitylhonokiol, piperonal, sarmentosine, sesquisabinene, (+)-alpha-phellandrene, (+)-endo-beta-bergamotene, (−)-camphene, (−)-linalool, alpha-humulene, beta-caryophyllene, beta-pinene, capsaicin, d-citronellol, dipentene, eucalyptol, eugenol, gamma-terpinene, myrcene, p-cymene, piperine, testosterone, (+)-sabinene, (z)-.beta.-ocimenol, 1,8-menthadien-4-ol, 16-hentriacontanone, 2,6-di-tert-butyl-4-methylphenol, 3-carene, 7-epi-.alpha.-eudesmol, aclnahmy, acetic acid, alpha thujene, amide 4, beta-alanine, bicyclogermacrene, butylhydroxyanisole, carotene, caryophyllone oxide, cepharadione a, chebi:70093, cholesterol formate, cis-.alpha.-bergamotene, crypton, cubebin, Curcuma longa, dehydropipernonaline, dextromethorphan, dl-arginine, guineensine, hedycaryol, hentriacontane, isobutyramide, kakoul, 1-ascorbic acid, 1-serine, 1-threonine, menthadien-5-ol, methylenedioxycinnamic acid, moupinamide, nonane, octane, oxirane, p-anisidine, p-mentha-2,8-dien-1-ol, paroxetine, pellitorine, phytosterols, piperettine, piperidine, piperidine-2-carboxylic acid, pipernonaline, piperolactam d, piperolein a, piperolein b, piperonal, pyrocatechol, retrofractamide a, retrofractamide b, retrofractamide c, sarmentine, sodium nitroprussiate, tannic acid, terpinen-4-ol, trichostachine, wisanine, (2e,4e,8z)-n-isobutyl-eicosa-2,4,8-trienamide, (2e,4z)-5-(4-hydroxy-3-methoxyphenyl)-1-(1-piperidinyl)-2,4-pentadien-1-one, (e,e)-, 1-piperoyl-, n-idobutyl-13-(3,4-methylenedioxyphenyl)-2e,4e,12e-tridecatrienamide, pyrrolidine, unk, asarinin, grandisin, piperine, piperlonguminine, piplartine, sesamin, trans-pinocarveol, î″-fa*garine, (+)-bornyl piperate, (1-oxo-3-phenyl-2e-propenyl)pyrrolidine, “(7r,8r)-3,4-methylenedioxy-4,7-epoxy-8,3-neolignan-7e-ene”, “(7s,8r)-4-hydroxy-4,7-epoxy-8,3-neolignan-(7e)-ene”, “(7s,8r)-4-hydroxy-8,9-dinor-4,7-epoxy-8,3-neolignan-7-aldehyde”, (â±)-erythro-1-(1-oxo-4,5-dihydroxy-2e-decaenyl)piperidine, (â±)-threo-1-(1-oxo-4,5-dihydroxy-2e-decaenyl)piperidine, (â±)-threo-n-isobutyl-4,5-dihydroxy-2e-octaenamide, 1(7),2-p-menthadien-4-ol, 1(7),2-p-menthadien-6-ol, 1-(1,6-dioxo-2e,4e-decadienyl)piperidine, 1-(1-oxo-2e,4e-dodedienyl)pyrrolidine, 1-(1-oxo-2e-decaenyl) piperidine, 1-(1-oxo-3-phenyl-2e-propenyl)piperidine, 1-1-oxo-3(3,4-methylenedioxy-5-methoxyphenyl)-2zpropenyl piperidine, 1-1-oxo-3(3,4-methylenedioxyphenyl)-2e-propenylpiperidine, 1-1-oxo-3(3,4-methylenedioxyphenyl)-2e-propenylpyrrolidine, 1-1-oxo-3(3,4-methylenedioxyphenyl)-2z-propenylpiperidine, 1-1-oxo-3(3,4-methylenedioxyphenyl)propylpiperidine, 1-1-oxo-5(3,4-methylenedioxyphenyl)-2e,4e-pentadienylpyrrolidine, 1-1-oxo-5(3,4-methylenedioxyphenyl)-2e,4z-pentadienyl pyrrolidine, 1-1-oxo-5(3,4-methylenedioxyphenyl)-2e,4z-pentadienylpiperidine, 1-1-oxo-5(3,4-methylenedioxyphenyl)-2z,4e-pentadienyl piperidine, 1-1-oxo-5(3,4-methylenedioxyphenyl)-2z,4e-pentadienyl pyrrolidine, 1-1-oxo-7(3,4-methylenedioxyphenyl)-2e,4e,6e-heptatrienylpyrrolidine, 1-1-oxo-9(3,4-methylenedioxyphenyl)-2e,8e-nonadienyl piperidine, pipernonaline, 1-terpinen-5-ol, 3,8(9)-p-menthadien-1-ol “4-desmethylpiplartine”, “5-hydroxy-7,3,4-trimethoxyflavone” cenocladamide, chavicine, cis-p-2,8-menthadien-1-ol, cis-p-2-menthen-1-ol, cryptone, dehydropipernonaline, guineensine, kaplanin, menisperine, methyl piperate, “methyl-(7r,8r)-4-hydroxy-8,9-dinor-4,7-epoxy-8,3-neolignan-7-ate”, n-isobutyl-(2e,4e)-octadecadienamide, n-isobutyl-(2e,4e)-octadienamide, n-isobutyl-(2e,4e,14z)-eicosatrienamide, n-isobutyl-2e,4e,12z-octadecatrienamide, n-isobutyl-2e,4e-dodedienamide, n-isobutyldeca-trans-2-trans-4-dienamide, neopellitorine b, pipataline, piperamide c 7:1(6e), piperamide c 9:1(8e), piperamide c 9:2(2e,8e), piperamide c 9:3(2e,4e,8e), piperamine, piperanine, piperchabamide a, piperchabamide b, piperchabamide c, piperchabamide d, pipercide, retrofractamide b, piperenol a, piperettine, piperitone, piperlonguminine, piperolactam a, piperolein a, piperolein b, piperonal, pipnoohine, pipyahyine, “rel-(7r,8r,7r,8r)-3,4-methylenedioxy-3,4,5,5-tetramethoxy-7,7-epoxylignan”, “rel-(7r,8r,7r,8r)-3,4,3,4-dimethylenedioxy-5,5-dimethoxy-7,7-epoxylignan”, retrofractamide a, retrofractamide b, sarmentine, sarmentosine, sesquisabinene, xanthoxylol, zp-amide a, zp-amide b, zp-amide c, zp-amide d, zp-amide e, n-isobutyl-4,5-dihydroxy-2e-decaenamide, n-isobutyl-4,5-epoxy-2e-decaenamide, pipercycliamide, wallichinine, unk, unk, brachystamide d, friedlein, phytosterols, unk, piperine, piperlongumine, 1-asarinin, phytosterols, piperine, asperphenamate, aurantiamide, phytosterols, piperettine, and sylvatine.
In some embodiments, the list of chemical components for at least one piper species comprises bis-noryangonin, 11-methoxy-nor-yangonin, 5,6-dehydrokawain, dihydromethysticin, and yangonin. In some embodiments, the at least one piper species is Piper methysticum.
In some embodiments, the second user query input for further analysis initiated by the second user query input comprises the list of chemical components: bis-noryangonin, 11-methoxy-nor-yangonin, 5,6-dehydrokawain, dihydromethysticin, and yangonin. In some embodiments, further analysis initiated by the second user query input comprising the list of chemical components comprises using the second user query input to search transcultural dictionaries, the data from the plurality of TMS associated with the second user query input. In some embodiments, further analysis comprises processing the data associated with the second user query input to create a second processed data returned by the second query user input, and retrieving the second processed data based on the second query user input. In some embodiments, the second processed data comprises a list of non-piper species comprising the list of chemical components. In some embodiments, the list of non-piper species comprises Petroselinum crispum, Dioscorea collettii, Dioscorea hypoglauca, Gentiana algida, Rubia cordifolia, and Alpinia speciosa. In some embodiments, processing the data associated with the second query user input comprises screening for non-piper species comprising the list of chemical components.
In some embodiments, further analysis comprises processing the data associated with the second user query input to create a second processed data returned by the second query user input, and retrieving the second processed data based on the second query user input.
In some embodiments, the second user query input comprises a biogeography of P. methysticum and a list of therapeutic indications, wherein the list of therapeutic indications comprises anxiety, mood, and depression.
In some embodiments, the second processed data comprises a list of non-piper species associated with anxiety, mood, depression, or a combination thereof found in non-piper species within the biogeography of P. methysticum.
In some embodiments, the list of non-piper species comprises Glycyrhizza uralensis/radix, Paeonia lactiflora, Scutellaria baicalensis, Panax ginseng, Saposhnikovia divaicata, and Poria cocos.
In some embodiments, populating the transcultural dictionaries with additional data developed by the machine learning algorithm comprises generating a therapeutic indication dictionary.
In some embodiments, at least one transcultural dictionary of the transcultural dictionaries comprises a search dictionary that collates Western and non-Western epistemological understanding of cancer, cancer-like patient presentations, cytotoxic agents within TMS formulations for cancer, and cancer pain.
In some embodiments, at least one transcultural dictionary of the transcultural dictionaries comprises a list of compounds associated with cancer pain, and a list of compounds known for treating pain.
In some embodiments, the first user input query comprises one or more user selected clinical indications. In some embodiments, the one or more user selected clinical indications is selected from cancer, cancer pain, and cancer and cancer pain.
In some embodiments, outputting the processed data returned by the query comprises outputting: a list of compounds associated with the user selected clinical indication, a list of prescription formulae for a given TMS, a list of organisms associated with the user selected clinical indication, or a combination thereof.
In some embodiments, the outputting further comprises outputting cytotoxic agents within the list of compounds that are indicated for pain and cancer across one or more TMS.
In some embodiments, outputting further comprises outputting the list of organisms associated with cancer and pain across one or more TMS.
In some embodiments, the list of compounds is categorized by class, identified as migraine dictionary hits, and are convergent between two or more TMS.
In some embodiments, the outputting further comprises outputting a list of compounds that is associated with a first user selected clinical indication, wherein the list of compounds that is associated with the first user selected clinical indication does not overlap with a list of compounds that is associated with a second user selected indication.
In some embodiments, the first user selected clinical indication is cancer, and the second user selected indication is pain.
Aspects of the present disclosure include a phytomedicine analytics for research optimization at scale (PhAROS) system for analyzing a plurality of traditional medical systems in a single computational space, the PhAROS system comprising: a computer server configured to communicate with one or more user clients (PhAROS_USER), comprising: (a) a database (PhAROS_BASE) comprising a memory configured to store a collection of data, the collection of data comprising: raw and optionally pre-processed data from a plurality of traditional medicine data sets; and optionally one or more of: plant data sets; literature-based text documents (corpus); and machine learning data sets; (b) a computer core processor (PhAROS_CORE), wherein the PhAROS_CORE is configured to receive and process the collection of data from the PhAROS_BASE to generate processed data; (c) one or more searchable repositories having data and optionally pre-processed data, wherein each searchable repository comprises a memory configured to store data entries, wherein the PhAROS_CORE is configured to send the processed data to and receive data from each of the searchable repositories, wherein each of the searchable repositories is configured to receive processed data from the PhAROS_CORE and send data and optionally pre-processed data to the PhAROS_CORE; (d) a computer-readable storage medium storing executable instructions that, when executed by a hardware processor, cause the PhAROS_CORE to communicate with the PhAROS_BASE and one or more of the searchable repositories to analyze data from a plurality of the traditional medicine data sets to produce an output responsive to a user query input into the PhAROS system.
In some embodiments, the PhAROS_CORE is further configured to manage, direct, collect, parse, and filter the collection of data from the PhAROS_BASE to generate processed data. In some embodiments, the PhAROS system further comprises one or more user clients (PhAROS_USER). In some embodiments, at least one PhAROS_USER client has a graphical user interface (GUI). In some embodiments, at least one PhAROS_USER client is configured to allow the user to communicate with the PhAROS_CORE. In some embodiments, at least one PhAROS_USER client is configured to allow the user to communicate with at least one of the searchable repositories. In some embodiments, at least one PhAROS_USER client is configured to allow the user to communicate with the PhAROS_CORE, PhAROS_BASE, and the searchable repositories.
In some embodiments, at least one searchable repository comprises: a first meta-pharmacopeia database (PhAROS_PHARM) comprising (i) data from PhAROS_BASE; and (ii) pre-processed data processed from data in the PhAROS_BASE related to at least one of: medical formulations; organisms; medical compound data sets; therapeutic indications; processed and normalized formalized pharmacopeias from one or more geographic regions associated with traditional medicines.
In some embodiments, the one or more geographic regions is selected from: Japan, China, India, Korea, South East Asia, Middle East, North America, South America, Russia, India, Africa, Europe, and Australia.
In some embodiments, the one or more processed and normalized formalized pharmacopeias comprises processed, translated normalized, individual published datasets or case reports in the scientific literature that document relationships between medicinal plants and disease indications.
In some embodiments, the one or more processed and normalized formalized pharmacopeias comprises processed, appropriate ethical partnerships, indigenous, cultural phytomedical formulations.
In some embodiments, the one or more processed and normalized formalized pharmacopeias comprises processed contemporary and historical herbologies that document relationships between medicinal plants and disease indications (e.g., Hildegard of Bingen, Causae et Curae, Physica).
In some embodiments, the one or more processed and normalized formalized pharmacopeias comprises processed, translation of resources from original languages processed using approaches selected from one or more of: machine literal translation, natural language processing, multilingual concept extraction or conventional translation, Optical character recognition (OCR) of historical materials, and artificial intelligence (AI)-driven intent translation.
In some embodiments, at least one searchable repository (PhAROS_CONVERGE) comprises data and pre-processed data that allow identification of commonalities in therapeutic approaches from biogeographically and culturally traditional medical systems (TMS). In some embodiments, the data and pre-processed data of the PhAROS_CONVERGE is further configured to allow identification of efficacious medical components across traditional medicine systems. In some embodiments, the data and pre-processed data of the PhAROS_CONVERGE is further configured to allow ranking optimization of de novo compound formulations and compound mixtures by utilizing transcultural components for subsequent preclinical and clinical testing for a given therapeutic indication.
In some embodiments, the data and pre-processed data of the PhAROS_CONVERGE comprises at least one of: therapeutic indication dictionaries related to traditional medical systems that reflect modern and historical terminology, and/or Western and non-Western epistemologies; medical formulation compositions related to traditional medical systems; compound data sets for a given therapeutic indication; and a proprietary digital composition index (n-dimensional vector and/or fingerprint).
In some embodiments, the computer-readable storage medium storing executable instructions, when executed by the hardware processor, cause the hardware processor to: develop training data sets for one or more machine learning algorithms to optimize the searchable repositories for a user; populate the one or more searchable repositories with additional data developed by the machine learning algorithm; and create, update, annotate, process, download, analyze, or manipulate the collection of data received by the Pharos_CORE. In some embodiments, the computer-readable storage medium storing executable instructions, when executed by the hardware processor, cause the PhAROS_CORE to: initiate a user to provide the user query input on the PhAROS_USER client, wherein the PhAROS_USER client is configured to communicate with the PhAROS_core and optionally the searchable repositories; search the user query input within the PhAROS_CORE, the searchable repositories, or a combination thereof; retrieve the processed data based on the user's query input for review by the user in PhAROS_USER; optionally initiate further processing of the retrieved processed data, if inquired by the user.
In some embodiments, the PhAROS_USER client further comprises a graphical data processing environment (PhAROS_FLOW) configured to allow the user to process data without or with reduced amount of at least one of: coding, system modeling tools comprising machine learning, or artificial intelligence (AI) tools.
In some embodiments, the machine learning and AI tools are selected from one or more of: support vector machine, artificial neural networks, deep learning, Naïve Bayesian, K-nearest neighbors, random forest, AdaBoost wisdom of crowds and ensemble predictors, and others, validation (such as MonteCarlo cross-validation, Leave-One-Out cross validation, Bootstrap Resampling, and y-randomization).
5. DETAILED DESCRIPTION
In the following description, reference is made to the accompanying drawings, which form a part hereof. It is to be understood that other embodiments may be utilized and structural changes may be made without departing from the scope of the present invention.
General Overview:
It should be noted that the description that follows, for example of a method and systems for phytomedicine analytics for research optimization at scale (PhAROS), is described for illustrative purposes and the underlying system can apply to any number and multiple types of phytomedicine analyses. In one embodiment of the present invention, the method and systems for phytomedicine analytics for research optimization at scale can be configured using multiple searchable databases. The method and systems for phytomedicine analytics for research optimization at scale can be configured to include algorithmic processing and machine learning algorithms and can be configured to include silico processing in order to simulate and thus predict therapeutic phenotypic results using the present invention.
The local client system 1a is wirelessly coupled to a local network. The local network is wirelessly coupled to a server system 2a. The remote client system 1b is wirelessly coupled to an external network/WWW. The external network/WWW is wirelessly coupled to the server system 2a. The server system 2a is configured with user devices, a display, interfaces coupled to a system bus that is coupled to storage devices, processor and a main memory of one embodiment
In accordance with some embodiments, the systems and methods described here as the PhAROS discovery platform for computational phyto-pharmacology (PhAROS) consist as a science gateway and virtual research environment for drug discovery user interfaces. As well, data repositories and data processing components not accessible to general users are accessible and maintained by administrator users.
Through a series of servers and computer systems; that downloads, pre-processes, cleans, processes, analyses, normalizes, dynamically normalizes or pre-process normalizes, correlates, translates, and sorts traditional medicine data and other correlative data, users can access the system, processing methods and data, and then rapidly and accurately view and compare processed tabular, graphical and non-text visual interpretations of the data. Users can also choose options that further process and reduce the data, depending on the users final wishes, this will depend on their choice of indication, medicinal plant component and/or compound, biological target, the users own competence and/or users domain of expertise. User options, filters and directions for generating an in silico hypothesis are customized based on the background of the user, including a basic biological researcher, clinical researcher, epidemiologist, pharmaceutical/therapeutic development professional, educator, environmentalist, war fighter resilience researcher, behavioral health researcher, xenobiologist, pharmacological logistics manager, chemical sourcing agent, medical doctor, field doctor, traditional medicine practitioner, NGO professional etc.
In some embodiments, the computing system can be any sort of server computing system (
In some embodiments generally PhAROS will integrate data sets, tools, and applications as a web-based portal with a graphical user interface PhAROS. PhAROS will connect an academic, industry and public health community of users with a pre-processed data repository, through cyberinfrastructure and computational resources (e.g., HPC). As a science gateway, PhAROS will allow users to query details of their scientific questions without the need for advanced expertise in areas such as supercomputing or data visualization. PhAROS will support user communities by providing advanced software applications (fully containerized workflows, analysis, simulation, prediction and modeling), human-in-the-loop intermediary analysis and cloud-based data repositories linked to cluster-, cloud- and super-computing services.
A user with an existing account securely logs into their existing account on PhAROS_USER subsystem. Through the PhAROS_USER interface, the user can initiate access to the other PhAROS subsystems. The user can search them directly to retrieve data, and/or initiate a logical processing pipeline in order to produce data based on the user's needs and the user's use case.
The other PhAROS subsystems process user actions for data production or data retrieval via the PhAROS_USER interface. The PhAROS user interface returns data; visuals, reports and any files needed back from the PhAROS subsystems, for review by the user. The user determines that this is sufficient and logs out of the PhAROS_USER system. Should the user wish to investigate the data further through interaction with the data via the PhAROS_USER interface the user initiates further processing as above until satisfied with the data the user needs, depending on the type of user, the user's query and the users use case. Upon completion the user logs out of the PhAROS_USER subsystem portal and web browser of one embodiment.
A user with an existing account securely logs into their existing account on PhAROS_USER subsystem. Through the PhAROS_USER interface, the user can initiate access to the other PhAROS subsystems. The user can search them directly to retrieve data, and/or initiate a logical processing pipeline in order to produce data based on the user's needs and the user's use case.
The other PhAROS subsystems process user actions for data production or data retrieval via the PhAROS_USER interface. The PhAROS_USER interface returns data; visuals, reports and any files needed back from the PhAROS subsystems, for review by the user. The user determines that this is sufficient and logs out of the PhAROS_USER system. Should the user wish to investigate the data further through interaction with the data via the PhAROS_USER interface the user initiates further processing as above until satisfied with the data the user needs, depending on the type of user, the user's query and the users use case. Upon completion the user logs out of the PhAROS_USER subsystem portal and web browser of one embodiment.
The administrative user interacts with PhAROS system and subsystems and has the options to create, maintain, update, backup, move and parse data between subsystems, download and transfer data from external servers, and sources attached to the server via the internet or permanent or temporally attached data storage devices, create, edit, update or change PhAROS code components including PhAROS_BRAIN Functions and PhAROS_FLOW data-pipelines and workspaces.
In order to efficiently provide, a greater range of data, an improved accuracy of data, and data searching ability, to backup data, to create machine learning modules and functions, using new or existing PhAROS functions, in alternative combinations with different variables. The administrative user initiates processes above and is either satisfied with the results, and additions to the PhAROS system, or reiterates the actions above. The administrative user logs out of the PhAROS system on the server computer of one embodiment.
Definitions
As used herein, the term “PhAROS_USER” refers to the user interactive system of the PhAROS platform, and includes but is not limited to functional user tools designed to aid in coordinating user defined in silico analysis across multiple sub repositories and tools, in part by coordinating with PhAROS_CORE to utilize processes, connect and retrieve data and present user requested data, in an accessible manner. Basic and administrative levels of access limit possible disruption of data resources and tools.
As used herein, the term “PhAROS_CORE” refers to the core functional system of the PhAROS system, including but not limited to tools designed to collect, parse and maintain sub-systems, raw data repositories, pre-processed repositories, training data, data tools, automated and manual processing and task management.
As used herein, the term “PhAROS_BRAIN” refers to a repository of integrated data and a data processing/assessing tool. PhAROS_BRAIN includes but is not limited to a system that links the PhAROS_USER interactive system to advanced analysis tools. PhAROS_BRAIN functions enable de novo analysis, as well as being able to populate PhAROS subsystems with data.
As used herein, the term “PhAROS_FLOW” refers to a graphical data processing environment that provides users and administrators with the ability to process data using the PhAROS_BRAIN functions without extensive coding. PhAROS_FLOW includes, but is not limited to, at least one of subsystem modeling tools including machine learning and AI tools such as support vector machine, artificial neural networks, deep learning, Naïve Bayesian, K-nearest neighbors, random forest, AdaBoost wisdom of crowds and ensemble predictors, and validation tools such as Monte Carlo cross-validation, Leave-One-Out cross validation, Bootstrap Resampling, and y-randomization.
As used herein, the term “PhAROS_PHARM” refers to a proprietary pre-processed repository and computational space. PhAROS_PHARM comprises, but is not limited to, at least one of:
the first ‘meta-pharmacopeia’, processed and normalized formalized pharmacopeias, formulations, associated plant/organisms, associated available compound sets, and indications, temporal and geographical data, indicating historical, and contemporary geographical, cultural and epistemology origins;
processed and normalized formalized pharmacopeias from Japan, China, India, Korea, South East Asia, Middle East, North/South America, Russia, India, Africa, Europe, Australia; processed, translated normalized, individual relevant published datasets or case reports in the scientific literature that document relationships between medicinal plants and disease indications;
processed, curated ethical partnerships, indigenous, cultural (e.g., African, Oceanic) phytomedical formulations;
processed open source contemporary and historical herbologies that document relationships between medicinal plants and disease indications (e.g., Hildegard of Bingen, Causae et Curae, Physica);
processed, translation of resources from original languages processed using approaches such as machine literal translation, natural language processing, multilingual concept extraction or conventional translation; OCR of historical materials, and AI driven intent translation.
As used herein, the term “PhAROS_CONVERGE” refers to a pre-processed repository that includes, but is not limited to, at least one of an unbiased in silico convergence analysis of formulation composition explicitly between medical systems, predictions of minimal and/or essential compound sets for a given indication, a proprietary digital composition index (n-dimensional vector and/or fingerprint) identifying efficacy across traditional medicine systems, ranked optimized de novo formulations and mixtures utilizing transcultural components for subsequent preclinical and clinical testing in particular indications.
As used herein, the term “PhAROS_CHEMBIO” refers to a pre-processed repository of chemical and biological data, including but not limited to at least one of chemical structure, physicochemical properties, known and/or algorithmically calculated or predicted PD/PK properties, putative biological effects, data informing of receptor binding, docking, regulation of signaling pathways, metabolism, drug-target relationships, and mechanism of action, CYP interactions, as well as published studies and clinical trials.
As used herein, the term “PhAROS_BIOGEO” refers to a pre-processed repository of integrated data, including but not limited to the meta-pharmacopeia, associated temporally, geographical, botanical, climatological, environmental, genomic, metagenomic, and metabolomic data on originating plants, components or other organisms.
As used herein, the term “PhAROS_METAB” refers to a pre-processed repository of integrated data of, including but not limited to, the meta-pharmacopeia with de novo metabolomic data for plants, and/or organisms that are not currently in medicinal use, supplemental metabolomic data secured for known medicinal plants and/or associated organisms.
As used herein, the term “PhAROS_MICRO” refers to a pre-processed repository of integrated data of, including but not limited to, the meta-pharmacopeia with microbiome data on microorganisms associated with plants/organisms/components of interest, and their secondary metabolome compositions.
As used herein, the term “PhAROS_CURE” refers to a pre-processed repository of integrated data, including but not limited to, the meta-pharmacopeia with documented spontaneous regression/remission events associated with botanical medicine or supplement usage, organized by organism, including plant, compound set and clinical manifestation/ICD codes.
As used herein, the term “PhAROS_QUANT” refers to a pre-processed repository of integrated data of, including but not limited to, the meta-pharmacopeia with component weighting data based on either proportional components using standardized measurements and normalizations, for formulations and/or de novo quantitative analysis of formulated components.
As used herein, the term “PhAROS_POPGEN” refers to a pre-processed repository of integrated data of, including but not limited to, the genetic admixtures, SNP characteristics and genetic/ethnic variability in populations in whom the formulations within the meta-pharmacopeia have been tested geographically and temporally.
As used herein, the term “PhAROS_TOX” refers to a pre-processed repository of integrated data of, including but not limited to, the meta-pharmacopeia with toxicological and side-effect profile data, and/or de novo experimentally-derived data, and/or in silico predicted toxicological and side-effect data.
As used herein, the term “PhAROS_BH” refers to a pre-processed repository of integrated data and a data processing/assessing tool, including but not limited to, contextualization data of meta-pharmacopeia datasets within a novel proprietary Bradford-Hill decision support framework, predicting data interpretation and assessing the evidence base for assertions of potential efficacy.
As used herein, the term “PhAROS_EPIST” refers to a pre-processed repository of integrated data and a data processing/assessing tool, including but not limited to, parsed of formulation components data, plant, compound, a proprietary PhAROS correlation tool, that links composition to underlying epistemology for inclusion of a component (e.g., TCM/Kampo concept of JUN-CHEN-ZUO-SHI (‘Monarch, Minister, Assistant and Envoy’).
As used herein, the term “PhAROS_BASE” refers to a structured raw and pre-processed data repository of all data used to develop all the integrated data repositories in PhAROS subsystems, full and partially constructed data processing/assessing tools, backups, user data, user process history, machine learning data sets, and PhAROS_CORPUS, a repository of texts utilized and maintained to extract and parse data, and for text mining purposes.
As used herein, the term “PhAROS_DIVERGE” refers to a pre-processed repository including but not limited to, an unbiased in silico divergence analysis comprising identifying alternative compounds derived from one or more organisms, and therapeutic approaches from biogeographically and culturally separated locales across the plurality of TMS.
As used herein, the term “transcultural dictionaries” refers to a search dictionary that collates Western and non-Western epistemological understanding of terms including, but not limited to, medical formulations, organisms, medical compound data sets, and therapeutic indications.
As used herein, the term “therapeutic indications” refers to information on the use of a medicine, where the information can include, but is not limited to, disease and/or condition, severity of disease and/or condition, target population, and aim of the treatment (e.g., diagnostic indication, prevention, or treatment).
PBS Embodiments Methods
Aspects of the present disclosure include a phytomedicine analytics for research optimization at scale (PhAROS) method for discovering and/or optimizing polypharmaceutical medicines. The PhAROS method comprises: analyzing, in a single computational space, data from a plurality of traditional medicine systems (TMS), wherein the analysis uses transcultural dictionaries to allow searches within distinct TMS data sets embodying different epistemologies and terminologies, wherein the analysis uses data returned by a query to identify new polypharmaceutical and/or optimized polypharmaceutical compositions.
For example, in some embodiments, the method includes receiving from a user in a graphical user interface (GUI), a user query input. The method uses the user query input (or user query) to search the data from the plurality of TMS, the data from the plurality of TMS associated with the first user query input. The method then processes the searched data to create processed data returned by the query from the plurality of TMS associated with the user query input. The analysis of the method uses data returned by the query to identify new polypharmaceutical and/or optimized polypharmaceutical compositions. However, the method can also include further processing the processed data, if further inquired by the user.
In some embodiments, analyzing comprises outputting the processed data returned by the query to the user for review by the user or for further analysis initiated by a second user query input.
User query Inputs can include, but are not limited to: (1) a medical condition, (2) a medical condition with a desired sub-type, (3) a medical condition, with a desired organism(s), (4) a divergence analysis with overlapping conditions, (5) a medical condition, with a geographical region, (6) desired compounds, or (7) current plant source with desired components.
For example, the analysis of the method can include outputting, for each of the respective inputs: Ranked Compounds & Ranked Minimum Essential Mixtures, Ranked Minimum Essential Mixtures by Clinical Sub-type, Ranked Compounds & Ranked Minimum Essential Mixtures, Ranked Compounds & Ranked Minimum Essential Mixtures, Ranked Formulas based on User's Geographical Location, Ranked Plant Sources, Relative Compound Abundance, Geography, and/or Alternative Plant Sources, Relative Compound Abundance, Geography.
In some embodiments, the analysis of the method can include any combination of input and outputs as described in
In some embodiments, Input (1) a medical condition includes an Output: Ranked Compounds & Ranked Minimum Essential Mixtures (see, e.g.,
In some embodiments, Input (2) a Medical Condition with a Desired Sub-type includes an Output: Ranked Minimum Essential Mixtures by Clinical Sub-type (see, e.g.,
In some embodiments, Input (3) a Medical Condition, with a Desired Organism(s) includes an Output: Ranked Compounds & Ranked Minimum Essential Mixtures (see, e.g.,
In some embodiments, Input (4) a divergence analysis with overlapping conditions includes an Output: Ranked Compounds & Ranked Minimum Essential Mixtures (see, e.g.,
In some embodiments, Input (5) Medical Condition, with a Geographical Region includes an Output: Ranked Formulas based on User's Geographical Location (see, e.g.,
In some embodiments, Input (6) Desired Compounds includes an Output: Ranked Plant Sources, Relative Compound Abundance, Geography (see, e.g.,
In some embodiments, Input (7) Current Plant Source with desired components include an Output: Alternative Plant Sources, Relative Compound Abundance, Geography (see, e.g.,
In some embodiments, outputting the processed data returned by the query to the user for review by the user or for further analysis comprises outputting a list of compounds associated with the user selected clinical indication, a list of prescription formulae for a given TMS, a list of organisms associated with the user selected clinical indication, or a combination thereof. In some embodiments, the processed data returned by the query to the user for review by the user or for further analysis comprises outputting molecular targets for the list of compounds that are clinically indicated for a therapeutic indication across one or more TMS.
In some embodiments, outputting the processed data returned by the query to the user for review by the user or for further analysis comprises outputting: a list of species associated with one or more therapeutic indications.
In some embodiments, the outputting further comprises outputting cytotoxic agents within the list of compounds that are indicated for a therapeutic indication across one or more TMS.
In some embodiments, outputting further comprises outputting the list of organisms associated with a therapeutic indication across more TMS.
In some embodiments, the list of compounds is categorized by class, identified as indication dictionary hits, and are convergent between two or more TMS.
In some embodiments, the outputting further comprises outputting a list of compounds that is associated with a first user selected clinical indication, wherein the list of compounds that is associated with the first user selected clinical indication does not overlap with a list of compounds that is associated with a second user selected indication.
User
As described above, in some embodiments, the method includes, first, receiving from a user in a graphical user interface (GUI), a user query input.
The user of the PhAROS method and system can include users with various access to outputs or data returned by a query. For example, the user can perform a user query input to retrieve data, and/or initiate a logical processing pipeline in order to produce data based on the user's needs and the user's use case.
In some embodiments, each user will be able to perform actions for data production or data retrieval via the PhAROS_USER interface according to their credentials (e.g. type of access the user will have to the PhAROS system). In some embodiments, the PhAROS user interface returns data; visuals, reports and any files needed back from the PhAROS subsystems, for review by the user. The user determines that this is sufficient and logs out of the PhAROS_USER system. Should the user wish to investigate the data further through interaction with the data via the PhAROS_USER interface the user initiates further processing as above until satisfied with the data the user needs, depending on the type of user, the user's query and the users use case. Upon completion the user logs out of the PhAROS_USER subsystem portal and web browser of one embodiment.
Non-limiting examples of the type of users with different access rights to the PhAROS system include, but are not limited to: administrative user having administrative access to the system on behalf of the stakeholder, direct but limited access to the system as a user by the stakeholder, direct unlimited access to the system as a user/administrator; clinician user having direct but limited access to the system for a particular therapeutic use, a user having direct but limited access to the system for a therapeutic use in a particular geographical region, a user having direct but limited access to the system for global health initiatives (e.g., world health organization (WHO) or for non-profit), a user having direct but limited access to the system for searching alternative compounds (e.g., compounds isolated from plant or other organism in a particular geographical region). For example, one user can include a user that lives in a rural geographical location that is interested in developing compounds or compound mixtures from organisms that are grown in that particular geographical location.
For example, the PhAROS methods of the present disclosure are applicable to global health challenges linked to medicine availability and quality in locales classified by the UN as developing economies, economies in transition, heavily indebted poor countries (HIPC), emerging economies and small island developing states (SIDS). Herbal and phytomedicines are major pillars of medical provisioning in national health systems for WHO member nations. The National Essential Medicines List of 34 WHO member nations contain representation of herbal medicines (spanning WHO African, eastern Mediterranean, Americas, European, South-East Asia and Western Pacific regions). Up to 65% of the global population rely wholly or in part on non-Western pharmaceutical approaches to morbidity.
PhAROS Global Health (PhAROS_GH) is an initiative to enable users within developing, emerging economies to access medical optimizations and rationalization data to improve safety and efficacy of TMS as they are currently deployed.
In some embodiments, the user is a PhAROS_GH user group. Non-limiting examples of a PhAROS_GH user includes: global and regional agencies/NGO concerned with healthcare quality and safety in non-developed economies; governmental and private healthcare systems and/or organizations; for-profit entities located in non-developed economies; Non-profit entities located in non-developed economies; and grassroots and community healthcare organizations, systems and providers. In some embodiments, a PhAROS_GH user group has direct but limited access to the system for global health initiatives, such as a user having direct but limited access to the system for: searching alternative compounds (e.g., compounds isolated from plant or other organism in a particular geographical region); supply chain optimization, where the PhAROS_GH user can use PhAROS data on organism-chemical component relationships that expand the potential source organisms for preparation of specific formulations, allowing substitution of ingredients across biogeographical boundaries and decreasing supply chain limitations; medicine rationalization/optimization, where the PhAROS_GH user can the PhAROS method to improve upon current formulations in a given locale by incorporating transcultural elements to build new formulations that leverage information generated across cultures, locations and biogeograhies; medicine rationalization/optimization, where the PhAROS_GH user can use the PhAROS method to reduce complexity of formation by identifying minimal essential component for a given indication (potential decreasing supply chain limitations, increasing safety and consistency, decreasing undesirable side effects, decreasing use of non-essential or anachronistic components); rational design, where the PhAROS_GH user can use the PhAROS method to identify phytomedical solutions that are customized to specific locations, ingredient resources, populations and needs.
In some embodiments, the method comprises second, using the user query input to search the data from the plurality of TMS, the data from the plurality of TMS associated with the first user query input.
In some embodiments, the method includes third, processing the searched data to create processed data returned by the query from the plurality of TMS associated with the user query input.
In some embodiments, the method includes fourth, retrieving processed data based on the user query input for review by the user.
In some embodiments, the method comprises fifth, further processing the processed data, if further inquired by the user.
Data from Traditional Medicine Systems (TMS)
In some embodiments, data from the plurality of TMS comprises at least one of: medical formulations; organisms; medical compound data sets; therapeutic indications, processed and normalized formalized pharmacopeias from one or more geographic regions associated with TMS; therapeutic indication dictionaries related to traditional medical systems that reflect modern and historical terminology; Western and non-Western epistemologies; temporal and geographical data indicating historical, and contemporary geographical, cultural and epistemology origins; raw and optionally pre-processed data from a plurality of traditional medicine data sets, plant data sets, and literature-based text documents (corpus). In some embodiments, the one or more geographic regions (as such region is presently defined) is selected from Japan, China, Taiwan, India, Korea, South East Asia, Middle East, North America, South America, Russia, India, Africa, Europe, Australia, and Oceania.
In certain embodiments, data from the TMS comprises medical formulations. In certain embodiments, data from the TMS comprises organisms. In certain embodiments, data from the TMS comprises medical compound data sets. In certain embodiments, data from the TMS comprises therapeutic indications. In certain embodiments, data from the TMS comprises processed and normalized formalized pharmacopeias from one or more geographic regions associated with TMS. In certain embodiments, data from the TMS comprises therapeutic indication dictionaries related to traditional medical systems that reflect modern and historical terminology. In certain embodiments, data from the TMS comprises Western and non-Western epistemologies. In certain embodiments, data from the TMS comprises temporal and geographical data indicating historical, and contemporary geographical, cultural and epistemology origins.
In certain embodiments, data from the TMS comprises raw and optionally pre-processed data from a plurality of traditional medicine data sets, plant data sets, and/or literature-based text documents (corpus). In some embodiments, data from the TMS comprises plant data sets. In certain embodiments, data from the TMS comprises traditional medicine data sets. In some embodiments, the data from the TMS comprises literature-based text documents.
In some embodiments, the data from the TMS comprises one or more of: compounds, ingredient lists, formulations and their associated therapeutic indications, e.g., associated with formalized publicly-available pharmacopeias from Japan, China, India, Korea, South East Asia, Middle East, North America, South America, Russia, India, Africa, Europe, and Australia.
In some embodiments, data from the TMS comprises datasets from three continents, five contemporary and historical cultural medical systems, spanning over 5000 years of human medical endeavor and the biogeography of >16.9M square miles of medicinal plant growth.
In some embodiments, data from the TMS comprises datasets of gene expression curated profiles maintained by NCBI and included in the Gene Expression Omnibus.
Transcultural Dictionaries
In some embodiments, the transcultural dictionary is a search dictionary that collates Western and non Western epistemological understanding of indication dictionaries (e.g., therapeutic indications), therapeutic indication dictionaries related to traditional medical systems that reflect modern and historical terminology, culture-specific terminology (modern and historical), organism dictionaries, compound lists, compound lists associated with a plant-source and/or therapeutic indication within a geographic location, and the like. In certain embodiments, the transcultural dictionaries comprise therapeutic indication dictionaries related to traditional medical systems that reflect modern and historical terminology. In certain embodiments, the transcultural dictionaries comprise therapeutic indication dictionaries related to organism dictionaries. In certain embodiments, the transcultural dictionaries comprise therapeutic indication dictionaries related to compound lists, and/or compound lists associated with a plant-source and/or therapeutic indication within a geographic location. Non-limiting examples of therapeutic indication dictionaries are provided in
In some embodiments, the transcultural dictionaries comprise a search dictionary that collates Western and non-Western epistemological understanding of migraine and migraine-like patient presentations.
In some embodiments, one transcultural dictionary of the transcultural dictionaries comprises a list of compounds associated with cancer pain, and a list of compounds known for treating pain. In certain embodiments, at least one transcultural dictionary of the transcultural dictionaries comprises a search dictionary that collates Western and non-Western epistemological understanding of pain, pain-like patient symptoms. In certain embodiments, at least one transcultural dictionary of the transcultural dictionaries comprises a search dictionary that collates Western and non-Western epistemological understanding of Piper species associated with a therapeutic indication.
In certain embodiments, at least one transcultural dictionary of the transcultural dictionaries comprises a search dictionary that collates Western and non-Western epistemological understanding of cancer, cancer-like patient presentations, cytotoxic agents within TMS formulations for cancer, and cancer pain.
Processed and Normalized Formalized Pharmacopeias
In some embodiments, one or more processed and normalized formalized pharmacopeias comprises processed, translated normalized, individual published datasets or case reports in the scientific literature that document relationships between medicinal plants and disease indications. In some embodiments, one or more processed and formalized pharmacopeias comprises processed, translated normalized, individual published datasets or case reports in the scientific literature that document relationships between medicinal plants and disease indications.
In some embodiments, one or more processed and normalized formalized pharmacopeias comprises processed, curated ethical partnerships, indigenous, cultural (e.g., African, Oceanic, and the like) phytomedical formulations.
In some embodiments, the one or more processed and normalized formalized pharmacopeias comprises processed contemporary and historical herbologies that document relationships between medicinal plants and disease indications (e.g., Hildegard of Bingen, Causae et Curae, Physica).
In some embodiments, the one or more processed and normalized formalized pharmacopeias comprises processed, translation of resources from original languages processed using approaches selected from one or more of: machine literal translation, natural language processing, multilingual concept extraction or conventional translation, Optical character recognition (OCR) of historical materials, and artificial intelligence (AI)-driven intent translation.
In some embodiments, the one or more processed and normalized formalized pharmacopeias comprises data from one or more databases selected from: chemical compound databases, metabolic pathway databases, gene-disease databases, traditional medicine databases, plant metabolomics database, databases for references and abstracts on life sciences and biomedical topics, and variant-phenotype relation database that may provide data regarding the association among a phenotype and one or more genetic loci or single nucleotide polymorphisms (SNPs). Example external data servers from which the data can be taken from include, but are not limited to: ClinVar, PubMed, DrugBank, STITCH for drugs, drug actions and drug-target interactions, PubChem, ChEMBL, Natural Products Atlas, MoleculeNet, ATC for chemical information databases, KEGG for Metabolic pathways, OMIM for Gene-disease relationships, TCM Data Warehouse, Clinical Trials.gov for clinical trials databases, PlantMetabolomics.org, Metabolights, SetUpX, SWMD, MetaboAnalyst for metabolomes, HPRD, BioGRID, DIP for protein databases, HPRD, BIND, DIP, HAPPI, MINT, STRING, PDZBase for biomolecular interactions, Cytoscape, Pajek, VisANT, GUESS, WIDAS, PATIKA, PATIKAweb, CADLIVE for networking and visualization tools, TOXNET, CTD, DSSToxicology, FDA Poisonous Plants database, National Poison Center for network toxicology and poison databases. Other processed and normalized formalized pharmacopeias include data from databases that store clinical study data, scientific papers, medical records, and suitable university databases.
In some embodiments, the one or more processed and normalized formalized pharmacopeias comprises data from one or more databases selected from: Chinese traditional medicines (ETCM, MESH), Japanese traditional medicines (kampo, Kegg), Korean traditional medicines (KTKP), Indian Traditional Medicines (TKDL, IMPPAT), African Traditional Medicines (SANCDB, ETMDB, and Prelude).
Medical Compound Datasets
In some embodiments, data from the plurality of TMS comprises medical compound data sets.
In some embodiments, the medical compound data sets chemical and/or biological data of medical compounds. In some embodiments, chemical and biological data of medical compounds comprise one or more of: chemical structure, physicochemical properties, known and/or algorithmically calculated or predicted PD/PK properties, putative biological effects, data informing of receptor binding, molecular docking sites on human receptors, regulation of signaling pathways, metabolism, drug-target relationships, mechanism of action, CYP interactions, or published studies and clinical trials of the medical compounds.
In certain embodiments, the medical compound data set comprises phytomedical compounds. In certain embodiments, the medical compound data set comprises one or more of: traditional Chinese medicine compounds, traditional Japanese medicine compounds, traditional Indian medicine compounds, traditional Korean medicine compounds, traditional South East Asian medicine compounds, traditional Middle Eastern medicine compounds, traditional North American compounds, traditional South American compounds, traditional Russian medicine compounds, traditional Indian medicine compounds, traditional African medicine compounds, traditional European medicine compounds, and traditional Australian medicine compounds.
In certain embodiments, the medical compound comprises compounds derived from the metabolomes of plants, fungi, and other prokaryotic and eukaryotic organisms.
Raw and Optionally Processed Data Normalized from a Plurality of Traditional Medicine Data Sets
In some embodiments, the raw and optionally pre-processed data normalized from a plurality of traditional medicine data sets comprises one or more selected from: meta-pharmacopeia, associated temporally, geographical, botanical, climatological, environmental, genomic, metagenomic, and metabolomic data on originating plants, components or other organisms; meta-pharmacopeia with de novo metabolomic data for plants, and organisms that are not currently in medicinal use, supplemental metabolomic data secured for known medicinal plants and/or associated organisms, and toxicological and side-effect profile data of medical compound data sets, de novo experimentally-derived data of medical compound data sets, and in silico predicted toxicological and side-effect data of medical compound data sets.
In certain embodiments, the raw and optionally pre-processed data normalized from a plurality of traditional medicine data sets comprises meta-pharmacopeia, associated temporally, geographical, botanical, climatological, environmental, genomic, metagenomic, and metabolomic data on originating plants, components or other organisms.
In certain embodiments, the raw and optionally pre-processed data normalized from a plurality of traditional medicine data sets comprises toxicological and side-effect profile data of medical compound data sets, de novo experimentally-derived data of medical compound data sets, and/or in silico predicted toxicological and side-effect data of medical compound data sets.
In certain embodiments, the raw and optionally pre-processed data normalized from a plurality of traditional medicine data sets comprises meta-pharmacopeia with de novo metabolomic data for plants, and organisms that are not currently in medicinal use, supplemental metabolomic data secured for known medicinal plants and/or associated organisms.
In certain embodiments, the raw and pre-processed data is stored in a data repository of all data used to develop all the integrated data repositories in PhAROS subsystems, full and partially constructed data processing/assessing tools, backups, user data, user process history, machine learning data sets, and PhAROS_CORPUS, a repository of texts utilized and maintained to extract and parse data, and for text mining purposes.
In some embodiments, the raw data can include raw text data, as well as specific sets of data are predominantly stored in the PhAROS_CORPUS, in the PhAROS_CORE subsystem. In some embodiments, Raw data, as well as specific sets of data are predominantly stored in the PhAROS_CORE subsystem, or processed and added to PhAROS subsystems, for access by various types of user, depending on their use case.
Analysis of Data, from a Plurality of Traditional Medicine Systems (TMS) in in a Single Computational Space
Aspects of the present methods include analyzing data from a plurality of TMS in a single computational space.
As described above in the “user” section, the method includes receiving a user query input, using the user query input to search the data from the plurality of TMS, the data from the plurality of TMS associated with the first user query input, processing the searched data to create processed data returned by the query from the plurality of TMS associated with the user query input, retrieving processed data based on the user query input for review by the user, and further processing the processed data, if further inquired by the user. In some embodiments, analyzing comprises outputting the processed data returned by the query to the user for review by the user or for further analysis.
Further processing the processed data can include a variety of analysis options, for example, performing: an in silico convergence analysis (PhAROS_CONVERGE), an in silico divergence analysis (PhAROS_DIVERGE), PhAROS_BIOGEO analysis, PhAROS_PHARM analysis, PhAROS_CHEMBIO analysis, PhAROS_METAB analysis, PhAROS_MICRO analysis, PhAROS_CURE analysis, PhAROS_QUANT analysis, PhAROS_POPGEN analysis, PhAROS_TOX analysis, PhAROS_BH analysis, PhAROS_BRAIN analysis, and/or PhAROS_EPIST analysis.
In some embodiments, further analysis can include a variety of analysis options, for example, performing: an in silico convergence analysis (PhAROS_CONVERGE), an in silico divergence analysis (PhAROS_DIVERGE), PhAROS_BIOGEO analysis, PhAROS_PHARM analysis, PhAROS_CHEMBIO analysis, PhAROS_METAB analysis, PhAROS_MICRO analysis, PhAROS_CURE analysis, PhAROS_QUANT analysis, PhAROS_POPGEN analysis, PhAROS_TOX analysis, PhAROS_BH analysis, PhAROS_BRAIN analysis, and/or PhAROS_EPIST analysis.
In-Silico Convergence Analysis
In some embodiments, the method includes processing the searched data to create processed data returned by the query from the plurality of TMS associated with the user query input.
In certain embodiments, processing the searched data comprises performing an in silico convergence analysis to search drug-target-indication relationships associated with the user query input. For example, the method can include a convergence as an analysis mode to search for “derisked compound mixtures”, for example, when searching for the same compounds in different TMS. The in silico convergence analysis reduces the complexity and de-risks translation of phytomedical therapies from TMS to Western pipelines through identifying commonalities in approaches from biogeographically and culturally separated locales. For example, as shown in
In another embodiment, an in silico convergence analysis can reduce complexity of TMS polypharmaceutical preparations to identify minimal essential efficacious components that are candidates for translation from TMS to Western discovery pipelines (
In certain embodiments, performing a convergence analysis provides improved and/or optimized polypharmaceutical and/or optimized polypharmaceutical compositions that have higher chances to be efficacious.
In certain embodiments, processing the searched data comprises performing an in silico convergence analysis comprising identifying commonalities between two or more of: a disease, a therapeutic indication, one or more compounds derived from one or more organisms, and therapeutic approaches from biogeographically and culturally separated locales, coincidence or convergence of one or more compounds across a plurality of TMS, and coincidence or convergence of one or more organisms across a plurality of TMS.
In certain embodiments, the in silico convergence analysis further comprises using processed data returned by the query to rank new polypharmaceutical compositions for subsequent preclinical and clinical testing for a given therapeutic indication.
In certain embodiments, processing the searched data from the plurality of TMS using the in silico convergence analysis predicts efficacy of the new and/or optimized polypharmaceutical compositions.
In some embodiments, processing the searched data from the plurality of TMS using the in silico convergence analysis identifies minimal essential compounds required for efficacy of the new and/or optimized polypharmaceutical compositions. Non-limiting examples of performing the convergence analysis of the methods described herein are provided in
In Silico Divergence Analysis
In some embodiments, processing the searched data comprises performing an in silico divergence analysis. An in silico divergence analysis provides region-specific solutions that can be included in de novo designed formulations that overcome biogeocultural boundaries. For example, performing an in silico divergence analysis provides for searching drug-target-indication relationships associated with the user query input.
In some embodiments, processing the searched data comprises performing an in silico divergence analysis comprising identifying alternative compounds derived from one or more organisms, and therapeutic approaches from biogeographically and culturally separated locales across a plurality of TMS. An example of a divergence analysis is illustrated in
In some embodiments, the in silico divergence analysis further comprises using processed data returned by the query to rank new polypharmaceutical compositions for subsequent preclinical and clinical testing for a given therapeutic indication.
In some embodiments, processing the searched data from the plurality of TMS using the in silico divergence analysis predicts efficacy of the new and/or optimized polypharmaceutical compositions.
In some embodiments, a first user input query comprises one or more user selected clinical indications. In some embodiments, the one or more user selected clinical indications is selected from cancer, cancer pain, and cancer and cancer pain.
In some embodiments, the method includes outputting processed data returned by the query. In certain embodiments, outputting the processed data returned by the query comprises outputting: a list of compounds associated with the user selected clinical indication, a list of prescription formulae for a given TMS, a list of organisms associated with the user selected clinical indication, or a combination thereof.
In some embodiments, outputting comprises outputting a list of compounds that is associated with a first user selected clinical indication, wherein the list of compounds that is associated with the first user selected clinical indication does not overlap with a list of compounds that is associated with a second user selected indication.
New Polypharmaceutical and/or Optimized Polypharmaceutical Compositions
In some embodiments, new polypharmaceutical and/or optimized polypharmaceutical compositions comprise one or more compounds derived from metabolomes of prokaryotic, Archaea, or eukaryotic organisms.
In some embodiments, the new polypharmaceutical and/or optimized polypharmaceutical compositions comprise one or more compounds derived from metabolomes of plants or fungi.
In some embodiments, the optimized polypharmaceutical compositions comprise one or more substitution compounds of an existing transcultural medicinal formulation.
In some embodiments, the optimized polypharmaceutical composition comprises a reduced number of compounds within the optimized polypharmaceutical composition as compared to an existing transcultural medicinal formulation, wherein the optimized polypharmaceutical composition comprises a minimal number of essential compounds to achieve a therapeutic outcome.
PhAROS_Brain
In some embodiments, the methods of the present disclosure comprise outputting the processed data returned by the query to the user for review by the user or for further analysis initiated by a second user query input, e.g., to identify the new polypharmaceutical and/or optimized polypharmaceutical compositions.
In certain embodiments, further analysis comprises, after outputting one or more selected from: developing training data sets for one or more machine learning models to optimize the transcultural dictionaries; populate the transcultural dictionaries with additional data developed by the machine learning algorithm; and creating, updating, annotating, processing, downloading, analyzing, or manipulating the data from the plurality of TMS. In certain embodiments, further analysis comprises developing training data sets for one or more machine learning models to optimize the transcultural dictionaries. In certain embodiments, further analysis comprises populating the transcultural dictionaries with additional data developed by a machine learning algorithm. In some embodiments, further analysis comprises creating, updating, annotating, processing, downloading, analyzing, or manipulating the data from the plurality of TMS.
In certain embodiments, populating the transcultural dictionaries with additional data developed by the machine learning algorithm comprises generating a therapeutic indication dictionary. In certain embodiments, at least one transcultural dictionary of the transcultural dictionaries comprises a search dictionary that collates Western and non-Western epistemological understanding of migraine and migraine-like patient presentations. In certain embodiments, at least one transcultural dictionary of the transcultural dictionaries comprises a search dictionary that collates Western and non-Western epistemological understanding of pain, pain-like patient symptoms. In certain embodiments, at least one transcultural dictionary of the transcultural dictionaries comprises a search dictionary that collates Western and non-Western epistemological understanding of Piper species associated with a therapeutic indication. In certain embodiments, populating the transcultural dictionaries with additional data developed by the machine learning algorithm comprises generating a dictionary for Piper species.
In certain embodiments, at least one transcultural dictionary of the transcultural dictionaries comprises a search dictionary that collates Western and non-Western epistemological understanding of cancer, cancer-like patient presentations, cytotoxic agents within TMS formulations for cancer, and cancer pain.
In certain embodiments, at least one transcultural dictionary of the transcultural dictionaries comprises a list of compounds associated with cancer pain, and a list of compounds known for treating pain.
In some embodiments, the method further comprises iteratively training the one or more machine learning models/algorithms with the one or more training data sets.
In some embodiments, the method further comprises applying a machine learning model to identify the new polypharmaceutical and/or optimized polypharmaceutical compositions. In some embodiments, the machine learning model is iteratively trained with one or more training data sets.
In some embodiments, wherein the machine learned model comprises a set of rules, wherein the set of rules are configured to: identify specific patterns of interest, therapeutic targets for subsequent processing, metadata groupings that correlate with indications across traditional medicines, identify missing plants, components or compounds, identify unknown indications for traditional medicines, identify toxic and non-toxic components and compounds, identify plant, component and compound mixtures with ranked therapeutic potential, identify plant, component and compound combination that would not be obvious or have greater therapeutic potential, than existing mixtures in isolated traditional medicines.
In some embodiments, the method comprises applying the machine-learned model to identify the new polypharmaceutical and/or optimized polypharmaceutical compositions.
In some embodiment, the PhAROS method comprises a computing server. In some embodiments, the computer server may include one or more computing devices that aggregates data in a federated database, analyzes various compilations of data entries, performs convergence analyses or divergence analyses, deconvolves modes and mechanisms associated with data entries, and trains and applies various predictive models such as machine learning models. The computing server may be referred to as data analytics platforms and, in some embodiments, a phytomedicine analytics platform for research optimization at scale. The computing server may receive, from a user device, an input that includes one or more terms, each of which may correspond to a data entry, a formula that include multiple data entries, a target, an indication, or a compound. In response, the computing server may automatically retrieve information and attributes related to the terms by parsing data from various external data sources and performing a query for data in the data store. The computing server may in turn aggregate the data and perform convergence analysis or divergence analysis to reconcile or identify the differences and conflicts in data entries retrieved from different data sources. The computing server may also apply one or more predictive models to predict the attributes of a combination of items that correspond to the data entries selected by the user. The computing server may transmit the results of its analyses directly to the client device via the network to be displayed and visualized in the interface or may transfer the results to data store, which may be accessible by client device.
In some embodiments, the computer server comprises a prediction and machine learning engine. The prediction and machine learning engine may train and apply different machine learning models to predict the attributes of a combination of data entries, such as a formulation based on several components obtained from different traditional medicine sources. The prediction and machine learning engine may predict de novo transcultural formulations reflecting integration of components derived from geographically and culturally separated locales and minimal essential therapeutic component list for a selected indication. The prediction and machine learning engine may also predict the properties of a new formulation and the efficacy of the formulation for a certain treatment or salutogenesis purpose. The prediction and machine learning engine may also be used to identify new therapeutic candidates from an input specified by the user.
In various embodiments, the prediction and machine learning engine may use various machine learning techniques and models. Example machine learning techniques include clustering, regression, classification and dimensionality reduction tailored to a specific data set and problems. Unsupervised machine learning may use data sets that are treated as ‘blind’ samples (without a label) or when classification and categorical labels are unavailable or incomplete. Supervised machine learning models such as SVM (support vector machine), ANN (artificial neural networks), which may include convolutional neural networks (CNN), recurrent neural networks (RNN) and long short-term memory networks (LSTM), DL (deep learning), Bayesian models, KNN (K-nearest neighbors), RF (random forest), ADA (AdaBoost), wisdom of crowds and ensemble predictors, virtual screening and others. The prediction and machine learning engine may also include validation models such as Monte Carlo cross-validation, Leave-One-Out (LOO) cross validation, Bootstrap Resampling, and y-randomization.
The training and use of a machine learning model may include generating a machine learning model, iteratively training the model with one or more sets of training samples, and applying the model. In various embodiments, the training techniques for a machine learning model may be supervised, semi-supervised, or unsupervised. In supervised learning, the machine learning models may be trained with a set of training samples that are labeled. For example, for a machine learning model trained to classify property of a component in a traditional medicine, the training samples may be known components labeled with their properties. In some cases, an unsupervised learning technique may be used. The samples used in training are not labeled. Various unsupervised learning technique such as clustering may be used. In some cases, the training may be semi-supervised with training set having a mix of labeled samples and unlabeled samples. A machine learning model may be associated with an objective function, which generates a metric value that describes the objective goal of the training process. For example, the training may intend to reduce the error rate of the model in generating predictions. In such a case, the objective function may monitor the error rate of the machine learning model. The objective function of the machine learning algorithm may be the training error rate in predicting properties in a training set. Such an objective function may be called a loss function. Other forms of objective functions may also be used, particularly for unsupervised learning models whose error rates are not easily determined due to the lack of labels.
Alternative Supply Chain
The PhAROS method of the present disclosure can be used to identify alternative sources for medically important phytomedical compounds. In order to widely adopt phytomedical components into mainstream medicine, the issue of supply chain availability can be addressed using the methods described herein. For example, the methods of the present disclosure can provide alternative sources of phytomedical components that may be easier to extract leading to production efficiencies.
In some embodiments, the method of the present disclosure includes first, receiving from a user in a graphical user interface (GUI), a user query input.
The user of the PhAROS method and system can include users with various access to outputs or data returned by a query. For example, the user can perform a user query input to retrieve data, and/or initiate a logical processing pipeline in order to produce data based on the user's needs and the user's use case.
In some embodiments, the user input query comprises one or more phytomedical compounds or formulations, and optionally a current source (plant or animal) and supply of the compound or formulation.
In some embodiments, the method includes processing the searched data to create processed data returned by the query from the plurality of TMS associated with the user query input. In certain embodiments, the processed data comprises a list of plant sources, known clinical indications associated with the phytomedical compounds or formulations and the TMS in which each compound was referenced. In certain embodiments, the processed data further comprises a relative abundance of the one or more compounds or formulations, wherein the relative abundance is the relative amount of the one or more compounds or formulations available. In certain embodiments, the processed data further comprises growing locations of the list of plant sources.
In certain embodiments, the processed data is cross ranked by one or more of frequency, relative abundance, availability, potency, and supply.
In some embodiments, the method includes outputting the processed data returned by the query to the user for review by the user or for further analysis initiated by a second user query input to identify the new polypharmaceutical and/or optimized polypharmaceutical compositions.
In some embodiments, the new polypharmaceutical and/or optimized polypharmaceutical compositions comprise one or more compounds derived from metabolomes of an alternative source of plants or fungi that were not previously identified for a specific use or indication. In certain embodiments, the optimized polypharmaceutical compositions comprise one or more substitution compounds of an existing transcultural medicinal formulation, wherein a source origin of the substitution compound is not found in an existing transcultural medicinal formulation.
In some embodiments, the method includes outputting a growing location comparison of a phytomedical component providing decision support for the phytomedical component supply chain (see e.g.,
In some embodiments, the method includes outputting one or more of: alternative organisms as sources of phytomedically-important compounds, new or relatively understudied organism sources of phytomedically-important compounds, and sources of phytomedically-important compounds linked to specific growing locations to inform supply chain design.
Additional Descriptions of the Pharos Methods
In some embodiments, the first user input query of the PhAROS method comprises one or more user selected clinical indications.
Migraine
In some embodiments, the one or more user selected clinical indications is migraine. In such cases, PhAROS can be used to design new polypharmaceutical approaches for treating migraine (see, e.g., Example 6). In some embodiments, outputting the processed data returned by the query comprises outputting: a list of compounds associated with the user selected clinical indication, a list of prescription formulae for a given TMS associated with the user selected clinical indication, or a combination thereof. In certain embodiments, the list of compounds is ranked by efficacy with statistical significance. See, for example,
In some embodiments, the outputting further comprises outputting molecular targets for the list of compounds that are clinically indicated for migraine across one or more TMS.
In some embodiments, the molecular targets comprise: Prelamin-A/C; Lysine-specific demethylase 4D-like; Microtubule-associated protein tau; Microtubule-associated protein tau; Endonuclease 4; Peripheral myelin protein 22; Nonstructural protein 1; Bloom syndrome protein; Bloom syndrome protein; Neuropeptide S receptor; Geminin; Histone-lysine N-methyltransferase, H3 lysine-9 specific 3; Geminin; Thioredoxin reductase 1, cytoplasmic; Acetylcholinesterase; Cholinesterase; Solute carrier organic anion transporter family member 1B1; Solute carrier organic anion transporter family member 1B3 Nuclear factor NF-kappa-B p65 subunit; p53-binding protein Mdm-2; Huntingtin; Ras-related protein Rab-9A; Survival motor neuron protein; Tyrosyl-DNA phosphodiesterase 1; Microtubule-associated protein tau; Microtubule-associated protein tau; Microtubule-associated protein tau; Nuclear receptor ROR-gamma; Aldehyde dehydrogenase 1A1; Thioredoxin glutathione reductase; 4′-phosphopantetheinyl transferase ffp; 4′-phosphopantetheinyl transferase ffp; Nonstructural protein 1; Microtubule-associated protein tau; Microtubule-associated protein tau; Type-1 angiotensin II receptor; Niemann-Pick C1 protein; MAP kinase ERK2; Nuclear receptor ROR-gamma; Alpha-galactosidase A; DNA polymerase beta; Beta-glucocerebrosidase; Nuclear factor erythroid 2-related factor 2; X-box-binding protein 1; Histone acetyltransferase GCN5; G-protein coupled receptor 55; Histone-lysine N-methyltransferase, H3 lysine-9 specific 3; DNA damage-inducible transcript 3 protein; ATPase family AAA domain-containing protein 5; Vitamin D receptor; Vitamin D receptor; Chromobox protein hom*olog 1; Thioredoxin reductase 1, cytoplasmic; DNA polymerase iota; DNA polymerase eta; Regulator of G-protein signaling 4; Beta-galactosidase; Regulator of G-protein signaling 4; Mothers against decapentaplegic hom*olog 3; Geminin; Alpha trans-inducing protein (VP16); ATPase family AAA domain-containing protein 5; ATPase family AAA domain-containing protein 5; ATPase family AAA domain-containing protein 5; DNA dC->dU-editing enzyme APOBEC-3G; Photoreceptor-specific nuclear receptor; Geminin; Ataxin-2; Glucagon-like peptide 1 receptor; ATPase family AAA domain-containing protein 5; ATPase family AAA domain-containing protein 5; ATPase family AAA domain-containing protein 5; ATPase family AAA domain-containing protein 5; Tyrosyl-DNA phosphodiesterase 1; Isocitrate dehydrogenase [NADP] cytoplasmic; Tyrosyl-DNA phosphodiesterase 1; Transcriptional activator Myb; Transcriptional activator Myb; Ubiquitin carboxyl-terminal hydrolase 1; Parathyroid hormone receptor; ATPase family AAA domain-containing protein 5; ATPase family AAA domain-containing protein 5; Telomerase reverse transcriptase; Telomerase reverse transcriptase Survival motor neuron protein; Thyroid hormone receptor beta-1; Arachidonate 15-lipoxygenase; Chromobox protein hom*olog 1; Geminin; Guanine nucleotide-binding protein G(s), subunit alpha; Pregnane X receptor; Nuclear receptor subfamily 1 group I member 2; Nuclear receptor subfamily 1 group I member 3; Pregnane X receptor; Pregnane X receptor; Pregnane X receptor; Pregnane X receptor; Nuclear receptor subfamily 1 group I member 2; Nuclear receptor subfamily 1 group I member 2; Pregnane X receptor; Pregnane X receptor; Nuclear receptor subfamily 1 group I member 2; Nuclear receptor subfamily 1 group I member 2; Nuclear receptor subfamily 1 group I member 3; Nuclear receptor subfamily 1 group I member 3; Nuclear receptor subfamily 1 group I member 3; Nuclear receptor subfamily 1 group I member 3; Nuclear receptor subfamily 1 group I member 3; Nuclear receptor subfamily 1 group I member 3; Nuclear receptor subfamily 1 group I member 3; Nuclear receptor subfamily 1 group I member 3; Nuclear receptor subfamily 1 group I member 3; Nuclear receptor subfamily 1 group I member 3; Nuclear receptor subfamily 1 group I member 3; Nuclear receptor subfamily 1 group I member 3; Nuclear receptor subfamily 1 group I member 3; Nuclear receptor subfamily 1 group I member 3; Nuclear receptor subfamily 1 group I member 3; Nuclear receptor subfamily 1 group I member 3; Nuclear receptor subfamily 1 group I member 3; and Nuclear receptor subfamily 1 group I member 3.
In some embodiments, the second user query input comprises the list of compounds.
In certain embodiments, further analysis initiated by the second user query input comprising the list of compounds comprises post-hoc screening for toxicity, chemical activity, or toxicity and chemical activity of the list of compounds. In certain embodiments, analysis comprises using the second user query input to search the data from the plurality of TMS associated with the second user query input.
In some embodiments, further analysis comprises processing the data associated with the second user query input to create a second processed data returned by the second query user input, and retrieving the second processed data based on the second query input for review by the user.
In some embodiments, the second processed data comprises a ranked list of potential minimal essential compounds required for efficacy of the new and/or optimized polypharmaceutical compositions.
In some embodiments, the list of compounds is categorized by class, identified as migraine dictionary search results, and are convergent between a plurality of TMS.
In some embodiments, the method further comprises further analysis initiated by a third user query input to identify the new polypharmaceutical and/or optimized polypharmaceutical compositions.
In some embodiments, further analysis comprises processing the data associated with the third user query input to create a third processed data returned by the query, and retrieving and outputting the third processed data based on the third user query input for review by the user.
In some embodiments, the third user query input comprises a query of neurotropic fungi associated with migraines in the plurality of TMS.
In some embodiments, the third processed data comprises one or more convergent compounds considered as alternative compounds of an existing transcultural compound with convergence between a plurality of TMS.
Pain Therapies Including Opioid-Alternative Strategies
In some embodiments, the user selected clinical indication is pain. In such cases, PhAROS can be used to design new polypharmaceutical approaches for treating pain (see, e.g., Example 1). In some embodiments, PhAROS can be used to identify novel convergent formulation components for pain (see, e.g., Example 1). A non-limiting example for identifying and/or designing novel pain formulations includes the workflow as shown in
In some embodiments, the processed data returned by the query comprises: a list of compounds associated with pain, a list of prescription formulae associated with pain, a list of organisms associated with pain, a list of chemicals associated with pain, or a combination thereof. In certain embodiments, the list of compounds, prescription formulae, organisms, and chemicals are indicated for pain across one or more TMS. See, for example,
In certain embodiments, the processed data further comprises: the identity of each TMS identified by an in silico convergent analysis, each TMS linked to one or more of: a number of compounds within the list of compounds associated with pain, a number of prescription formulae within the list of prescription formulae associated with pain, a number of organisms within the list of organisms associated with pain, and a number of chemicals within the list of chemicals associated with pain. See, for example,
In some embodiments, the list of compounds comprises a list of alkaloids or terpenes.
In some embodiments, the list of compounds comprises: a list of opioids and/or alkaloid candidate analgesics, a list of ligands for nociceptive ion channels, a list of compounds with demonstrated neuroactivity, a list of compounds with bioactivity, and a list of compounds with bioactivity associated with pain.
In some embodiments, the second user query input comprises the list of compounds.
In some embodiments, further analysis initiated by the second user query input comprising the list of compounds comprises post-hoc screening for toxicity, chemical activity, or toxicity and chemical activity of the list of compounds.
In some embodiments, further analysis comprises using the second user query input to search the data from the plurality of TMS, the data from the plurality of TMS associated with the second user query input.
In some embodiments, further analysis comprises processing the data associated with the second user query input to create a second processed data returned by the second query user input, and retrieving the second processed data based on the second query input for review by the user.
In some embodiments, the second processed data comprises a ranked list of potential minimal essential compounds required for efficacy of the new and/or optimized polypharmaceutical compositions for treating pain. In certain embodiments, the second processed data comprises a second list of compounds ranked by one or more of: class, target, pathway, and coincidence or convergence of each of the compounds across specific TMS.
In some embodiments, the second processed data comprises a list of convergent compounds within the list of compounds between one or more TMS.
In some embodiments, the second processed data comprises a list of divergent compounds within the list of compounds
In some embodiments, the second processed data comprises a list of convergent compounds within the list of compounds that is considered as alternative compounds of an existing transcultural compound convergent between or more TMS.
In some embodiments, the list of compounds comprises a list of alkaloids, convergent between two or more TMS and associated with pain.
In certain embodiments, the list of alkaloids comprises: niacin, berberine, palmatine, trigonelline, jatrorrhizine, d-pseudoephedrine, candicine, protopine, stachydrine, harmane, liriodenine, caffeine, sinoacutine, ephedrine, niacinamide, 3-hydroxytyramine, anonaine, magnoflorine, sanguinarine, cryptopine, piperine, dihydrosanguinarine, papaverine, codeine, narcotoline, higenamine, roemerine, gentianine, xanthine, theophylline, ricinine, morphine, pelletierine, meconine, narceine, xanthaline, harmine, and reserpine (see, e.g.,
In certain embodiments, the list of compounds comprises a list of terpenes convergent between one or more TMS and associated with pain.
In certain embodiments, the list of terpenes comprise: alpha-pinene, linalool, terpineol, oleanolic acid, beta-sitosterol, p-cymene, myrcene, beta-bisabolene, beta-humulene, carvacrol, beta-caryophyllene, gamma-terpinene, geraniol, 1,8-cineole, alpha-farnesene, limonene, ursolic acid, beta-selinene, terpilene, spinasterol, beta-eudesmol, citral, sabinene, stigmasterol, limonene, beta-elemenene, d-cadinene, terpinene-4-ol, uralenic acid, borneol, beta-pinene, limonin, camphene, campesterol, citronellal, isocyperol, ruscogenin, crocetin, squalene, brassicasterol, piperitenone, lycopene, toralactone, phytofluene, alpha-carotene, ecdysone, neomenthol, auroxanthin, soyasapogenol-e, cyasterone, neodihydrocarveol, guaiazulene, alpha-pinene, crataegolic acid, violaxanthin, and pathoulene (see, e.g.,
Pain Type
In some embodiments, the user input query is pain type. In such cases, PhAROS can be used to identify new polypharmaceutical compositions targeted to specific pain subtypes (see, e.g., Example 2).
In some embodiments, the processed data returned by the query comprises: a list of pain types across one or more TMS.
In some embodiments, the list of pain types comprises: abdominal, cardiac/chest, mouth, muscle, back, inflammation, joint, eye, chronic pain/inflammation, labor/postpartum, skin, throat, limb, bone, breast, ear, pelvic, intestinal, anal, pain sensitivity, rib, neuropathic, bladder, kidney, lung, menstruation, facial, liver, arthritis, fallopian tube, urethra, and vagin*l, pain. See, for example,
In some embodiments, for each pain type, the processed data comprises a list of TMS referenced from the plurality of TMS, associated with the pain type.
In some embodiments, the processed data returned by the query comprises a list of compounds associated with each pain type.
In some embodiments, the processed data further comprises a list of organisms for which the compounds within the list of compounds is derived.
In some embodiments, the processed data comprises the list of pain types and a list of organisms, wherein one or more pain types is associated with one or more organisms.
In some embodiments, the processed data comprises the list of pain types and a list of compounds, wherein one or more pain types is associated with one or more compounds.
In some embodiments, for each pain type, the processed data comprises identity of a plurality of TMS linked to one or more selected from: the pain type, one or more compounds associated with the pain type, and one or more organisms associated with the pain type.
In some embodiments, an example PhAROS OUTPUT can include all molecular targets (data integration with GO, KEGG, others) associated with chemical components of TMS formulations indicated for pain. As shown in
Piper Species-Containing Phytomedicines
In some embodiments, at least one transcultural dictionary of the transcultural dictionaries comprises a search dictionary that collates Western and non-Western epistemological understanding of Piper species associated with a therapeutic indication. See, for example, non-limiting methods described in Example 3.
In some embodiments, PhAROS is sued to identify alternatives to Piper species for anxiety, pain, relaxation, and epilepsy.
In some embodiments, populating the transcultural dictionaries with additional data developed by the machine learning algorithm comprises generating a dictionary for Piper species.
In some embodiments, the therapeutic indication is selected from pain, sedation, anxiety, depression, epilepsy, mood, and sleep.
In some embodiments, the therapeutic indication is selected from: hydropisy, gout, acne, coma, generalized hypopigmentation of hair, abnormal intrinsic pathway, abnormal female internal genitalia, pterygium, pain, gout, apoplexy, atony, headache, cancer giddiness, ring worm, epilepsy, otalgia, sciatica, hallucinations, alopecia, leucoderma/vitiligo, paralysis/hemiplegia, quartan fever ichthyosis, arthralgia, ptyriasis alba, congenital deafness alopecia furfuracea, hepatic obstruction, psychosis/insanity/mania, diseases of head and neck, bronchial asthma scrofula/cervical lymphadenitis, paroxysmal fever/intermittent fever bellas palsy, cramp/convulsion/spasm, strangury/dribbling of urine flaccidity, dyspnea, tremor, vertigo, tenesmus, poisoning flatulence, jaundice, toothache, hemorrhage, arthritis, lumbago backache, urinary incontinence, colic, weakness of stomach, sexual debility/anaphrodisia, palpitation, delerium, ptyriasis nigra, gastric dyscrasia, piles/ano rectal mass/haemorrhoids, fever with vata predominance, fatigue, insect bite, phlegmetic cough, splenic obstruction, blurring of vision, night blindness, corneal opacity, indigestion, vata-kaphaja, oedema/inflammation, anemia, chronic obstructive jaundice/chlorosis, cough/bronchitis, emaciation/cachexia, seminal disorders, pulmonary cavitation, gaseous/flatulence, disease with kapha predominance, tubercular cough/cough due to weakness or emaciation, pyrexia, diseases of spleen, dyspepsia/loss of appetite sprue/malabsorption syndrome, urinary disorders/polyuria curable disease of severe nature, obesity, cholera, asthma insomnia, sedative, diarrhea, anorexia, dysentery, dyspepsia, gonorrhea, rheumatism, bronchitis, cholagogue, emmenagogue, abdominal lump, angina pectoris, pleurodynia and intercostal neuralgia, stiffness, dryness of mouth, diseases of the mouth, diseases of head, and disease with vata predominance.
In some embodiments, the user input query comprises a list of Piper species of the family Piperaceae.
In some embodiments, said outputting the processed data returned by the query comprises outputting: a list of Piper species associated with one or more therapeutic indications.
In some embodiments, the one or more therapeutic indications is selected from pain, sedation, anxiety, depression, epilepsy, mood, and sleep.
In some embodiments, the therapeutic indication is selected from: hydropisy, gout, acne, coma, generalized hypopigmentation of hair, abnormal intrinsic pathway, abnormal female internal genitalia, pterygium, pain, gout, apoplexy, atony, headache, cancer giddiness, ring worm, epilepsy, otalgia, sciatica, hallucinations, alopecia, leucoderma/vitiligo, paralysis/hemiplegia, quartan fever ichthyosis, arthralgia, ptyriasis alba, congenital deafness alopecia furfuracea, hepatic obstruction, psychosis/insanity/mania, diseases of head and neck, bronchial asthma scrofula/cervical lymphadenitis, paroxysmal fever/intermittent fever bellas palsy, cramp/convulsion/spasm, strangury/dribbling of urine flaccidity, dyspnea, tremor, vertigo, tenesmus, poisoning flatulence, jaundice, toothache, hemorrhage, arthritis, lumbago backache, urinary incontinence, colic, weakness of stomach, sexual debility/anaphrodisia, palpitation, delerium, ptyriasis nigra, gastric dyscrasia, piles/ano rectal mass/haemorrhoids, fever with vata predominance, fatigue, insect bite, phlegmetic cough, splenic obstruction, blurring of vision, night blindness, corneal opacity, indigestion, vata-kaphaja, oedema/inflammation, anemia, chronic obstructive jaundice/chlorosis, cough/bronchitis, emaciation/cachexia, seminal disorders, pulmonary cavitation, gaseous/flatulence, disease with kapha predominance, tubercular cough/cough due to weakness or emaciation, pyrexia, diseases of spleen, dyspepsia/loss of appetite sprue/malabsorption syndrome, urinary disorders/polyuria curable disease of severe nature, obesity, cholera, asthma insomnia, sedative, diarrhea, anorexia, dysentery, dyspepsia, gonorrhea, rheumatism, bronchitis, cholagogue, emmenagogue, abdominal lump, angina pectoris, pleurodynia and intercostal neuralgia, stiffness, dryness of mouth, diseases of the mouth, diseases of head, and disease with vata predominance.
In some embodiments, outputting the processed data returned by the query comprises outputting: the list of piper species that are convergent across one or more TMS using the in silico convergent analysis.
In some embodiments, the list of Piper species comprises Piper attenuatum, Piper betle, Piper betle, Piper boehmeriaefolium, Piper borbonense, Piper capense, Piper chaba, Piper cubeba, Piper cubeba, Piper cubeba, Piper cubeba, Piper futokadsura, Piper futo-kadzura, Piper guineense, Piper hamiltonii, Piper kadsura, Piper kadsura, Piper laetispicum, Piper longum, Piper longum, Piper longum, Piper longum, Piper mullesua, Piper nigrum, Piper nigrum, Piper nigrum, Piper nigrum, Piper nigrurml., Piper puberulum, Piper pyrifolium, Piper retrofractum, Piper retrofractum, Piper retrofractum, Piper schmidtii, Piper sylvaticum, Piper sylvestre, and Piper umbellatum.
In some embodiments, each Piper species within the list of Piper species is associated with one or more TMS, therapeutic indications within the one or more TMS, sets of chemical components linked to each Pipers species and associated with the therapeutic indication, or a combination thereof.
In some embodiments, the list of chemical components for the list of Piper species associated with the therapeutic indication, anxiety, comprises piperine, guineensine, piperlonguminine, arecaidine, arecoline, beta-cadinene, beta-carotene, beta-caryophyllene, carvacrol, chavicol, diosgenin, estragole, eucalyptol, eugenol, gamma-terpinene, p-cymene, 1-triacontanol, 4-allyl-1,2-diacetoxybenzene, 4-allylbenzene-1,2-diol, 4-aminobutyric acid, allylpyrocatechol, calcium, dl-alanine-15n, dl-arginine, dl-asparagine, dl-aspartic acid, dl-valine, glutamate, glycine, hentriacontane, hydrogen oxalate, 1-ascorbic acid, 1-leucine, 1-methionine, l-proline, 1-serine, 1-threonine, malic acid, methyleugenol, nicotinate, octadecanoate, orn, phenylalanine, phytosterols, retinol, riboflavin, tyrosine cation radical, vitamin e, 4-allylcatechol, norcepharadione b, piperolactam a, piperolactam c, piperine, piperlongumine, d-fructose, d-glucose, phytosterols, (+)-sesamin, (−)-hinokinin, (−)-yatein, 1,4-cineole, 1,8-cineol, 1,8-cineole, 1-4-cineol, alpha-cubebene, alpha-pinene, alpha-terpinene, alpha-terpineol, beta-bisabolene, beta-caryophyllene, beta-cubebene, beta-pinene, caryophyllene, cineol, d-limonene, delta-cadinene, dipentene, gamma-terpinene, humulene, ledol, limonene, linalol, linalool, myrcene, ocimene, p-cymene, piperine, sabinene, terpineol, (+)-sabinene, (+)-zeylenol, (−)-clusin, (−)-cubebinin, (−)-cubebininolide, 2,4,5-trimethoxybenzaldehyde, allo-aromadendrene, alpha-muurolene, alpha-phellandrene, alpha-thujene, apiole, asarone, aschantin, azulene, beta-elemene, beta-phellandrene, bicyclosesquiphellandrene, cadinene, calamene, calamenene, copaene, cubebin, cubebinolide, cubebol, cubenol, dillapiole, eo, epicubenol, gamma-humulene, heterotropan, muurolene, nerolidol, piperenol a, piperenol b, piperidine, sabinol, safrole, terpinolene, (+)-4-iso-propyl-1-methyl-cyclohex-1-en-4-ol, (+)-car-4-ene, (+)-crotepoxide “(−)-5-o-methoxy-hinokinin” (−)-cadinene, (−)-cubebinone, (−)-di-o-methyl-thujaplicatin methyl ether, (−)-dihydro-clusin, (−)-dihydro-cubebin, (−)-isoyatein, 1-isopropyl-4-methylene-7-methyl-1,2,3,6,7,8,9-heptahydro, 10-(alpha)-cadinol, “3(r)-3-4-dimethoxy-benzyl-2(r)-3-4-methylenedioxy-benzyl-butyrolactone”, alpha-o-ethyl-cubebin, beta-o-ethyl-cubebin, cadina-1-9(15)-diene, cesarone, cubebic acid, d-delta-4-carene, gum, hemi-ariensin, 1-cadinol, manosalin, resinoids, resins, trans-terpinene, (e)-citral, (z)-citral, citral, dihydroanhydropodorhizol, dihydrocubebin “(8r,8r)-4-hydroxycubebinone”, “(8r,8r,9s)-5-methoxyclusin”, 1-(2,4,5-trimethoxyphenyl)-1,2-propanedione, cubeben camphor, cubebin, ethoxyclusin, heterotropan, magnosalin, (+)-cubenene, (+)-delta-cadinene, 1,4-cineole, arachidic acid, beta-cadinene, dihydrocubebin, docosanoic acid, eucalyptol, hinokinin, oleic acid, palmitic acid, yatein, (+)-piperenol b, (+)-sabinene, (+)-zeylenol, (−)-clusin, (−)-cubebinin, (−)-cubebininolide, (−)-dihydroclusin “(8r,8r)-4-hydroxycubebinone”, “(8r,8r,9s)-5-methoxyclusin” 1-epi-bicyclosesquiphellandrene, 2,4,5-trimethoxybenzaldehyde, alpha-muurolene, calamenene, chembl501119, chembl501260, crotepoxide, cubebin, cubebinone, cubebol, cyclohexane, epizonarene, ethoxyclusin, hexadecenoic acid, isohinokinin, isoyatein, 1-asarinin, lignans machilin f, octadeca-9,12-dienoic acid, octadecanoate, picrotoxinum, piperidine, thujaplicatin, unii-5vg84p9unh, zonarene, (+)-deoxy, (+)-piperenol a, acetic acid-((r)-6,7-methylenedioxy-3-piperonyl-1,2-dihydro-2naphthylmethyl ester), cubebinol, hibalactone, isocubebinic ether, podorhizon, kadsurin a, isodihydrofutoquinol b, denudatin b, kadsurenone, elemicin, futoquinol, kadsurin a, sitosterol, î′-sitosterol, stigmasterol, (+)-acuminatin, (e,7s,11r)-3,7,11,15-tetramethylhexadec-2-en-1-ol, phytol, (â±)-galgravin, 4-(2r,3r,4s,5s)-5-(1,3-benzodioxol-5-yl)-3,4-dimethyl-2-tetrahydrofuranyl-2-methoxyphenol, machilin f, asaronaldehyde, asarylaldehyde, chicanine, crotepoxide, futoxide, futoamide, futoenone, futokadsurin a, futokadsurin b, futokadsurin c, galbacin, galbelgin, kadsurenin b, kadsurenin c, kadsurenin k, kadsurenin l, kadsurenin m, machilusin, n-isobutyldeca-trans-2-trans-4-dienamide, piperlactam s, veraguensin, zuonin a, artecanin, piperine, piperitenone, piplartine, pisatin, sesamin, undulatone, 1,2,15,16-tetrahydrotanshiquinone, 1-undecylenyl-3,4-methylenedioxybenzene, guineensine, hexadecane, laurotetanine, lawsone, piperidine, piperlonguminine, sesamol, beta-caryophyllene, p-cymene, piperine, piperlongumine, 2-phenylethanol “4-methoxyacetophenone”, 6,7-dibromo-4-hydroxy-1h,2h,3h,4h-pyrrolo1,2-apyrazin-1-one, alpha thujene, aristololactam, diaeudesmin, dihydrocarveol, eicosane, ent-zingiberene, fargesin, guineensine, heneicosane, heptadecane, hexadecane, 1-asarinin, lignans machilin f, methyl 3,4,5-trimethoxycinnamate, nonadecane, octadecane, phytosterols, piperlonguminine, pipernonaline, piperundecalidine, pluviatilol, terpinolene, triacontane, (2e,4e)-n-isobutyl-2,4-decadienamide, isobutyl amide, yangonin, 10-methoxyyangonin, 11-methoxyyangonin, 11-hydroxyyangonin, desmethoxyyangonin, 11-methoxy-12-hydroxydehydrokavain, 7,8-dihydroyangonin, kavain, 5-hydroxykavain, 5,6-dihydroyangonin, 7,8-dihydrokavain, 5,6,7,8-tetrahydroyangonin, 5,6-dehydromethysticin, methysticin, 7,8-dihydromethysticin, (−)-bornyl ferulate, (−)-bornyl-caffeate, (−)-bornyl-p-coumarate, 1-cinnamoylpyrrolidine, 11-hydroxy-12-methoxydihydrokawain, 2,5,8-trimethyl-1-napthol, 3,4-methylene dioxy cinnamic acid, 3a,4a-epoxy-5b-pipermethystine, 5-methyl-1-phenylhexen-3-yn-5-ol, 5,6,7,8-tetrahydroyangonin2, 9-oxononanoic acid, benzoic acid, bornyl cinnamate, caproic acid, cinnamalacetone, cinnamalacetone2, cinnamic acid, desmethoxyyangonin, dihydro-5,6-dehydrokawain, dihydro-5,6-dehydrokawain2, dihydrokavain, dihydrokavain2, dihydromethysticin, flavokawain a, flavokawain b, flavokawain c, glutathione, methysticin2, mosloflavone, octadecadienoic acid methyl ester, p-hydroxy-7,8-dihydrokavain, p-hydroxykavain, phenyl acetic acid, pipermethystine, prenyl caffeate, nectandrin b, neferine, (+)-limonene, 1,8-cineole, alpha-bulnesene, alpha-cubebene, alpha-guaiene, alpha-gurjunene, alpha-humulene, alpha-pinene, alpha-terpinene, alpha-terpineol, alpha-terpineol acetate, alpha-trans-bergamotene, arachidic acid, astragalin, behenic acid, beta-bisabolene, beta-carotene, beta-caryophyllene, beta-cubebene, beta-farnesene, beta-pinene, beta-selinene, beta-sitosterol, borneol, butyric acid, caffeic acid, campesterol, camphene, camphor, carvacrol, caryophyllene, cedrol, cinnamic acid, cis-carveol, citral, d-limonene, delta-cadinene, dl-limonene, eugenol, fat, gamma-terpinene, hexanoic acid, hyperoside, isocaryophyllene, isoquercitrin, kaempferol, 1-alpha-phellandrene, 1-limonene, lauric acid, limonene, linalol, linalool, linoleic acid, monoterpenes, myrcene, myristic acid, myristicin, myrtenal, myrtenol, niacin, ocimene, oleic acid, p-coumaric acid, p-cymene, palmitic acid, perillaldehyde, piperine, quercetin, quercitrin, rhamnetin, rutin, sabinene, sesquiterpenes, stearic acid, stigmasterol, trans-carveol, trans-pinocarveol, (−)-cubebin, (z)-ocimenol, 1(7),2-p-menthadien-4-ol, 1(7),2-p-menthadien-6-ol, 1-terpinen-4-ol, 1-terpinen-5-ol, 2,8-p-menthadien-1-ol, 2-methyl-pentanoic acid, 2-undecanone, 3,8(9)-p-menthadien-1-ol, 3-methyl-butyric acid, 4-methyl-triacontane, acetophenone, alpha-bisabolene, alpha-copaene, alpha-linolenic acid, alpha-phellandrene, alpha-santalene, alpha-selinene, alpha-thujene, alpha-tocopherol, alpha-zingiberene, ar-curcumene, ascorbic acid, benzoic acid, beta-bisabolol, beta-caryophyllene alcohol, beta-elemene, beta-phellandrene, beta-pinone, boron, calamene, calamenene, calcium, car-3-ene, carvetonacetone, carvone, caryophyllene alcohol, caryophyllene-oxide, chavicine, chlorine, choline, chromium, cis-nerolidol, cis-ocimene, cis-p-2-menthen-1-ol, citronellal, citronellol, clovene, cobalt, copper, cryptone, cubebine, cuparene, delta-3-carene, delta-elemene, dihydrocarveol, dihydrocarvone, elemol, eo, feruperine, fluoride, gaba, gamma-cadinene, gamma-muurolene, germacrene-b, germacrene-d, globulol, guineensine, heliotropin, hentriacontan-16-ol, hentriacontan-16-one, hentriacontane, hentriacontanol, hentriacontanone, iodine, iron, isochavicine, isopiperine, isopulegol, limonen-4-ol, lipase, magnesium, manganese, methyl-eugenol, n-formylpiperidine, n-hentriacontane, n-heptadecane, n-nonadecane, n-nonane, n-pentadecane, n-tridecane, nerolidol, nickel, oxalic acid, p-cymen-8-ol, p-cymene-8-ol, p-menth-8-en-1-ol, p-menth-8-en-2-ol, p-methyl-acetophenone, pellitorine, phenylacetic acid, phosphorus, phytosterols, piperanine, pipercide, piperettine, pipericine, piperidine, piperitone, piperonal, piperonic acid, piperylin, piperyline, potassium, pyrrolidine, pyrroperine, retrofractamide-a, riboflavin, safrole, sesquisabinene, silica, sodium, spathulenol, starch, sulfur, terpinen-4-ol, terpinolene, thiamin, thujene, tocopherols, trans-nerolidol, trichostachine, ubiquinone, water, zinc, (−)-3,4-dimethoxy-3,4-demethylenedioxy-cubebin, (−)-phellandrene, 1,1,4-trimethylcyclohepta-2,4-dien-6-one, 1,8(9)-p-menthadien-4-ol, 1,8(9)-p-menthadien-5-ol, 1,8-menthadien-2-ol, 1-(2,4-decadienoyl)-pyrrolidine, 1-(2,4-dodecadienoyl)-pyrrolidine, 1-alpha-phellandrene, 1-piperyl-pyrrolidine, 2-trans-4-trans-8-trans-piperamide-c-9-3, 2-trans-6-trans-piperamide-c-7-2, 2-trans-8-trans-piperamide-c-9-2, 2-trans-piperamide-c-5-1, 3,4-dihydroxy-6-(n-ethyl-amino)-benzamide, 4,10,10-trimethyl-7-methylene-bicyclo-(6.2.0)decane-4-car . . . , 4-methyl-tritriacontane, 5,10(15)-cadinen-4-ol, 6-trans-piperamide-c-7-1, 8-trans-piperamide-c-9-1, acetyl-choline, alpha-amorphene, alpha-cis-bergamotene, alpha-cubebine, beta-cubebine, carvone-oxide, caryophylla-2,7(15)-dien-4-beta-ol, caryophylla-2,7(15)-dien-4-ol, caryophylla-3(12),7(15)dien-4-beta-ol, caryophyllene-ketone, cis-2,8-menthadien-2-ol, cis-sabinene-hydrate, cis-trans-piperine, citronellyl-acetate, cumaperine, dihydropipercide, epoxydihydrocaryophyllene, eugenol-methyl-ether, geraniol-acetate, geranyl-acetate, isobutyl-caproate, isobutyl-isovalerate, isochavinic acid, kaempferol-3-o-arabinosyl-7-o-rhamnoside, linalyl-acetate, m-mentha-3(8),6-diene, m-methyl-acetophenone, methyl-caffeic acid-piperidide, methyl-carvacrol, methyl-cinnamate, methyl-cyclohepta-2,4-dien-6-one, methyl-heptanoate, methyl-octanoate, n-(2-methylpropyl)-deca-trans-2-trans-4-dienamide, n-5-(4-hydroxy-3-methoxy-phenyl)-pent-trans-2-dienoyl-piperidine, n-butyophenone, n-heptadecene, n-isobutyl-11-(3,4-methylenedioxy-phenyl)-undeca-trans-2-trans-4-trans-10-trienamide, n-isobutyl-13-(3,4-methylenedioxy-phenyl)-trideca-trans-2-trans-4-trans-12-trienamide, n-isobutyl-eicosa-trans-2-trans-4-cis-8-trienamide, n-isobutyl-eicosa-trans-2-trans-4-dienamide, n-isobutyl-octadeca-trans-2-trans-4-dienamide, n-methyl-pyrroline, n-pentadecene, n-trans-feruloyl-piperidine, nerol-acetate, p-cymene-8-methyl-ether, p-menth-cis-2-en-1-ol, p-menth-trans-2-en-1-ol, phytin-phosphorus, piperolein-a, piperolein-b, piperolein-c, piperoleine-b, polysaccharides, quercetin-3-o-alpha-d-galactoside, rhamnetin-o-triglucoside, terpin-1-en-4-ol, terpinyl-acetate, trans-cis-piperine, trans-sabinene-hydrate, trans-trans-piperine, chavicol, pinocembrin, piperine, piperitenone, piplartine, trans-pinocarveol, 1(7),2-p-menthadien-4-ol, 1(7),2-p-menthadien-6-ol, 1(7),8(10)-p-menthadien-9-ol, 3,8(9)-p-menthadien-1-ol, chavicine, cis-p-2-menthen-1-ol, cryptone, cryptopimaric acid, dihydrocarveol, piperanine, piperettine, piperidine, piperitone, piperitylhonokiol, piperonal, sarmentosine, sesquisabinene, (+)-alpha-phellandrene, (+)-endo-beta-bergamotene, (−)-camphene, (−)-linalool, alpha-humulene, beta-caryophyllene, beta-pinene, capsaicin, d-citronellol, dipentene, eucalyptol, eugenol, gamma-terpinene, myrcene, p-cymene, piperine, testosterone, (+)-sabinene, (z)-.beta.-ocimenol, 1,8-menthadien-4-ol, 16-hentriacontanone, 2,6-di-tert-butyl-4-methylphenol, 3-carene, 7-epi-.alpha.-eudesmol, aclnahmy, acetic acid, alpha thujene, amide 4, beta-alanine, bicyclogermacrene, butylhydroxyanisole, carotene, caryophyllone oxide, cepharadione a, chebi:70093, cholesterol formate, cis-.alpha.-bergamotene, crypton, cubebin, Curcuma longa, dehydropipernonaline, dextromethorphan, dl-arginine, guineensine, hedycaryol, hentriacontane, isobutyramide, kakoul, 1-ascorbic acid, 1-serine, 1-threonine, menthadien-5-ol, methylenedioxycinnamic acid, moupinamide, nonane, octane, oxirane, p-anisidine, p-mentha-2,8-dien-1-ol, paroxetine, pellitorine, phytosterols, piperettine, piperidine, piperidine-2-carboxylic acid, pipernonaline, piperolactam d, piperolein a, piperolein b, piperonal, pyrocatechol, retrofractamide a, retrofractamide b, retrofractamide c, sarmentine, sodium nitroprussiate, tannic acid, terpinen-4-ol, trichostachine, wisanine, (2e,4e,8z)-n-isobutyl-eicosa-2,4,8-trienamide, (2e,4z)-5-(4-hydroxy-3-methoxyphenyl)-1-(1-piperidinyl)-2,4-pentadien-1-one, (e,e)-, 1-piperoyl-, n-idobutyl-13-(3,4-methylenedioxyphenyl)-2e,4e,12e-tridecatrienamide, pyrrolidine, asarinin, grandisin, piperine, piperlonguminine, piplartine, sesamin, trans-pinocarveol, î″-fa*garine, (+)-bornyl piperate, (1-oxo-3-phenyl-2e-propenyl)pyrrolidine, “(7r,8r)-3,4-methylenedioxy-4,7-epoxy-8,3-neolignan-7e-ene”, “(7s,8r)-4-hydroxy-4,7-epoxy-8,3-neolignan-(7e)-ene”, “(7s,8r)-4-hydroxy-8,9-dinor-4,7-epoxy-8,3-neolignan-7-aldehyde”, (â±)-erythro-1-(1-oxo-4,5-dihydroxy-2e-decaenyl)piperidine, (a*)-threo-1-(1-oxo-4,5-dihydroxy-2e-decaenyl)piperidine, (â±)-threo-n-isobutyl-4,5-dihydroxy-2e-octaenamide, 1(7),2-p-menthadien-4-ol, 1(7),2-p-menthadien-6-ol, 1-(1,6-dioxo-2e,4e-decadienyl)piperidine, 1-(1-oxo-2e,4e-dodedienyl)pyrrolidine, 1-(1-oxo-2e-decaenyl) piperidine, 1-(1-oxo-3-phenyl-2e-propenyl)piperidine, 1-1-oxo-3(3,4-methylenedioxy-5-methoxyphenyl)-2zpropenyl piperidine, 1-1-oxo-3(3,4-methylenedioxyphenyl)-2e-propenylpiperidine, 1-1-oxo-3(3,4-methylenedioxyphenyl)-2e-propenylpyrrolidine, 1-1-oxo-3(3,4-methylenedioxyphenyl)-2z-propenylpiperidine, 1-1-oxo-3(3,4-methylenedioxyphenyl)propylpiperidine, 1-1-oxo-5(3,4-methylenedioxyphenyl)-2e,4e-pentadienylpyrrolidine, 1-1-oxo-5(3,4-methylenedioxyphenyl)-2e,4z-pentadienyl pyrrolidine, 1-1-oxo-5(3,4-methylenedioxyphenyl)-2e,4z-pentadienylpiperidine, 1-1-oxo-5(3,4-methylenedioxyphenyl)-2z,4e-pentadienyl piperidine, 1-1-oxo-5(3,4-methylenedioxyphenyl)-2z,4e-pentadienyl pyrrolidine, 1-1-oxo-7(3,4-methylenedioxyphenyl)-2e,4e,6e-heptatrienylpyrrolidine, 1-1-oxo-9(3,4-methylenedioxyphenyl)-2e,8e-nonadienyl piperidine, pipernonaline, 1-terpinen-5-ol, 3,8(9)-p-menthadien-1-ol “4-desmethylpiplartine”, “5-hydroxy-7,3,4-trimethoxyflavone” cenocladamide, chavicine, cis-p-2,8-menthadien-1-ol, cis-p-2-menthen-1-ol, cryptone, dehydropipernonaline, guineensine, kaplanin, menisperine, methyl piperate, “methyl-(7r,8r)-4-hydroxy-8,9-dinor-4,7-epoxy-8,3-neolignan-7-ate”, n-isobutyl-(2e,4e)-octadecadienamide, n-isobutyl-(2e,4e)-octadienamide, n-isobutyl-(2e,4e,14z)-eicosatrienamide, n-isobutyl-2e,4e,12z-octadecatrienamide, n-isobutyl-2e,4e-dodedienamide, n-isobutyldeca-trans-2-trans-4-dienamide, neopellitorine b, pipataline, piperamide c 7:1(6e), piperamide c 9:1(8e), piperamide c 9:2(2e,8e), piperamide c 9:3(2e,4e,8e), piperamine, piperanine, piperchabamide a, piperchabamide b, piperchabamide c, piperchabamide d, pipercide, retrofractamide b, piperenol a, piperettine, piperitone, piperlonguminine, piperolactam a, piperolein a, piperolein b, piperonal, pipnoohine, pipyahyine, “rel-(7r,8r,7r,8r)-3,4-methylenedioxy-3,4,5,5-tetramethoxy-7,7-epoxylignan”, “rel-(7r,8r,7r,8r)-3,4,3,4-dimethylenedioxy-5,5-dimethoxy-7,7-epoxylignan”, retrofractamide a, retrofractamide b, sarmentine, sarmentosine, sesquisabinene, xanthoxylol, zp-amide a, zp-amide b, zp-amide c, zp-amide d, zp-amide e, n-isobutyl-4,5-dihydroxy-2e-decaenamide, n-isobutyl-4,5-epoxy-2e-decaenamide, pipercycliamide, wallichinine, brachystamide d, friedlein, phytosterols, piperine, piperlongumine, 1-asarinin, phytosterols, piperine, asperphenamate, aurantiamide, phytosterols, piperettine, and sylvatine (See
In some embodiments, the list of chemical components for at least one Piper species comprises bis-noryangonin, 11-methoxy-nor-yangonin, 5,6-dehydrokawain, dihydromethysticin, and yangonin.
In some embodiments, the at least one Piper species is Piper methysticum.
In particular, PhAROS was used to identify alternatives to P. methysticum for anxiety, pain, relaxation and epilepsy based on the restricted biogeography of P. methysticum and reports of compounds within P. methysticum with purported liver toxicity.
In some embodiments, the second user query input for further analysis initiated by the second user query input comprises the list of chemical components: bis-noryangonin, 11-methoxy-nor-yangonin, 5,6-dehydrokawain, dihydromethysticin, and yangonin.
In some embodiments, further analysis initiated by the second user query input comprising the list of chemical components comprises using the second user query input to search transcultural dictionaries, the data from the plurality of TMS associated with the second user query input.
In some embodiments, further analysis comprises processing the data associated with the second user query input to create a second processed data returned by the second query user input, and retrieving the second processed data based on the second query user input.
In some embodiments, the second processed data comprises a list of non-Piper species comprising the list of chemical components.
In some embodiments, the list of non-Piper species comprises Petroselinum crispum, Dioscorea collettii, Dioscorea hypoglauca, Gentiana algida, Rubia cordifolia, and Alpinia speciosa.
In some embodiments, processing the data associated with the second query user input comprises screening for non-Piper species comprising the list of chemical components.
In some embodiments, further analysis comprises processing the data associated with the second user query input to create a second processed data returned by the second query user input, and retrieving the second processed data based on the second query user input.
In some embodiments, the second user query input comprises a biogeography of P. methysticum and a list of therapeutic indications, wherein the list of therapeutic indications comprises anxiety, mood, and depression.
In some embodiments, the second processed data comprises a list of non-Piper species associated with anxiety, mood, depression, or a combination thereof found in non-piper species within the biogeography of P. methysticum.
In some embodiments, the list of non-Piper species comprises Glycyrhizza uralensis/radix, Paeonia lactiflora, Scutellaria baicalensis, Panax ginseng, Saposhnikovia divaicata, and Poria cocos.
Cancer
In some embodiments, the first user input query comprises one or more user selected clinical indications.
In some embodiments, the one or more user selected clinical indications is selected from cancer, cancer pain, and cancer and cancer pain. In such cases, PhAROS_CONVERGE convergence analysis and PhAROS_DIVERGE divergence analysis are used to identify potential cytotoxic agents that could become new cancer fighting drugs within complex TMS formulations for cancer and identify compound sets with potential for cancer pain over other pain subtypes. See, for example, Example 4.
In some embodiments, said outputting the processed data returned by the query comprises outputting: a list of compounds associated with the user selected clinical indication, a list of prescription formulae for a given TMS, a list of organisms associated with the user selected clinical indication, or a combination thereof.
In some embodiments, the outputting further comprises outputting cytotoxic agents within the list of compounds that are indicated for pain and cancer across one or more TMS.
In some embodiments, outputting further comprises outputting the list of organisms associated with cancer and pain across one or more TMS.
In some embodiments, the list of compounds is categorized by class, identified as migraine dictionary hits, and are convergent between two or more TMS.
In some embodiments, the outputting further comprises outputting a list of compounds that is associated with a first user selected clinical indication, wherein the list of compounds that is associated with the first user selected clinical indication does not overlap with a list of compounds that is associated with a second user selected indication.
In some embodiments, the first user selected clinical indication is cancer, and the second user selected indication is pain.
PhAROS System
Aspects of the present disclosure include systems for carrying out the steps of the methods described herein.
An aspect of the present disclosure provides a phytomedicine analytics for research optimization at scale (PhAROS) system for analyzing a plurality of traditional medical systems in a single computational space, the PhAROS system comprising: a computer server configured to communicate with one or more user clients (PhAROS_USER) comprising: (a) a database (PhAROS_BASE) comprising a memory configured to store a collection of data, the collection of data comprising: raw and optionally pre-processed data from a plurality of traditional medicine data sets; and optionally one or more of: plant data sets; literature-based text documents (corpus); and machine learning data sets; (b) a computer core processor (PhAROS_CORE), wherein the PhAROS_CORE is configured to receive and process the collection of data from the PhAROS_BASE to generate processed data; (c) one or more searchable repositories having data and optionally pre-processed data, wherein each searchable repository comprises a memory configured to store data entries, wherein the PhAROS_CORE is configured to send the processed data to and receive data from each of the searchable repositories, wherein each of the searchable repositories is configured to receive processed data from the PhAROS_CORE and send data and optionally pre-processed data to the PhAROS_CORE; (d) a computer-readable storage medium storing executable instructions that, when executed by a hardware processor, cause the PhAROS_CORE to communicate with the PhAROS_BASE and one or more of the searchable repositories to analyze data from a plurality of the traditional medicine data sets to produce an output responsive to a user query input into the PhAROS system.
In some embodiments, the PhAROS_CORE is further configured to manage, direct, collect, parse, and filter the collection of data from the PhAROS_BASE to generate processed data.
In some embodiments, the PhAROS system further comprises one or more user clients (PhAROS_USER).
In some embodiments, at least one PhAROS_USER client has a graphical user interface (GUI). The interface such as a graphical user interface (GUI) may be the visual component of the application for a user to enter inputs, selects different data entries, and views results generated by the computing server. In some embodiments, the interface may not include visual elements but allow a user to interface with the computing server directly through code instructions, such as in the case of an API. The interface may display various visualizations of data and results. For example, the interface may display various charts and analytics that summarize the results of a data analysis. The interface may also display visual data geographically such as by showing the associated locations of various data entries in a digital map. The interface may include various interactive elements such as checklists, dialog boxes, dropdown menus, tabs, and other control elements.
In some embodiments, at least one PhAROS_USER client is configured to allow the user to communicate with the PhAROS_CORE.
In some embodiments, at least one PhAROS_USER client is configured to allow the user to communicate with at least one of the searchable repositories.
In some embodiments, at least one PhAROS_USER client is configured to allow the user to communicate with the PhAROS_CORE, PhAROS_BASE, and the searchable repositories.
In some embodiments, at least one searchable repository comprises: a first meta-pharmacopeia database (PhAROS_PHARM) comprising (i) data from PhAROS_BASE; and (ii) pre-processed data processed from data in the PhAROS_BASE related to at least one of: medical formulations; organisms; medical compound data sets; therapeutic indications; processed and normalized formalized pharmacopeias from one or more geographic regions associated with traditional medicines.
In some embodiments, the one or more geographic regions is selected from: Japan, China, India, Korea, South East Asia, Middle East, North America, South America, Russia, India, Africa, Europe, and Australia.
In some embodiments, the one or more processed and normalized formalized pharmacopeias comprises processed, translated normalized, individual published datasets or case reports in the scientific literature that document relationships between medicinal plants and disease indications.
In some embodiments, the one or more processed and normalized formalized pharmacopeias comprises processed, curated ethical partnerships, indigenous, cultural phytomedical formulations.
In some embodiments, the one or more processed and normalized formalized pharmacopeias comprises processed contemporary and historical herbologies that document relationships between medicinal plants and disease indications (e.g., Hildegard of Bingen, Causae et Curae, Physica).
In some embodiments, the one or more processed and normalized formalized pharmacopeias comprises processed, translation of resources from original languages processed using approaches selected from one or more of: machine literal translation, natural language processing, multilingual concept extraction or conventional translation, Optical character recognition (OCR) of historical materials, and artificial intelligence (AI)-driven intent translation.
In some embodiments, at least one searchable repository (PhAROS_CONVERGE) comprises data and pre-processed data that allow identification of commonalities in therapeutic approaches from biogeographically and culturally traditional medical systems (TMS).
In some embodiments, the data and pre-processed data of the PhAROS_CONVERGE is further configured to allow identification of efficacious medical components across traditional medicine systems.
In some embodiments, the data and pre-processed data of the PhAROS_CONVERGE is further configured to allow ranking optimization of de novo compound formulations and compound mixtures by utilizing transcultural components for subsequent preclinical and clinical testing for a given therapeutic indication.
In some embodiments, the data and pre-processed data of the PhAROS_CONVERGE comprises at least one of: therapeutic indication dictionaries related to traditional medical systems that reflect modern and historical terminology, and/or Western and non-Western epistemologies; medical formulation compositions related to traditional medical systems; compound data sets for a given therapeutic indication; and a proprietary digital composition index (n-dimensional vector and/or fingerprint).
In some embodiments, the computer-readable storage medium storing executable instructions, when executed by the hardware processor, cause the hardware processor to: develop training data sets for one or more machine learning algorithms to optimize the searchable repositories for a user; populate the one or more searchable repositories with additional data developed by the machine learning algorithm; and create, update, annotate, process, download, analyze, or manipulate the collection of data received by the Pharos_CORE.
In some embodiments, the computer-readable storage medium storing executable instructions, when executed by the hardware processor, cause the PhAROS_CORE to: initiate a user to provide the user query input on the PhAROS_USER client, wherein the PhAROS_USER client is configured to communicate with the PhAROS_CORE and optionally the searchable repositories; search the user query input within the PhAROS_CORE, the searchable repositories, or a combination thereof, retrieve the processed data based on the user's query input for review by the user in PhAROS_USER; optionally initiate further processing of the retrieved processed data, if inquired by the user.
In some embodiments, the PhAROS_USER client further comprises a graphical data processing environment (PhAROS_FLOW) configured to allow the user to process data without or with reduced amount of at least one of: coding, system modeling tools comprising machine learning, or artificial intelligence (AI) tools.
In some embodiments, the machine learning and AI tools are selected from one or more of: support vector machine, artificial neural networks, deep learning, Naïve Bayesian, K-nearest neighbors, random forest, AdaBoost wisdom of crowds and ensemble predictors, and others, validation (such as MonteCarlo cross-validation, Leave-One-Out cross validation, Bootstrap Resampling, and y-randomization).
In some embodiments PhAROS contains a suite of informatics tools, data pipelines and data repositories allowing for user access and decision support tools for identifying a drug, a compound, a mixture, or an organism discovery.
The PhAROS system contains a suite of informatics tools, data pipelines and data repositories allowing for user access and decision support tools for drug discovery. Depending on the need of the user/stakeholder, data repositories, and pre-processed repositories, can be cross correlated, analyzed and assessed for particular questions, these subcomponents and data sets, include but are not limited to: PhAROS_USER, PhAROS_CORE, PhAROS_BRAIN, PhAROS_FLOW, PhAROS_PHARM, PhAROS_CONVERGE, PhAROS_DIVERGE, PhAROS_CHEMBIO, PhAROS_BIOGEO, PhAROS_METAB, PhAROS_MICRO, PhAROS_CURE, PhAROS_QUANT, PhAROS_POPGEN, PhAROS_TOX, PhAROS_BH, PhAROS_EPIST, and PhAROS_BASE.
The PhAROS system includes a computing server, in accordance with some embodiments. The example computing server may include one or more computers such as one or more server-side computing devices and cloud computing devices. The server-side computing device and the cloud computing devices each may include one or more processors and memory. The memory may store computer code that includes instructions. The instructions, when executed by one or more processors, cause the processors to perform one or more processes described herein, such as one or more processes or workflows defined by instructions. In some embodiments, the server-side computing device and the cloud computing devices may be implemented in a distributed manner. For example, the server-side computing device may communicate with the cloud computing devices via the network. The cloud computing devices may include multiple computers operated in a distributed fashion. The computing server may also take other forms. For example, instead of implementing cloud computing devices, the computing server may take the form of a non-cloud server. The computing devices may be one of the on-site servers that communicate with the server-side computing device locally. In some embodiments, the computing server may take the form of a personal computer that executes code instructions directly instead of using any additional computing devices. Other suitable implementations are also possible.
In some embodiments, the computing server may include data mining engine, data integration engine, prediction and machine learning engine, pharmacopeia database, convergence analysis engine, chemical and biological substance database, plant and organism database, metabolomics database, microbiome database, cure prediction engine, quantitative analysis engine, population genetics database, toxicological and side-effect prediction engine, causality engine, epistemology engine, and visualization engine. In various embodiments, the computing server may include fewer or additional components, depending on the functionalities of the computing server in various embodiments. The computing server also may include different components. The functions of various components in computing server may be distributed in a different manner than described below. This particular example computing server may be used for a phytomedicine analytics platform. For other types of federated databases, different components may be used. While the phytomedicine analytics platform is used as an example throughout this description, various techniques and processes discussed herein may be applied to other federated database, medicine related or not.
The components of the computing server may be embodied as software engines that include code (e.g., program code comprised of instructions, machine code, etc.) that is stored on an electronic medium (e.g., memory and/or disk) and executable by one or more processors (e.g., CPUs, GPUs, other general processors). The components also could be embodied in hardware, e.g., field-programmable gate arrays (FPGAs) and/or application-specific integrated circuits (ASICs), that may include circuits alone or circuits in combination with firmware and/or software. Each component may be a combination of software code instructions and hardware such as one or more processors that execute the code instructions to perform various processes. Each component may include all or part of the example structure and configuration of the computing machine described in
The computing server may take the form of a tool accessible within the company for research and development purposes. The computing server may provide a GUI, use mySQL or similar architecture, and enable API code linking to publicly available external databases. In some embodiments, the computing server may take the form of an online platform made available as a science gateway and virtual research environment for drug discovery to users (industry, academia, agencies, healthcare providers) as a fee for service. In some embodiments, the computing server may serve as an exploration tool for consumers and patients.
Data mining engine parses data from various sources, such as external data servers, various databases or subsystems that may be stored in data store, and other unstructured sources such as the Internet and documents. In some embodiments, the data mining engine may include a format converter that changes data formats to a standardized format used in the computing server. For example, a user may provide a search term related to a traditional medicine formulation. The computing server may generate a query to an external data server, such as a traditional Chinese medicine (TCM) database, through a call of the API of the external data server. In response, the external data server provides a data payload in a format defined by the external data server, such as JSON, XML, CSV, or another data-serialization format. The data mining engine may parse data in the payload based on keys and relevant fields and convert the parsed data to a standardized format used in the computing server. The data mining engine may also retrieve data entries from data store through a query language such as SQL. In some embodiments, the data mining engine may also conduct Internet search of key search terms specified by the users. The data mining engine may parse data actual data from the HTML files based of HMTL identifiers, HMTL dividers, CSS selectors, XPath, etc. using parsing tools such as BEAUTIFUL SOUP or NOKOGIRI. The data mining engine may also perform curation and other text mining processes such as scanning of images, OCR, and natural language processing to store data, particularly historical data such as documentations and books of traditional medicines, to various databases operated by the computing server.
The data integration engine consolidating various data entries from different data sources to generate a compiled dataset. The data integration process may occur on demand or a part of the routine process to build various databases in the computing server, such as the pharmacopeia database. In some embodiments, a user of the computing server, through the application, may specify one or more herb components and/or one or more traditional medicine formulas. The computing server, based on the user input, carries out queries to various databases to retrieve data entries that are related to the user inputs. The data entries may include various attributes that agree with or contradict other data entries. The data integration engine may identify the attributes that belong to the same field and aggregate the attributes together. The data integration engine may also identify and flag attributes from different entries that are potentially in conflict with each other. In some embodiments, the data integration engine may also retrieves data from various sources and convert the data in a structured format that has common attributes, metrics and metadata. The standardized data may be saved in the pharmacopeia database.
In some embodiments, the method of creating the PhAROS_PHARM, pre-processed repository, and computational space, generally comprising and including but not limited to, the first ‘meta-pharmacopeia’, processed and normalized formalized pharmacopeias, formulations, associated plant/organisms, associated available compound sets, and indications, temporal and geographical data, indicating historical, and contemporary geographical, cultural and epistemology origins. Efficacy-based research approaches have been proposed as more appropriate for traditional Chinese medicine than attempting to fit the TCM into a Western mechanism-based research framework.
Tang (writing in the BMJ in 2006) asked “is the current Western model of research-trying out unknown treatments in animals-suitable for studying treatments that have long been used in humans?” The PhAROS_PHARM pre-processed repository, and computational space, overcomes these issues syncretically, allowing a diversity of inputs and pathways to outputs that can start from efficacy-based a priori assumptions or mechanistic inquiry. The method includes data input from multiple sources, to become the content of this meta-pharmacopeia repository. Importing, cleaning, reducing and normalizing data and metadata for compounds, ingredient lists, formulations and their associated therapeutic indications. Including but not limited to formalized publicly-available pharmacopeias from Japan, China, India, Korea, South East Asia, Middle East, South America, Russia, India, Africa, Oceania and Europe. Associated metadata will be imported, cleaned, normalized and compressed, this includes historical and contemporary data sources that document linkages between medicinal formulation, ingredient compounds/chemical components and indications for therapeutic use, translations of resources from original languages processed using approaches such as machine translation, natural language processing, multilingual concept extraction or conventional translation; OCR of historical materials.
In some embodiments, an example of a constructed PhAROS_PHARM meta pharmacopeia was assembled in a single computational space containing 20,826 phytomedicine formulations, >31,000 component chemicals and their indications, currently accessible through a graphical dashboard for direct interrogation of this system component, independently of other PhAROS system components and modules. This example dataset contains assembled phytomedical intelligence/data from three continents, five contemporary and historical cultural medical systems, spanning over 5000 years of human medical endeavor and the biogeography of >16.9M square miles of medicinal plant growth.
In some embodiment and one example here, the method used to construct a PhAROS_PHARM meta-pharmacopeia repository and computational space, utilized discrimination data protocols as ‘in-group’ and ‘out-group’ data for inclusion in PhAROS_PHARM data structure. The method in this example utilized only formalized medical systems with established indication-formulation-regimen frameworks, while excluding approaches that rely upon animal medicine, mineral medicine, shamanism and humoral medicine.
In some embodiments, the PhAROS system can, using subcomponents of the system, provide a method to rationalize phytomedicine design and cultivation pipelines for global health issues. Phytomedicines remain as major components of medical optionality for billions of individuals in rural, developing or impoverished locations worldwide. There exists continued advocacy for equitable distribution of Western medicines, and additionally there is not only an economic exigency but an ethical responsibility to optimize formulation and improve availability and access of low cost phytomedicine alternatives to comparatively expensive Western medicines, for global health populations and rationally leverage their potential benefits.
In some embodiments, the PhAROS system can, using subcomponents of the system, provide a method to aid in democratization of optimized phytomedicines, that can also serve populations by decreasing the influence of fraudulent practitioners and eliminating the perceived need for medically-irrelevant exploitative, and sometimes abhorrent, formulation components. PhAROS systems can inform global health solutions using methods in specific sub-systems, by (1) Identifying minimal essential formulations for efficacy and safety through combining data results from PhAROS_METAB, and PhAROS_CHEMBIO, Subsequently utilizing the PhAROS_BIOGEO subsystem to identify plant, mixture, component and/or compound sources, for desired formulations and matching them to growing locations, environments and seasons, to generate cultivation plans for practitioners and community members.
The PhAROS_CORE subsystem is connected to the other subsystems including the PhAROS_BRAlN. Subcomponents are accessed through the major components and include the PhAROS_PHARM, PhAROS_CONVERGE, PhAROS-CHEMBIO, PhAROS_BlOGEO, PhAROS_METAB, PhAROS_MICRO, PhAROS_CURE, PhAROS_QUANT, PhAROS_POPGEN, PhAROS_TOX, PhAROS_BH, PhAROS_EPIST, and PhAROS_BASE K.
The function modules being accessed include PhAROS_GEO Functions, PhAROS_BIOINFORMATICS Functions, PhAROS_EVALUATE Functions, PhAROS_IMAGE ANALYTICS Functions, PhAROS_NETWORKS Functions, PhAROS_TIME Functions, PhAROS_MODEL Functions, PhAROS_VISUALIZE Functions, PhAROS_TEXT MINING Functions, PhAROS_UNSUPERVISED Functions, and PhAROS_DATA Functions. As PhAROS_BRAIN Functions data is collected the data is transmitted to the PhAROS_FLOW. PhAROS_FLOW allows the user to build data analysis workflows visually, using the PhAROS_BRAIN Functions.
In this example worksheet flow of functions are needed for evaluation of classifiers. Users can select a cell in the confusion matrix to view and visualize related data. Selected data from a data table is displayed from the confusion matrix to the data table. The confusion matrix is utilized for additional analysis of cross validation results. Evaluation results are transferred to the test and score module. Cross-validation takes place in the test and score module. Users can click here to visualize the performance scores. Several learners can be scored in cross validation simultaneously.
In this example the learners include Logistic Regression, Random Forest Classification and SVM. Users can select to visualize the data as a table. That process transmits data back and forth from the test and score module to the PhAROS dataset package module as the user creates the desired data table of one embodiment.
In one embodiment, the PhAROS_BRAIN Subsystem functions include, but are not limited to the following functions accompanying uses in Table 1 below:
The user uses query input area, pull down menus, and other options to choose what results are required, based on the user and their use case for the data required and computations necessary. Example queries may include an Organism name, indication, Metabolome, formulation, compound and target. This example query will utilize the PhAROS_PHARM, PhAROS_TOX, PhAROS_BRAIN, and table data—rank ordered by tox. The query is sent to the PhAROS_CORE subsystem, where it is interpreted and actioned.
The PhAROS_CORE subsystem searches and retrieves data from subsystems. In this example the data is being retrieved from the PhAROS_BRAIN Functions, PhAROS_PHARM, and PhAROS_TOX. PhAROS_CORE sub system, prepares data as requested, and sends data to PhAROS_USER subsystem for presentation and further interaction. The user receives data in requested format.
An example of output includes PhAROS_BRAIN table data—rank ordered frequency PhAROS_BRAIN-visualize scatter plot of toxicology from PhAROS_TOX. The user investigates data. The user identifies data of interest for re-processing. Selects query from data presented.
In this example query for re-processing for a compound the user utilizes PhAROS_POPGEN, PhAROS_BH, and PhAROS_BRAIN Functions. The query is sent to the PhAROS_CORE subsystem, where it is interpreted and actioned. The PhAROS_CORE sub system searches and retrieves data from subsystems. PhAROS_POPGEN, PhAROS_BH, and PhAROS_BRAIN Functions. The user receives data in requested format. Example output. PhAROS_POPGEN—table data—SNP issues with population vs. compound PhAROS_BRAlN-visualize scatter plot of suitability from PhAROS_BH. This example of a user process is completed, and results are stored in the PhAROS_BASE in USER DATA of one embodiment.
Example queries may include an indication pain, Metabolome, formulation, compound and target. This example query will utilize the PhAROS_CONVERGE with output in a table. The query is sent to the PhAROS_CORE subsystem, where it is interpreted and actioned. The PhAROS_CORE sub system searches and retrieves data from subsystems. In this example the data is being retrieved from the PhAROS_CONVERGE Functions. A PhAROS_CORE sub system, prepares data as requested, and sends data to PhAROS_USER subsystem for presentation and further interaction. The user receives data in requested format. The user investigates data. The user actions AI interface with PhAROS_BRAIN to analyze data. The query is sent to the PhAROS_CORE subsystem, where it is interpreted and actioned with the PhAROS_BRAIN Functions. The PhAROS_BRAIN subsystem functions, AI accesses the data and returns optimal results of convergence.
The user receives data in requested format, and results are stored in the PhAROS_BASE USER DATA.
Through a web browser and/or user interface the administrator user accesses the PhAROS_USER sub-system. The administrator user chooses options for the deposit and parsing of data from external data sources to be deposited as new databases and data collections within the PhAROS_BASE and alternatively is added to existing relevant data sets within the PhAROS_BASE. Another administrator user option for Subsystem name: PhAROS_CORE is the PhAROS_USER subsystem interface communicates with this PhAROS_CORE subsystem.
This PhAROS_CORE subsystem collects the user request with their chosen options, and retrieves and processes data, from external data sources into new or existing data structures within PhAROS_BASE. Here an administrator user is utilizing PhAROS_BRAIN FUNCTIONS to collect and process data from an external database source and depositing it in a newly formed database within the PhARO5 BASE. Other data stored in the PhAROS_BASE remains untouched.
External databases/data sources data mined for information is data added to the PhAROS_BASE system from external data source. The external data gathered is stored in a new database and distributed into the PhAROS_BRAIN and PhAROS_BASE repositories. An example of the distributions to the PhAROS_BASE repositories include, but are not limited to a Japanese Traditional medical database, African Traditional medical database, Korean Traditional medical database, USER DATA, Plant Database, and CORPUS of one embodiment.
In this example addition of data to the PhAROS_PHARM subsystem is shown with the Subsystem name: PhAROS_USER. Through a web browser and/or user interface the administrator user accesses the PhAROS_USER sub-system. The administrator user chooses options tor the deposit, and parsing of data from the Pharos Base repository (and its subsystems) into the PhAROS_PHARM sub-system. The Subsystem name: PhAROS_CORE directs the additions. The PhAROS_USER subsystem interface communicates with this PhAROS_CORE subsystem. This subsystem collects the user query with their chosen options, and retrieves and processes data, from appropriate subsystems and coordinates with other subsystems to further analyze, assess and visualize the data. Returning the results back to the user through the prior PhAROS_USER subsystem.
Here an administrator user utilizes a series of PhAROS_BRAIN Functions to move data from the PhAROS_BASE traditional medicine datasets, plant data sets, and literature database [CORPUS], cleans, parses, processes, analyzes and deposits the data in the PhAROS_PHARM Subsystem. PhAROS_BRAIN controls the processes for the additions. The PhAROS_BASE controls its subsystems. Data added to the sub-system from PhAROS_BASE subsystems include for example PhAROS_BASE repositories include, but are not limited to the Japanese Traditional medical database, African Traditional medical database, Korean Traditional medical database, USER DATA, Plant Database, and CORPUS. This data is added to the PhAROS_PHARM in one embodiment.
In one embodiment PhAROS includes a method for creation of the meta-pharmacopeia PhAROS_PHARM. In one embodiment PhAROS includes a user interaction dashboard for the PhAROS_PHARM component. In one embodiment PhAROS includes a method used to construct and assemble the PhAROS_PHARM meta-pharmacopeia repository and computational space.
In one embodiment, a PhAROS data process is utilized for in silico convergence analysis (ISCA). In one embodiment a PhAROS data process is utilized to deconvolve modes and mechanisms of action, inclusion priority and underlying epistemology to identify minimal essential formulations of phytochemicals for specific indications. In one embodiment a PhAROS data process is utilized to generate a method to diversify the supply chain of a user/stakeholder for phytomedicine plants, organisms, components and/or compounds.
In one embodiment PhAROS components can be utilized to provide a method to rationalize phytomedicine design and cultivation pipelines for global health issues.
In one embodiment PhAROS components can be utilized to provide a method to generate compositional benchmarking for quality control, assurance and fraud detection. In one embodiment PhAROS components can be utilized to provide a method to generate target-oriented rational design. In one embodiment PhAROS components can be utilized to provide a method to test the hypothesis that across the vast geographical, cultural and historical datasets encompassed by the meta-pharmacopeia, rare, non-obvious, curative combinations of phytomedicines will have emerged at intervals.
PhAROS in silico drug discovery engine has unique properties/claims. PhAROS includes multiple pharmacopeia in a single interrogatable space. PhAROS processes are for uncovering optimized therapeutic mixtures (OTM)/minimum essential mixtures (MEM). The PhAROS method is not looking for single ingredient-single target formulations or for whole plant medicine as in the traditional medical systems. The PhAROS method is using culturally-based epistemology to define the functional categories of necessary ingredients within these mixtures and salutogenesis: focusing on the promotion of health (rather than pathology).
PhAROS capabilities include identifying new drug-target-indication relationships for pre-clinical investigation and drug development; suggesting minimal essential phytomedical formulations for a given indication through filtering non-essential components; suggesting alternative, equivalent formulations for a given indication that provide for improved efficacy, decreased side effects or novel IP development; identifying alternate supply chain options for phytomedicine components; de-risking exploration of phytomedicines as therapeutic components by assessing their convergent emergence between geographically- and culturally-separated medical systems; de novo design of a new class of ‘transcultural’ medicines; and integrating phytomedical intelligence for a particular indication across geographically and culturally distinct pharmacopeias.
The embodiments show a method for creation of the meta-pharmacopeia PhAROS_PHARM. In some embodiments PhAROS contains a suite of informatics tools, data pipelines and data repositories allowing for user access and decision support tools for identifying a drug, a compound, a mixture, an organism discovery. Depending on the need of the user data repositories, and pre-processed repositories, can be cross correlated, analyzed and assessed for particular questions, these sub components and data sets, include but are not limited to.
PhAROS_USER. This is the user interactive system including but not limited to functional user tools designed to aid in coordinating user defined in silico analysis across multiple sub repositories and tools, coordinating with PhAROS_CORE, to utilize processes, connect and retrieve data and present user requested data, in an accessible manner. Basic and administrative levels of access limit possible disruption of data resources and tools.
PhAROS_CORE. This is the core system of functional system including but not limited to tools designed to collect, parse and maintain sub-systems, raw data repositories, pre-processed repositories, training data, data tools, automated and manual processing and task management.
PhAROS_PHARM. This is a proprietary pre-processed repository, and computational space, comprising and including but not limited to, the first ‘meta-pharmacopeia’, processed and normalized formalized pharmacopeias, formulations, associated plant/organisms, associated available compound sets, and indications, temporal and geographical data, indicating historical, and contemporary geographical, cultural and epistemology origins; Including but not limited to processed and normalized formalized pharmacopeias from Japan, China, India, Korea, South East Asia, Middle East, North/South America, Russia, India, Africa, Europe, Australia; Including but not limited to processed, translated normalized, individual relevant published datasets or case reports in the scientific literature that document relationships between medicinal plants and disease indications; Including, but not limited to processed, curated ethical partnerships, indigenous, cultural (e.g., African, Oceanic) phytomedical formulations; Including but not limited to processed contemporary and historical herbologies that document relationships between medicinal plants and disease indications (e.g., Hildegard of Bingen, Causae et Curae, Physica); Including but not limited to processed, translation of resources from original languages processed using approaches such as machine literal translation, natural language processing, multilingual concept extraction or conventional translation; OCR of historical materials. AI driven intent translation.
PhAROS_CONVERGE. This is a pre-processed repository including but not limited to, an un biased in silico convergence analysis of formulation composition explicitly between medical systems, predictions of minimal and/or essential compound sets for a given indication, a proprietary digital composition index (n-dimensional vector and/or fingerprint), identifying efficacy across traditional medicine systems, ranked optimized de novo formulations and mixtures utilizing transcultural components for subsequent preclinical and clinical testing in particular indications.
PhAROS_CHEMBIO. This is a pre-processed repository of chemical and biological data, including but not limited to chemical structure, physicochemical properties, known and/or algorithmically calculated or predicted PD/PK properties, putative biological effects, data informing of receptor binding, docking, regulation of signaling pathways, metabolism, drug-target relationships, and mechanism of action, CYP interactions, as well as published studies and clinical trials.
PhAROS_BIOGEO. This is a pre-processed repository of integrated data, including but not limited to the meta-pharmacopeia, associated temporally, geographical, botanical, climatological, environmental, genomic, metagenomic, and metabolomic data on originating plants, components or other organisms.
PhAROS_METAB. This is a pre-processed repository of integrated data of, including but not limited to, the meta-pharmacopeia with de novo metabolomic data for plants, and organisms that are not currently in medicinal use, supplemental metabolomic data secured for known medicinal plants and/or associated organisms.
PhAROS_MICRO. This is a pre-processed repository of integrated data of, including but not limited to, the meta-pharmacopeia with microbiome data on microorganisms associated with plants/organisms/components of interest, and their secondary metabolome compositions.
PhAROS_CURE. This is a pre-processed repository of integrated data, including but not limited to, the meta-pharmacopeia with documented spontaneous regression/remission events associated with botanical medicine or supplement usage, organized by organism, including plant, compound set and clinical manifestation/ICD codes.
PhAROS_QUANT. This is a pre-processed repository of integrated data of, including but not limited to, the meta-pharmacopeia with component weighting data based on either proportional components using standardized measurements and normalizations, for formulations and/or de novo quantitative analysis of formulated components.
PhAROS_POPGEN. This is a pre-processed repository of integrated data of, including but not limited to, the genetic admixtures, SNP characteristics and genetic/ethnic variability in populations in whom the formulations within the meta-pharmacopeia have been tested geographically and temporally.
PhAROS_TOX. This is a pre-processed repository of integrated data of, including but not limited to, the meta-pharmacopeia with toxicological and side-effect profile data, and/or de novo experimentally-derived data, and/or in silico predicted toxicological and side-effect data.
PhAROS_BH. This is a pre-processed repository of integrated data and a data processing/assessing tool, including but not limited to, contextualization data of meta-pharmacopeia datasets within a novel proprietary Bradford-Hill decision support framework, predicting data interpretation and assessing the evidence base for assertions of potential efficacy.
PhAROS_EPIST. This is a pre-processed repository of integrated data and a data processing/assessing tool, including but not limited to, parsed of formulation components data, plant, compound, a proprietary PhAROS correlation tool, that links composition to underlying epistemology for inclusion of a component (e.g., TCM/Kampo concept of JUN-CHEN-ZUO-SHI (‘Monarch, Minister, Assistant and Envoy’).
PhAROS_BRAIN. This is a repository of integrated data and a data processing/assessing tool, including but not limited to, a system that links the PhAROS_USER interactive system above to advanced analysis tools, PhAROS_BRAIN Functions which enable de novo analysis, as well as being able to populate PhAROS subsystems with data.
PhAROS_FLOW, a graphical data processing environment that allows users and administrators the ability to process data using the PhAROS_BRAIN functions without extensive coding, system modeling tools including machine learning and AI tools such as support vector machine, artificial neural networks, deep learning, Naïve Bayesian, K-nearest neighbors, random forest, AdaBoost wisdom of crowds and ensemble predictors, and others, validation (such as MonteCarlo cross-validation, Leave-One-Out cross validation, Bootstrap Resampling, and y-randomization).
The application relates generally to a method and system that can be used for the unbiased, user or artificial intelligence (AI) guided, identification of putative human and animal therapeutic targets, proof of mechanism, analysis of therapeutic potential of a compound, identification of complex mixtures for human on animal therapeutics, optimization of complex mixtures for human on animal therapeutics, supply chain.
This system utilizes the processing of large amounts of pharmacopeia data; data analysis, mathematical manipulation, machine learning identification, and other unique combinations of mathematical assessment of this data, through a user interface and user interaction to produce easily interpretable results and visualizations that inform the user of potential therapeutic targets for an indication, therapeutic potential of a compound, and formulations of new classes of transcultural medicines.
Lead identified compounds are subjected to further chemical modification processed to improve putative action, toxicity and availability, and are ultimately tested in human clinical trials. During the identification and testing of a new medicine for an indication, information and data on historical phytomedical approaches are generally ignored, overlooked, and/or over simplified, in favor of current computational analysis of fundamental single compound chemical analysis, based on structure, and comparison of said structure to other structures, and substructure components.
Pathways for potentially efficacious medicine to move from non-Western pharmacopeias to mainstream medicine are currently inadequate; relying on either painstaking, high cost, compound-by-compound testing in Western preclinical and clinical efficacy paradigms, or on ‘rediscovery’ of components during high-throughput screening in academic or pharmaceutical industry research settings. Moreover, since non-Western medical systems are inherently polypharmaceutical and Western approaches are typically ‘single drug-single target’, simple preclinical or clinical screening will miss compounds that only work when contextualized by other components. Non-Western pharmacopeias are also highly siloed along cultural dividing lines, and tend to be examined in isolation by scientists from the originating country. This misses opportunities to identify consonant approaches that are duplicated across pharmacopeias, which could help pre-validate drug-target-indication relationships. In addition, it misses a major opportunity to combine efficacious components across cultural lines to design optimal new polypharmaceutical medicines.
These historical phytomedical approaches have spanned all human geographies, cultures and civilizations, across thousands of years, and although most have not been tested in any formalized setting, they have most likely been tested on enormous numbers of individuals, to produce effective therapeutics without strict scientific method, but rather Monte Carlo methods, using empirical and observational evidence over significantly longer time periods than current de novo compounds are tested in clinical trials. Much of this historical phytomedical information has become formalized pharmacopeias and have evolved and coalesced in many geographically isolated societies.
The majority of historical phytomedical compositions are organized into multi-ingredient formulations, and are usually based on collections of whole plant components rather than single chemical compounds, as the means to purify and identify such components has only become available in the last few hundred years. At this level the composition is often hundreds or thousands of individual chemical components. Moreover, the underlying epistemologies for inclusion of some components may have no parallel in an evidence-based medicine approach, rather reflecting a response to a belief system grounded in regional religion, superstition or myth.
The systems and methods described here as the PhAROS discovery platform for computational phyto-pharmacology is designed not to assess solely the identified chemical components (many of which are missing), in each traditional medicine versus a symptom or indication, as would be usually found in contemporary assessment systems. Rather the PhAROS discovery platform is designed to assess and analyze the entire epistemological framework for a traditional medicine, the prescribing and development of indication-prescription relationships, and utilizes assumptions and anachronistic knowledge cross-correlated across other geographically and temporally evolved traditional medicines.
This knowledge given in isolation may appear to have no significant utility, interest or translatability in modern medico-pharmacological development; however analysis across these systems can present clear decision support frameworks that incorporate the epistemological basis for syndrome differentiation and design of formulations and uses an unbiased methodology for validation and inclusion/exclusion criteria of components in formulations.
In some embodiments, the PhAROS system enables organized input, processing and output matrices for specific types of stakeholder, allowing them to interface with, and interrogate the PhAROS system, enabling processing of data, retrieval of data, additional metadata, information, statistical analysis, and visualizations, that allows the user/stakeholder degrees of confidence in possible therapeutic potential of identified plant, organisms, compounds, mixtures, and mixture components, allowing rapid decision priorities to be made. Production of data for a given stakeholder can be achieved through either i) Administrative access to the system on behalf of the stakeholder, ii) Direct but limited access to the system as a user by the stakeholder, or iii) Direct unlimited access to the system as a user/administrator.
In some embodiments, the stakeholder has a starting point or asset with which they wish to initialize data analysis across the PhAROS system. Depending on the input type/data and quality, and the output required by the stakeholder, different components of the PhAROS system can be utilized in combination, and/or individually to produce the desired results needed by the stakeholder.
In some embodiments, the user/stakeholder has a Plant or organism name input. In such an embodiment, the PhAROS system can deliver, relevant data about this plant or organism, including but not limited to, the Chemical component list/metabolome (curated and machine readable); corresponding targets, regulated pathways, known actions, binding/docking properties; associated toxicity data, side effect, adverse event data; corresponding indications (including by convergence analysis, see below); any associated spontaneous regressions; geographical distribution and associated bio, environmental, climate data; associated microbiomes; modified Bradford-Hill decision support analysis for development.
In some embodiments, the user/stakeholder has an indication or disease input. In such an embodiment, the PhAROS system can deliver, relevant data about this indication or disease input, including but not limited to, transcultural alternative formulation datasets; predicted minimal essential component lists for indications with associated targets, actions, binding/docking properties, toxicity data, side effects, adverse event data; a plant list and/or metabolome list for component sourcing; weighed analysis for component prioritization and ranking; modified Bradford-Hill decision support analysis for development.
In some embodiments, the user/stakeholder has a metabolome input. In such an embodiment, the PhAROS system can deliver, relevant data about this metabolome input, including but not limited to, corresponding targets, regulated pathways, known actions, binding/docking properties; associated toxicity data, side effects profiles, adverse event data; indications; alternative plant and/or metabolome list.
In some embodiments, the user/stakeholder has a formulation or mixture component list input. In such an embodiment, the PhAROS system can deliver, relevant data about this formulation or mixture component list input, including but not limited to, a chemical component list; corresponding targets, regulated pathways, known actions, binding/docking properties; associated toxicity data, side effect data; plant list and/or metabolome list for component sourcing; epistemological analysis of component rationales; indications; weighting analysis for component prioritization; alternative formulations from different cultural contexts; predicted minimal essential component list for indications.
In some embodiments, the user/stakeholder has a chemical compound input. In such an embodiment, the PhAROS system can deliver, relevant data about this chemical compound input, including but not limited to, corresponding targets, regulated pathways, known actions, binding/docking properties; associated toxicity data, side effect, adverse event data; formulations; corresponding indications (including by convergence analysis, see below); epistemological analysis of rationales for inclusion in formulations; any associated spontaneous regressions; representation in metabolomes and/or plant/fungi lists for alternative sourcing; modified Bradford-Hill decision support analysis for development.
In some embodiments, the user/stakeholder has a target input. In such an embodiment, the PhAROS system can deliver, relevant data about this target input, including but not limited to, a compound list of known ligands of the target; target list for chemically similar compounds; their associated regulated pathways; list of formulations containing compounds predicted to interact with target, mapped to indications; source plants/fungi and/or metabolomes for compounds predicted to interact with target, binding/docking properties; associated toxicity data, side effect, adverse event data; formulations; corresponding indications, including by convergence analysis.
In some embodiments, the user/stakeholder has identified the need for a formulation. The PhAROS system can deliver a relevant formulation based on one or more inputs designated by the user/stakeholder. This PhAROS-informed formulation can include but not limited to, the following formation types: (A) minimal essential formulations derived from discriminating essential from non-essential components of traditional medicine formulations; (B) Transcultural de novo formulations assembled based on efficacy predictions from one or more traditional medicine approaches to a particular indication; (C) de novo formulations rationally designed based on PhAROS outputs across multiple traditional medicines; (D) A, B or C as a combination therapy with one or more additional components derived from Western pharmacopeias or drug discovery; or (E) bystander compounds or combinations identified through PhAROS analytics that have potential non-medical uses or applications.
In some embodiments, the user/stakeholder has identified the need for the PhAROS system to identify a formulation for real world uses that can include, but not limited to one or more of the following six: (1) human use pharmaceutical agents, (2) human nutraceuticals/supplements, (3) veterinary use pharmaceutical agents, (4) veterinary use nutraceuticals/supplements, (5) non-veterinary agricultural use, (6) Food additives, industrial and other uses.
In some embodiments, the user/stakeholder has identified the need for the PhAROS system to identify a formulation for use as a human pharmaceutical agent that can include, but not limited to, acute or chronic symptomatic disease management, disease and disorder treatment, or disease prevention.
In some embodiments, the user/stakeholder has identified the need for the PhAROS system to identify a formulation for use as a human nutraceuticals/supplements that can include, but not limited to, acute or chronic symptomatic disease management, disease and disorder treatment, disease prevention, human performance enhancement, or as an alternative to “non-natural” substances that would otherwise limit the user/stakeholder in being able to label their product as “natural”, “from nature”, “nature designed”, “all natural”, “no chemical additives” or similar statement.
In some embodiments the user/stakeholder has identified the need for the PhAROS system to identify a formulation for use as a veterinary pharmaceutical that can include, but not limited to, acute or chronic symptomatic disease management, disease and disorder treatment, disease prevention, or as an alternative to prohibited substances including most synthetic fertilizers and pesticides that would otherwise limit the farmer/grower in being able to label their product as organic. (i.e., at least 95% of animal feed must be grown to organic standards. No use of artificial fertilizers or pesticides on feed crops or grass is permitted.)
In some embodiments, the user/stakeholder has identified the need for the PhAROS system to identify a formulation for use as a veterinary nutraceuticals/supplement that can include, but not limited to, acute or chronic symptomatic disease management, disease and disorder treatment, disease prevention, yield improvement, performance enhancement, or as an alternative to prohibited substances including most synthetic fertilizers and pesticides that would otherwise limit the farmer/grower in being able to label their product as organic. (i.e., at least 95% of animal feed must be grown to organic standards. No use of artificial fertilizers or pesticides on feed crops or grass is permitted.)
In some embodiments, the user/stakeholder has identified the need for the PhAROS system to identify a formulation for use as an agricultural product that can include, but not limited to, plant derived insecticides, plant derived prophylactic insecticides, herbicides, fungicides, anti-parasitics, or as an alternative to prohibited substances including most synthetic fertilizers and pesticides that would otherwise limit the farmer/grower in being able to label their product as organic (i.e., at least 95% of animal feed must be grown to organic standards. No use of artificial fertilizers or pesticides on feed crops or grass is permitted).
In some embodiments, the user/stakeholder has identified the need for the PhAROS system to identify a formulation for use as a food additive, or industrial and other use, including, but not limited to, Shellac, Waxes, Natural Gums, Resins, Coatings, Adhesives, Dyes, Fragrances, Preservatives, Biodegradable polymers, Repellents, Natural fibers or as an alternative to “non-natural” substances that would otherwise limit the user/stakeholder in being able to label their product as “natural”, “from nature”, “nature designed”, “all natural”, “no chemical additives”, or similar statement.
Efficacy-based research approaches have been proposed as more appropriate for traditional Chinese medicine (TCM) rather than attempting to fit the TCM into a Western mechanism-based research framework. Tang et al. (writing in the BMJ in 2006) hypothesized that the current Western model of research, of trying out unknown treatments in animals, is not suitable for studying treatments that have long been used in humans. In some embodiments the PhAROS system is able to answer this hypothesis syncretically, allowing a diversity of inputs and pathways to outputs that can start from efficacy-based a priori assumptions or mechanistic inquiry, rather than the laborious testing of unknown compounds in animals to yield only correlative evidence that a compound made be efficacious in human therapy or treatment.
The user investigates data. User requires Post-hoc screening, for toxicity and chemical activity Input: compounds ranked by efficacy—from previous results. Process options: Post-hoc screening for toxicity, chemical activity and utilize: PhAROS_CHEMBIO and PhAROS_TOX. A query is sent to PhAROS_CORE sub system, where it is interpreted and actioned. The PhAROS_CORE sub system searches and retrieves data from subsystems including PhAROS_CHEMBIO and PhAROS_TOX. The user receives data in requested format. Output results: Ranked list of potential minimal essential, polypharmaceutical. The user process and results are stored in PhAROS_BASE and USER DATA of one embodiment.
In some embodiments the PhAROS system can, using sub components of the system, perform in silico convergence analysis to identify minimal essential formulations of phytochemicals for specific indications. PhAROS uses algorithms within its PhAROS_BRAIN FUNCTIONS to perform a proprietary method called in silico convergence analysis (ISCA). In some embodiments the PhAROS system component PhAROS_METAB is utilized, in combination with PhAROS_USER, PhAROS_CORE. This is a pre-processed repository of integrated data of, including but not limited to, the meta-pharmacopeia with de novo metabolomic data for plants, and/organisms that are not currently in medicinal use, supplemental metabolomic data secured for known medicinal plants and/or associated organisms. Within this embodiment, PhAROS_METAB is interrogated with an indication through PhAROS_USER, and PhAROS_CORE, and a computational space is assembled where all compounds and their associated plants and formulations for that indication reside.
This dataset is then processed to identify compounds that have been arrived at as a consensus between one or more cultures, as within this convergent set are components with a significant likelihood of contributing to efficacy. Post-hoc screening using PhAROS_CHEMBIO, and PhAROS_TOX components then differentiates between bioactive or otherwise medically important (e.g., excipient) components, and excludes those that do not contribute to medicinal effects (e.g., plant structural molecules), thus the system can reduce complexity by minimizing duplication. The resulting ranked list of potential minimal essential, polypharmaceutical, mixtures can then be advanced through other PhAROS system components, and/or traditional discovery pipelines, but in a significantly de-risked fashion through the PhAROS_BRAIN FUNCTION ICSA methodology for component prioritization, and therapeutic potential indexing.
The PhAROS system has the ability to generate, de novo, transcultural ‘meta-medicines’ that hybridize evidence of efficacy across cultures, geography and time, to rationally design new poly-pharmaceuticals that are not obvious and do not pre-exist in the meta-pharmacopeia. In some embodiments the PhAROS system can undertake ‘divergence’ analysis. A significant method in de-risking components that are found in a limited subset of cultures, time periods or geographies, but have a significant likelihood of being efficacious.
In some embodiments, these plants, mixture components, and/or compounds are identified as candidates to supplement formulations from other settings or as components of novel proprietary formulations. This novel method illustrates a significant advantage over current methods, encompassing and leveraging the critical method of PhAROS' transcultural nature. That is that without analysis by the PhAROS system efficacious components that would have been limited to a particular non-Western pharmacopeia for reasons of geography, botany or environment, are now identifiable and available to supplement formulations from other locales and/or they can be contributory components to de novo proprietary and optimized formulations and mixtures.
In some embodiments, the PhAROS system can produce new formulations from convergence or divergence analyses, that are added to sub-component systems of the PhAROS system, and will join the extant formulations within the PhAROS meta-pharmacopeia to be part of a significantly large number of AI training and testing sets for AI and machine learning algorithms that are designed for prediction within the PhAROS_BRAIN subsystem.
Input query: partially pre-validated formulation components, and compounds. Output: compounds, formulations. Options: inclusion/exclusion decision making criteria and ranking based on epistemological rationales and chemical/biological and quantitative rationales. Query is sent to PhAROS_CORE sub system, where it is interpreted and actioned. PhAROS CORE subsystem, searches and retrieves data from subsystems including PhAROS_BRAIN, PhAROS_CHEMBIO, PhAROS_QUANT, and PhAROS_EPIST.
PhAROS_CORE sub system prepares data as requested, and sends data to PhAROS_USER subsystem for presentation and further interaction. User receives data in requested format. Combined ranked out from: Output PhAROS_EPIST: cultural/epistemological rationales for inclusion/exclusion of specific compounds, mixtures, and formulations de-risk potential candidates. Output PhAROS_CHEMBIO: inclusion/exclusion ranking by weighting criteria based on the chemical/biological criteria. Output PhAROS_QUANT: inclusion/exclusion ranking by weighting criteria based on the quantitative, rather than qualitative, aspects of the TM formulation. User process and results stored in PhAROS_BASE and USER DATA of one embodiment.
In some embodiments, the PhAROS system can, using sub components of the system, deconvole modes and mechanisms of action, generate inclusion priorities and underlying epistemology to identify minimal essential formulations of phytochemicals for specific indications. In some embodiments, the PhAROS system can contribute additional information to the transcultural pre-validation of formulations through convergence analysis, utilizing the PhAROS subsystems PhAROS_CHEMBIO, PhAROS_QUANT and PhAROS_EPIST, in combination with PhAROS_USER, PhAROS_CORE, and PhAROS_BRAIN FUNCTIONS.
In isolation and in combination these systems further de-risk potential candidates for further advancement through standard discovery pipelines. PhAROS sub-systems and methods include, but are not limited to, the PhAROS_CHEMBIO subsystem, is a pre-processed repository of chemical and biological data, including but not limited to chemical structure, physicochemical properties, known and/or algorithmically calculated or predicted PD/PK properties, putative biological effects, data informing of receptor binding, docking, regulation of signaling pathways, metabolism, drug-target relationships, mechanism of action, CYP interactions, as well as published studies and clinical trials. Using these system potential targets can be assessed and modes and mechanisms of action for candidates that are being evaluated for inclusion in, or exclusion from, minimal essential formulations can be identified.
Additional use of PhAROS_QUANT provides a second dimension to the inclusion/exclusion decision making by incorporating weighting criteria based on the quantitative, rather than qualitative, aspects of the TM formulation. PhAROS_QUANT is a pre-processed repository of integrated data of, including but not limited to, the meta-pharmacopeia with component weighting data based on either proportional components using standardized measurements and normalizations, for formulations and/or de novo quantitative analysis of formulated components.
Finally, implementing PhAROS_EPIST in this pipeline identifies cultural/epistemological rationales for inclusion/exclusion decisions which can be used to further discriminate necessary from likely unimportant components. PhAROS_EPIST is a pre-processed repository of integrated data and a data processing/assessing tool, including but not limited to, parsed of formulation components data, plant, compound, a proprietary PhAROS correlation tool, that links composition to underlying epistemology for inclusion of a component of one embodiment.
Query is sent to PhAROS_CORE sub system, where it is interpreted and actioned. PhAROS_CORE subsystem, searches and retrieves data from subsystems including PhAROS_BRAIN Functions, PhAROS_PHARM, PhAROS_METAB, and PhAROS_BIOGEN. PhAROS_CORE subsystem prepares data as requested, and sends data to PhAROS_USER subsystem for presentation and further interaction. User receives data in requested format.
Cross referenced results from output PhAROS_PHARM: output list of plant sources, Output PhAROS_METAB: relative abundance and Output PhAROS_BIOGEN: growing locations. The user process and results are stored in PhAROS_BASE and USER DATA. Ranked data from these subsystems provides ranked results and decision support for supply chain availability and logistics issues for phytomedical companies, as well as providing other plant, organism, and mixture and compound sources for non-phytomedical uses of one embodiment.
In some embodiments, the PhAROS system can, using subcomponents of the system, provide a method to diversify the supply chain of a user/stakeholder for phytomedicine plants, organisms, components and/or compounds. In citations where phytomedicines are limited by supply chain issues, there are multiple methods to alleviate supply of these components, including total synthesis, bioreactor approaches and alternate sourcing.
In some embodiments the PhAROS system and PhAROS sub-components can be used to inform on alternate sources of these components through interrogation of the PhAROS_PHARM sub-system, in combination with PhAROS_USER, PhAROS_CORE, and PhAROS_BRAIN, with a compound of interest or formulation and the generation of an output list of plant sources. In some embodiments this data can be used to integrate the PhAROS_METAB sub-system, and metabolomic data can be assessed (where available) or commissioned to evaluate for relative abundance of the compound of interest. Alternative sources of compounds of interest can then be evaluated for commercial viability. Supply chains may also be impinged, and therefore subject to availability by specific geographical, climatological, seasonal or environmental limitations if the most recognized sources of a particular phytomedical compound are associated with specific locations and seasons.
In some embodiments, the PhAROS_BIOGEO sub-system can be utilized as a method for analysis of growing conditions, in combination with a GIS framework, in order to identify new viable growing locales for plant sources of specific compounds, and alleviate supply chain availability issues. The resulting data from PhAROS, and these subsystems, will provide decision support for supply chain availability and logistics issues for phytomedical companies, as well as providing other plant, organism, mixture and compound sources for non-phytomedical uses.
The PhAROS processing pathway is utilized to provide a method to rationalize phytomedicine design and cultivation pipelines for global health issues. In some embodiments the PhAROS system can, using subcomponents of the system, provide a method to rationalize phytomedicine design and cultivation pipelines for global health issues. Phytomedicines remain as major components of medical optionality for billions of individuals in rural, developing or impoverished locations worldwide. There exists continued advocacy for equitable distribution of Western medicines, and additionally there is not only an economic exigency but an ethical responsibility to optimize formulation and improve availability and access of low cost phytomedicine alternatives to comparatively expensive Western medicines, for global health populations and rationally leverage their potential benefits.
In some embodiments, the PhAROS system can, using subcomponents of the system, provide a method to aid in democratization of optimized phytomedicines, that can also serve populations by decreasing the influence of fraudulent practitioners and eliminating the perceived need for medically-irrelevant exploitative, and sometimes abhorrent, formulation components. PhAROS systems can inform global health solutions using methods in specific sub-systems, by (1) identifying minimal essential formulations for efficacy and safety through combining data results from PhAROS_METAB, and PhAROS_CHEMBIO, and subsequently utilizing the PhAROS_BIOGEO subsystem to identify plant, mixture, component and/or compound sources, for desired formulations and matching them to growing locations, environments and seasons, to generate cultivation plans for practitioners and community members.
In one embodiment, the PhAROS processing pathway is utilized to provide a method to rationalize phytomedicine design and cultivation pipelines for global health issues. The PhAROS processing pathway is utilized to provide a method to generate compositional benchmarking for quality control, assurance and fraud detection.) In some embodiments the PhAROS system can, using subcomponents of the system, provide a method to generate compositional benchmarking for quality control, assurance and fraud detection. Currently the primary method by which medicinal approaches move from non-Western to Western settings is via their translation into nutraceuticals. Unfortunately, this nutraceuticals market is plagued by abstraction and oversimplification of formulations that nevertheless claim fidelity to the original formulation-indication relationship found in the non-Western system.
In some embodiments, the PhAROS subsystems provide the tools and methods necessary to inform the rational design of high-quality formulations for nutraceuticals that legitimately contain the minimal essential ingredient set that PhAROS identifies with the highest efficacy. This improves products produced by PhAROS stakeholders/users within the nutraceuticals industry, and significantly reduces the negative health impacts and reduced unnecessary expenditures. In addition, the PhAROS subsystems provide the tools and methods to provide a set of compositional benchmarks related to claimed indications, for consumer/industry validation of products. These benchmarks support quality and integrity of nutraceuticals and provide a validation, quality assurance index/mark/certification linked to the PhAROS system.
In some embodiments, the PhAROS processing pathway is utilized to provide a method to generate compositional benchmarking for quality control, assurance and fraud detection. In some embodiments, the PhAROS system can, using subcomponents of the system, provide a method to generate a target-oriented rational design. This is true in cases where novel information about emerging diseases (e.g., Zoonosis) can be timely and important. In some embodiments, the PhAROS system can provide a method to generate novel disease-target relationships to be used for target-oriented rational design.
An example of the potential impact of this kind of approach is illustrated by recent studies in which an enzyme key to the functioning of non-COVID 19 (but related) coronaviruses (SARS-CoV and MERS-CoV) which was identified as structurally conserved with SARS-CoV2. 3D hom*ology modeling of the enzyme was utilized and screened against a medicinal plant library containing 32,297 individual potential anti-viral phytochemicals/traditional Chinese medicinal compounds; this resulted in 9 potential hits for further exploration. In some embodiments, the PhAROS systems would replicate these types of analyses at a much larger scale and with the additional aspect and method of utilizing an extremely large transcultural and transhistorical meta-pharmacopeia dataset as a starting point.
In some embodiments, the PhAROS processing pathway is utilized to provide a method to generate target-oriented rational design. In some embodiments the PhAROS system can, using subcomponents of the system, provide a method to test the hypothesis that across the vast geographical, cultural and historical datasets encompassed by the meta-pharmacopeia, rare, non-obvious, curative combinations of phytomedicines will have emerged at intervals. These may be manifested in historical and religious records and in modern literature/anecdotal reports including those on ‘spontaneous’ regressions/remissions where individuals and patients documented concurrent or prior use of alternative medicines associated with phytomedicine use.
In some embodiments, the PhAROS_CURE subsystem utilizes a set ethnographical, text mining and statistical analyses to evaluate connections between phytomedicines and regressions or curative events. In some embodiments, the data produced from the PhAROS_CURE subsystem can cross correlate with data from the PhAROS_METAB subsystem and PhAROS_CHEMBIO subsystem, which produces a method to then identify commonalities and potential candidates for further investigation.
In some embodiments, the PhAROS processing pathway is utilized to provide a method to test the hypothesis that across the vast geographical, cultural and historical datasets encompassed by the meta-pharmacopeia, rare, non-obvious, curative combinations of phytomedicines will have emerged at intervals.
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Additional Considerations
Traditional Chinese Medicine (TCM). Mental and physical practices as well as phytomedicine, animal and mineral remedies, the Doctrines of Chinese medicine are rooted in cosmological concepts such as yin-yang and five phases known as water, wood, fire, earth and metal. TCM describes health as the harmonious interaction of these entities and the outside world, and disease as a disharmony. TCM diagnoses trace symptoms to patterns of the underlying disharmony, by measuring the physiological indicators. TCM was developed over ˜3500 years with standardization efforts from 1950s onwards in the People's Republic of China.
Kampo medicine. Kampo is a component of medical practice in contemporary Japan that has its origins in Chinese medical practices first developed in the Han Dynasty (206 BC-AD 220). The medicines and associated practices were first introduced to Japan via Korea in the seventh to ninth centuries AD, with a subsequent influx of Chinese medical practices beginning in 1498. Though Kampo shares many elements with Traditional Chinese Medicine, it also developed into a uniquely Japanese practice between the two periods of Chinese introduction and subsequent to Japan cutting off contact with outsiders in 1630 CE. During the Meiji Restoration, Kampo fell out of favor due to being perceived as not modern, and the Japanese government adopted German medical practice as the country's standard. After the end of the second world war, Kampo underwent a renaissance in popularity. In 1976, it was included in the Japan National Insurance Program, and today it is taught in all Japanese medical schools alongside Western biomedicine.
Ayurveda. Ayurveda (Mukherjee et al., 2017) is an Indian medical system, based around epistemology of three energies (doshas): Vata is the energy of movement; pitta is the energy of digestion or metabolism and kapha is the energy of lubrication and structure. The cause of disease in Ayurveda is viewed as a lack of proper cellular function due to an excess or deficiency of vata, pitta or kapha. Disease can also be caused by the presence of toxins. Balance in constitution is ideal and the natural order; imbalance is disorder. Health is order; disease is disorder. Ayurvedic therapeutic approaches include phytomedicine, meditative practices, physical manipulation, diet, environment.
Traditional European medicine. Medicine in pre-Enlightenment Europe was a combination of elements derived from Greek and Roman medical writings, acquired through translations from Greek and Arabic sources, along with a mix of relatively poorly documented indigenous practices. The more systematic of these practices were largely based on humourism, which is the belief that disease is caused by imbalance among the four “humours” (blood, phlegm, yellow bile, and black bile). Humoural medicine sought to treat disease symptoms by inducing symptoms (often with extreme methodologies such as purging and bloodletting) seen as opposite to those of diseases rather than treating the underlying causes. Disease was viewed as caused by an excess of one humour and thus would be treated by inducing its opposite, however damaging.
Unani is an Arab-Persian medical system also practiced widely in India. It is focused on prevention of disease and is similar to early European medicine in its idea of imbalances between fundamental humours. It focused on three therapeutic paths: Izalae Sabab (elimination of cause), Tadeele Akhlat (normalization of humours) and Tadeele Aza (normalization of tissues/organs).
Islamic medicine greatly informed the development of Western medicine through the dissemination of its essential texts, especially via the Ottoman Empire, and promotes holistic approaches to health as well as a ground-breaking emphasis on public hygiene and the authentication of phytomedicines.
Allopathic Western medicine. Strongly influenced by Greek philosophy and Arab/Islamic medicine prior to 1500, Allopathic Western medicine developed an increasingly evidence-based framework from the Renaissance through enlightenment and the industrial age. Allopathic Western medicine is science-based, modern medicine, that uses medications or surgery to treat or suppress symptoms or the ill effects of disease. Allopathic Western medicine utilized an evidence-based regulatory framework that demands a continuum of proofs of mechanism and efficacy prior to delivery.
A full discussion of timelines, geographies, and the complexities of comparing medical systems cross-culturally is beyond the scope of this disclosure, but Leonti and Verpoorte (2017) (Leonti and Verpoorte, 2017) includes an excellent recent review of geographic and temporal influence of different medical traditions on each other. See also Etkin, Baker, and Busch (2008) (Etkin et al., 2008) and Etkin (2006) (Etkin, 2006) for discussion of cultural factors influencing therapeutic practice, and Leslie (1998) (Leslie, 1998) on comparative study of Asian medical systems.
The foregoing description of the embodiments has been presented for the purpose of illustration; it is not intended to be exhaustive or to limit the patent rights to the precise forms disclosed. Persons skilled in the relevant art can appreciate that many modifications and variations are possible in light of the above disclosure.
Embodiments are in particular disclosed in the attached claims directed to a method and a computer program product, wherein any feature mentioned in one claim category, e.g. method, can be claimed in another claim category, e.g. computer program product, system, storage medium, as well. The dependencies or references back in the attached claims are chosen for formal reasons only. However, any subject matter resulting from a deliberate reference back to any previous claims (in particular multiple dependencies) can be claimed as well, so that any combination of claims and the features thereof is disclosed and can be claimed regardless of the dependencies chosen in the attached claims. The subject-matter which can be claimed comprises not only the combinations of features as set out in the disclosed embodiments but also any other combination of features from different embodiments. Various features mentioned in the different embodiments can be combined with explicit mentioning of such combination or arrangement in an example embodiment. Furthermore, any of the embodiments and features described or depicted herein can be claimed in a separate claim and/or in any combination with any embodiment or feature described or depicted herein or with any of the features.
Some portions of this description describe the embodiments in terms of algorithms and symbolic representations of operations on information. These operations and algorithmic descriptions, while described functionally, computationally, or logically, are understood to be implemented by computer programs or equivalent electrical circuits, microcode, or the like. Furthermore, it has also proven convenient at times, to refer to these arrangements of operations as engines, without loss of generality. The described operations and their associated engines may be embodied in software, firmware, hardware, or any combinations thereof.
Any of the steps, operations, or processes described herein may be performed or implemented with one or more hardware or software engines, alone or in combination with other devices. In one embodiment, a software engine is implemented with a computer program product comprising a computer-readable medium containing computer program code, which can be executed by a computer processor for performing any or all of the steps, operations, or processes described. The term “steps” does not mandate or imply a particular order. For example, while this disclosure may describe a process that includes multiple steps sequentially with arrows present in a flowchart, the steps in the process do not need to be performed by the specific order claimed or described in the disclosure. Some steps may be performed before others even though the other steps are claimed or described first in this disclosure.
Throughout this specification, plural instances may implement components, operations, or structures described as a single instance. Although individual operations of one or more methods are illustrated and described as separate operations, one or more of the individual operations may be performed concurrently, and nothing requires that the operations be performed in the order illustrated. Structures and functionality presented as separate components in example configurations may be implemented as a combined structure or component. Similarly, structures and functionality presented as a single component may be implemented as separate components. These and other variations, modifications, additions, and improvements fall within the scope of the subject matter herein. In addition, the term “each” used in the specification and claims does not imply that every or all elements in a group need to fit the description associated with the term “each.” For example, “each member is associated with element A” does not imply that all members are associated with an element A. Instead, the term “each” only implies that a member (of some of the members), in a singular form, is associated with an element A.
Finally, the language used in the specification has been principally selected for readability and instructional purposes, and it may not have been selected to delineate or circ*mscribe the patent rights. It is therefore intended that the scope of the patent rights be limited not by this detailed description, but rather by any claims that issue on an application based hereon. Accordingly, the disclosure of the embodiments is intended to be illustrative, but not limiting, of the scope of the patent rights.
6. EXAMPLES Example 1. Proof-of-Concept Demonstration of in Silico Convergence Analysis: Pain
In this example, PhAROS was used to identify novel convergent formulation components for pain. In particular, PhAROS was used to discover polypharmaceutical medicines for treating pain by analyzing, in a single computational space, data from a plurality of traditional medicine systems (TMS), where the analysis used transcultural dictionaries to allow searches within distinct TMS data sets embodying different epistemologies and terminologies, and where the analysis uses data returned to a query (i.e., “pain”) to identify new polypharmaceutical and/or optimized polypharmaceutical compositions.
Data analysis included a subset of the Inputs as described in
As part of the analysis, transcultural dictionaries that collate Western and non-Western epistemological understanding of pain and pain-like symptoms were used here. The transcultural dictionaries with additional data developed by a machine learning algorithm generated a therapeutic indication dictionary where pain was the indication.
Also as part of the analysis, a searchable repository (PhAROS_CONVERGE) included data and pre-processed data that allowed identification of commonalities in therapeutic approaches from biogeographically and culturally traditional medical systems (TMS). The data and pre-processed data of the PhAROS_CONVERGE included: (1) therapeutic indication dictionaries related to traditional medical systems that reflect modern and historical terminology, and/or Western and non-Western epistemologies; (2) medical formulation compositions related to traditional medical systems; (3) compound data sets for a given therapeutic indication; and (4) a proprietary digital composition index (n-dimensional vector and/or fingerprint).
Additionally, the data and pre-processed data of the PhAROS_CONVERGE was further configured to allow (1) identification of efficacious medical components across traditional medicine systems and (2) ranking optimization of de novo compound formulations and compound mixtures by utilizing transcultural components for subsequent preclinical and clinical testing for a given therapeutic indication.
The processed data returned by the query included: a list of compounds associated with pain, a list of prescription formulae associated with pain, a list of organisms associated with pain, a list of chemicals associated with pain, or a combination thereof.
Moreover, each TMS identified by the in silico convergent analysis described above was linked to one or more of: a number of compounds within the list of compounds associated with pain, a number of prescription formulae within the list of prescription formulae associated with pain, a number of organisms within the list of organisms associated with pain, and a number of chemicals within the list of chemicals associated with pain. Data outputted from this example is described below.
In Silico convergence analysis (ISCA) examines an indication (e.g., pain) across TM systems from multiple cultures and seeks to identify compound-level commonalities in the formulations that different cultures have arrived at through empirical/historical experimentation.
Example 2. Methods and Compositions for Novel Pain Therapies Targeted to Specific Pain Subtypes Identified Using the PhAROS in Silico Drug Discovery Platform
In this example, a PhAROS method was used to identify new polypharmaceutical compositions targeted to specific pain subtypes.
In particular, PhAROS was used to identify new polypharmaceutical compositions for treating specific pain subtypes by analyzing, in a single computational space, data from a plurality of traditional medicine systems (TMS), where the analysis used transcultural dictionaries to allow searches within distinct TMS data sets embodying different epistemologies and terminologies, and where the analysis used data returned by a query (i.e., pain type) to identify new polypharmaceutical and/or optimized polypharmaceutical compositions for specific pain subtypes.
Data analysis included a subset of the Inputs as described in
The processed data included a list of pain types across multiple TMS. For each pain type, the processed data included a list of TMS referenced from the plurality of TMS, associated with the pain type. Additionally, for each pain type, the processed data included the identity of a plurality of TMS linked to one or more selected from: the pain type, one or more compounds associated with the pain type, and one or more organisms associated with the pain type.
PhAROS_PHARM text mining collapsed greater than 1000 pain indications across 5 TMS to 37 major categories (
The processed data revealed that PhAROS can use data from a plurality of traditional medicine systems to differentiate between pain types.
Table 4 shows compounds most broadly associated with each type of pain (ranking by Formula Count, 300+) as identified by the PhAROS method. Additional analysis was performed to identify (i) broad and narrow spectrum analgesics from the outputted data from the PhAROS method and (ii) information for reducing complexity and de-risking components for further evaluation.
To identify putative broad spectrum analgesic candidates, the 37 categories identified above were ranked to identify putative broad spectrum analgesic candidates.
To identify putative narrow spectrum analgesic candidates, the 37 categories identified above were ranked to identify putative narrow spectrum analgesic candidates (based on narrowest pain spectrum).
Overall, this example shows that PhAROS can use data from a plurality of traditional medicine systems to differentiate between pain types and match chemical components and ingredient organisms to specific pain types, thereby identifying new polypharmaceuticals—complex mixtures—for treating specific pain subtypes.
Example 3. Piper Species Study
In this example, PhAROS was used to identify alternatives to Piper species for anxiety, pain, relaxation, and epilepsy. In particular, PhAROS was used to identify alternatives to P. methysticum for anxiety, pain, relaxation and epilepsy based on the restricted biogeography of P. methysticum.
The rationale for this study is provided below. (i) Piper species possess therapeutic and preventive potential against several chronic disorders. Piper species are represented in major TMS systems. (ii) Kavalactones are restricted to Piper methysticum. (iii) Piper species other than the kavalactone containing P. methysticum are indicted for pain, sedation, anxiety, depression, mood. Among the functional properties of Piper plants/extracts/active components, the antiproliferative, anti-inflammatory, and neuropharmacological activities of the extracts and extract-derived bioactive constituents are thought to be key effects for the protection against chronic conditions, based on preclinical in vitro and in vivo studies. The use of Piper species is informed by traditional and contemporary Cultural Medical Systems (CMS). Over 100 Piper species are in use in CMS in China, Korea, Japan, India, Africa and Oceania. P. methysticum has gained particular attention for anxiety and major depressive disorder based on its use in the Pacific as kava/sakai, a ritual soporific and relaxant drink. The proposed active ingredients of kava are kavalactones, but there is a paradox because many Piper spp. appear indicated for anxiety, in traditional medicine but the KL (pyrones) are thought to be restricted to P. methysticum.
Briefly, the approach used in this example included identifying medically important Piper spp. that could be used to interrogate PhAROS_PHARM and generate outputs associated with each Piper species to (1) a TMS, (2) one or more indications within the different TMS, and (3) sets of chemical components linked to each species within the databases comprising PhAROS_PHARM.
Here, PhAROS was used to discover polypharmaceutical medicines for treating pain, sedation, anxiety, depression, epilepsy, mood, and sleep by analyzing, in a single computational space, data from a plurality of traditional medicine systems (TMS), where the analysis used transcultural dictionaries to allow searches within distinct TMS data sets embodying different epistemologies and terminologies, and where the analysis uses data returned by a query (i.e., piper species) to identify alternative polypharmaceutical and/or optimized polypharmaceutical compositions to those found in Piper spp.
Data analysis included a subset of the Inputs as described in
As part of the analysis, transcultural dictionaries that collate Western and non-Western epistemological understanding of piper species associated with the pain, sedation, anxiety, depression, epilepsy, mood, and sleep therapeutic indications were used here.
Outputting the processed data returned by the query revealed: a list of piper species associated with one or more therapeutic indications. For example,
Each Piper species within the list of Piper species (
As noted above, the aim here was to identify alternatives to P. methysticum for treating anxiety, pain, relaxation and epilepsy based on the restricted biogeography pf P. methysticum. Representation of Piper spp in formulations derived from the various TMS in PhAROS_PHARM and associated with indications mined using a custom dictionary that included pain, epilepsy, anxiety, depression, mood and sleep.
Next, PhAROS was used to inquire if TMS formulae for pain, epilepsy, anxiety, depression, mood, relaxation, and sleep contained the Kavalactones that are associated with the efficacy of the highly biogeographically-restricted and culturally-sensitive P. methysticum. In particular, the aim was to identify alternatives to P. methysticum for anxiety, pain, relaxation and epilepsy based on the restricted biogeography pf P. methysticum, as previously noted.
Overall, this example showed that PhAROS could be used to identify alternatives to P. methysticum for anxiety, pain, relaxation and epilepsy based on the restricted biogeography of P. methysticum.
PhAROS_PHARRM Anxiety Machine Learning Study
Next, an unbiased machine learning method was used to identify alternatives to P. methysticum for anxiety, pain, relaxation, and epilepsy based on the restricted biogeography of P. methysticum. The machine learning approach was designed to treat every piece of data and metadata in the PhAROS_PHARM computational space as a feature and ask, of these features, which best predict an association with the anxiety/mood/depression dictionary. A feature's ability to predict the anxiety/mood/depression indications was normalized to all other indications.
A PhAROS_PHARM machine learning output, including chemical component type classes, was assessed for the ability to predict an anxiety/mood/depression indication over all other indications. Specific chemical type features most predictive of anxiety/mood/depression utility of a formulation were: alkaloid, terpene, fatty acid-related compounds, flavonoid, and phenyl propanoid (See
PhAROS_PHARM machine learning outputs, including ingredient organisms, were assessed for their ability to predict an anxiety/mood/depression indication over all other indications. Specific ingredient organisms most predictive of anxiety/mood/depression utility of a formulation were: Glycyrhizza uralensis radix, Paeonia lactiflora, Scutellaria baicalensis, Panax ginseng, Saposhnikovia divaicata, and Poria cocos (see
Overall, the machine learning approach identified the top ranked chemical components and specific ingredient organisms that could serve as a basis for identifying new polypharmaceuticals.
Example 4. PhAROS_PHARM Divergence Analysis of Cancer & Pain in Database to Find Novel Cytotoxic Agents
In this example, PhAROS convergence analysis (PhAROS_CONVERGE) and PhAROS divergence analysis (PhAROS_DIVERGE) were used to identify potential cytotoxic agents that might become a part of a novel cancer therapy and, separately, within complex TMS formulations for cancer and to identify compound sets with potential for cancer pain over other pain subtypes.
In this example, the hypothesis was that TMS formulations for cancer will display significant convergence with pain since pain is likely to be a major symptom in historical and contemporary presentations by cancer patients to TM practitioners. Conversely, in the divergent compound group between cancer and pain there are likely to be cytotoxic (growth inhibitory) chemical components that may be explored for untapped therapeutic utility. Therefore, this study had two aims: (1) use in silico convergence and divergence analysis in PhAROS to identify potential cytotoxic agents within complex TMS formulations for Cancer and (2) identify compound sets with potential for cancer pain over other pain subtypes.
Here, PhAROS was used to discover polypharmaceutical medicines for treating cancer by analyzing, in a single computational space, data from a plurality of traditional medicine systems (TMS), where the analysis used transcultural dictionaries to allow searches within distinct TMS data sets embodying different epistemologies and terminologies, and where the analysis uses data returned by a query to identify new polypharmaceutical and/or optimized polypharmaceutical compositions for use in treating cancer pain over other pain subtypes. The query(s) included three clinical indications (i) cancer, (ii) cancer pain, and (iii) cancer and cancer pain.
In this example, data analysis included a subset of the Inputs as described in
As part of the analysis, transcultural dictionaries that collate Western and non-Western epistemological understanding of cancer, cancer-like patient presentations, cytotoxic agents within TMS formulations for cancer, and cancer pain were part of the TMS used here. The transcultural dictionaries included a list of compounds associated with cancer pain, and a list of compounds known for treating pain. In addition, the transcultural dictionaries were further populated with additional data developed by a machine learning algorithm that generated a therapeutic indication dictionary for: cancer, cancer pain, and cancer and cancer pain.
Outputting the processed data returned by the query (i.e., clinical indications including cancer, cancer pain, and cancer and cancer pain) produced a list of compounds associated with the user selected clinical indications, a list of prescription formulae for a given TMS, and a list of organisms associated with the user selected clinical indication (
ML predictions showed that >80% of the chemical components of cancer medications in PhAROS are also found in pain medication.
The outputted, processed data included cytotoxic agents within the list of compounds that are indicated for pain and cancer across one or more TMS. This created a CANCERPAIN master list of compounds for subsequent comparison with ALLPAIN.
Divergence analysis of the compound list included identifying a list of compounds associated with a first user-selected clinical indication (i.e., cancer), where the list of compounds that is associated with the first user-selected clinical indication (i.e., cancer) does not overlap with a list of compounds that is associated with a second user-selected indication (i.e., pain).
The divergence analysis identified a divergent chemical component subset between cancer and pain indications, which can now be mined for cytotoxic components using PhAROS_CHEMBIO and PhAROS_TOX (
Results for the ML predictions included: cancer and pain medicine component overlap most of the time; a CANCERPAIN master list of compounds that is available for subsequent comparison with ALLPAIN; ML predictions show that >80% of the chemical components of cancer medications in PhAROS are also found in pain medication; a divergent chemical component subset has been identified between cancer and pain indications, which can now be mined for cytotoxic components using PhAROS_CHEMBIIO and PhAROS_TOX; and ML can assess ingredient organisms most likely to contain chemical components that diverge between cancer and pain (i.e., most likely cytotoxic or non-analgesic ingredients).
Further assessment using machine learning of ingredient organisms most likely to contain chemical components that diverge between cancer and pain (i.e., most likely cytotoxic or non-analgesic ingredients) is shown in
Overall, this example showed that PhAROS-based divergence analysis can be used to identify potential cytotoxic agents within complex TMS formulations for cancer and identify compound sets with particular potential for cancer pain over other pain subtypes.
Example 5. World Health Initiatives & Alternative Supply Chain Proof-of Concept
In this example, PhAROS was used to identify alternative sources for medically important phytochemicals that have distinct biogeographies.
Polypharmaceuticals (phytomedicines) are limited by supply chain issues. There is a constellation of approaches to this challenge including total synthesis, bioreactor approaches and alternate sourcing. The PhAROS methods as described herein can be used to inform the latter, through interrogation of PhAROS_PHARM with a compound of interest or formulation and the generation of an output list of plant sources. Within PhAROS, data can come from metabolomic data (PhAROS_METAB) (where available) or commissioned to evaluate for relative abundance of the compound of interest. In addition, as supply chains have geographical, climatological and environmental limitations, the most recognized sources of a particular phytomedical compound are associated with specific locales. Therefore, using PhAROS_BIOGEO enables analysis of growing conditions overlaid on a geographic information system (GIS) framework to identify viable growing locales for plant sources of specific compounds. Overall, PhAROS outputs based on the analysis described herein can provide decision support for supply chain and logistics issues for phytomedical companies.
In order to widely adopt phytomedical components into mainstream medicine the issue of supply chain availability needs to be addressed because: (1) the best understood plant sources may be endangered or geographically-restricted, (2) alternative sources may be easier to extract leading to production efficiencies, (3) many complex phytotherapeutics are not amenable to total synthesis so supply chain expansion would be needed for their eventual widespread usage.
In this example, a list of phytomedically important compounds for indications ranging from cancer to pain was assembled using PubMed searches. This test set (user input query) was used to interrogate PHAROS_PhARM to identify plant sources, known indications and TMS systems in which the compound was used, and for what indications. Data integration via Global Biodiversity Information Facility (GBIF) was used to assess biogeography.
In particular, the PhAROS method was used to identify (discover) alternative sources of phytochemicals by analyzing in a single computational space, data from a plurality of traditional medicine systems (TMS), where the analysis used transcultural dictionaries to allow searches within distinct TMS data sets embodying different epistemologies and terminologies, and where the analysis uses data returned by a query to identify new polypharmaceutical and/or optimized polypharmaceutical compositions, including alternative sources for phytochemicals included in the polypharmaceutical compositions. A list of phytomedically important compounds for indications ranging from cancer to pain was assembled using PubMed searches. This test set was used to interrogate PhAROS_PHARM to identify plant sources, known indications and TMS systems in which the compound was used, and for what indication.
The query was to identify alternative sources for the set of compounds or formulations. The compounds/formulations were identified using PubMed searches for compounds treating indications ranging from cancer to pain.
Data analysis included a subset of the Inputs as described in
The output returned by the first user input query (i.e., the list of one or more phytochemical compounds or formulations) produced a list of plant sources, known clinical indications associated with the phytomedical compounds or formulations, the TMS in which each compound was referenced, and a relative abundance of the one or more compounds or formulations available (See
Analysis of Potential Supply Chain Species for Parthenolide
As an example, we further explored the potential supply chain species for Parthenolide (PTL), a sequiterpene lactone from Tanacetum parthenium (Feverfew). It has been used across traditional and indigenous Western systems for analgesia and anti-inflammatory properties. The historical pharmacological knowledge underlying this application has been validated in the last two decades by controlled, mechanistic scientific studies that show efficacy in migraine (through the targeting of TRP Transient Receptor Potential ion channels) and inflammation (e.g. in rheumatoid arthritis, inflammation associated with cystic fibrosis and the murine EAE MS model). Feverfew itself is well-tolerated with minor adverse events (flatulence, bloating, heartburn, diarrhea). There are isolated reports of Feverfew acting as a contact allergen and exerting anti-platelet effects which require monitoring or cessation of Feverfew extract exposure. These side effects create a potential clinical need to identify alternative sources of PTL, while supply chain, logistic and local production issues would also motivate the identification of sources outside Feverfew.
PTL, considered to be the main active ingredient in Feverfew, is a sesquiterpene with 15 carbon atoms, 3 isoprene units and an alpha methylene-gamma lactone moiety (a cyclic ester). PTL appears to have direct cytotoxic effects and its anti-inflammatory effects may also decrease tumor success due to the close linkages between oncogenic proliferation and inflammation. PTL interrupts cell cycle progression and induces apoptosis and there is evidence that PTL decreases tumor size in vivo. Guzman et al. have shown effectiveness of PTL in AML, where effectiveness appears to relate to the constitutive activation of NFκB in AML cells compared to normal myeloid cells. PTL is likely to impact transformed cells in multiple ways, including the fact that through acting as a Michael acceptor it can participate in adduct formation which in turn can target enzymes such as DNA polymerase. However, the primary target protein for the cytotoxic effects of sesquiterpene lactones including PTL is NFκB, which is central to cell cycle progression and cell growth and is an anti-oncogene. Importantly, the co-targeting of proliferation and inflammation through NFκB gives PTL the potential for a ‘one-two punch’ for cancer—hitting both uncontrolled proliferation and the facilitating inflammatory milieu in which tumors tend to be more successful. Moreover, studies show that PTL can critically inhibit Cancer Stem Cells (CSC) in the context of non-small cell lung carcinoma, melanoma, multiple myeloma and nasopharyngeal carcinoma, again working via NFκB inhibition. This multi-faceted potential of PTLs creates their potential to be truly blockbusting, game changing drugs in difficult-to-treat cancers.
The biogeographical analyses in
As shown in
Example 6. Migraine: Transcultural Formulations, Minimal Essential Formulations
In this example, PhAROS was used to design new polypharmaceutical approaches for treating migraine.
There is an unmet need for migraine treatments for at least several reasons. First, triptans are not effective against all migraines. Second, opioids and barbiturates have high addiction potential. Third, ergotamine has nausea, vomiting and cardiovascular side effects, and is contraindicated for use in combination with a range of common drugs (antibiotics, anti-retrovirals, antidepressants). As such, the aim of this study was to identify transcultural and minimal essential components to design new polypharmaceutical approaches to migraine. The approach used was to apply migraine dictionary to PhAROS_PHARM and to perform data integration with PhAROS_MOLBIO, etc.
Briefly, here, the PhAROS method was used to discover polypharmaceutical medicines for treating migraine by analyzing, in a single computational space, data from a plurality of traditional medicine systems (TMS) (e.g., including, without limitation, normalized formalized pharmacopeias from one or more geographic regions associated with TMS (i.e., PhAROS_PHARM) and medical compound data sets comprising chemical and biological data of medical compounds (i.e., PhAROS_CHEMBIO)), where the analysis used transcultural dictionaries to allow searches within distinct TMS data sets embodying different epistemologies and terminologies, and where the analysis uses data returned by a query to identify new polypharmaceutical and/or optimized polypharmaceutical compositions.
As the clinical indication is migraine, the query (i.e., the first user input query) is to identify new polypharmaceutical and/or optimized polypharmaceutical compositions for migraine.
Data analysis included a subset of the Inputs as described in
As part of the analysis, transcultural dictionaries that collate Western and non-Western epistemological understanding of migraine and migraine-like patient presentations were used here. The transcultural dictionaries with additional data developed by a machine learning algorithm generated a therapeutic indication dictionary where migraine was the indication.
Outputting the processed data returned by the first user input query (i.e., migraine as the clinical indication) produced a list of compounds associated with the user selected clinical indication (i.e., migraine), and a list of prescription formulae for any given TMS associated with the user selected clinical indication.
The processed data also included a list of molecular targets for the list of compounds that are clinically indicated for migraine across one or more TMS.
Neurotropic Fungi-Derived Components of a Novel Polypharmaceutical Formulation to Further Evaluate for Migraine
In this example, the hypothesis was that the PhAROS method could identify alternatives to ergotamine. In particular, the aim was to identify neurotropic fungi indicated for migraines in TMS using PhAROS to output data.
First, using text mining, 209 neurotropic fungi were identified, including: Claviceps, Cordyceps, Gerronema, Mycena, Amanita, Pluteus, Copelandia, Panacolina, Panaeolus, Agrocybe, Conocybe, Hypholom, Psilocybe, Gymnopilus, Inocybe, Boletus, Hemiella, Russula, Lycoperdon, Vascellum. The 209 neutrotropic fungi were assessed against TCM, TKM, TIM, TAM, and TJM using PhAROS.
Only two neurotropic fungi (Claviceps purpurea (TCM) and Amanita muscaria (TIM)) appeared in any TMS associated with migraine.
Indications for Claviceps purpurea (TCM) and Amanita muscaria (TIM) include migraine pain, migraine pain and post-partum bleeding, and anti-poison.
As shown in
This example showed that PhAROS can identify new polypharmaceuticals for treating migraine that will be validated using traditional wet lab processes.
7. EQUIVALENTS AND INCORPORATION BY REFERENCE
While the invention has been particularly shown and described with reference to a preferred embodiment and various alternate embodiments, it will be understood by persons skilled in the relevant art that various changes in form and details can be made therein without departing from the spirit and scope of the invention.
All references, issued patents and patent applications cited within the body of the instant specification are hereby incorporated by reference in their entirety, for all purposes.