Systematic analyses of drugs and disease indications in RepurposeDB reveal pharmacological, biological and epidemiological factors influencing drug repositioning

Shameer, Khader; Glicksberg, Benjamin S.; Hodos, Rachel; Johnson, Kipp W.; Badgeley, Marcus A.; Readhead, Ben; Tomlinson, Max; O’Connor, Timothy D.; Miotto, Riccardo; Kidd, Brian; Chen, Rong; Ma’ayan, Avi; Dudley, Joel T.

doi:10.1093/bib/bbw136

Cited by 71 publications

(50 citation statements)

References 125 publications

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“…There are already several large-scale biobanks and population-based cohorts including the UK Biobank (500,000 participants), the All of Us initiative (1000,000+ participants), and the Million Veterans Program, now include linkage to EHRs [73]. Deep phenotyping by way of using EHR-linked biobank data has been used as a resource for the discovery of novel drug targets [74][75][76][77]. For example, Dewey et al [78] used the exome sequencing data linked to the EHR from 58,000 patients collected at the Geisinger Health System and found that loss-of-function mutations in ANGPTL3 were correlated with the development of coronary artery disease.…”

Section: Suggestions To Improve Translational Researchmentioning

confidence: 99%

Lost in translation: the valley of death across preclinical and clinical divide – identification of problems and overcoming obstacles

2019

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A rift that has opened up between basic research (bench) and clinical research and patients (bed) who need their new treatments, diagnostics and prevention, and this rift is widening and getting deeper. The crisis involving the "translation" of basic scientific findings in a laboratory setting into human applications and potential treatments or biomarkers for a disease is widely recognized both in academia and industry. Despite the attempts that have been made both in academic and industry settings to mitigate this problem, the high attrition rates of drug development and the problem with reproducibility and translatability of preclinical findings to human applications remain a fact and the return on the investment has been limited in terms of clinical impact. Here I provide an overview of the challenges facing the drug development, and translational discordance with specific focus on a number of "culprits" in translational research including poor hypothesis, irreproducible data, ambiguous preclinical models, statistical errors, the influence of organizational structures, lack of incentives in the academic setting, governmental funding mechanisms, the clinical relevance of basic research, insufficient transparency, and lack of data sharing in research. I further provide some suggestions and new strategies that include some new aspects on open innovation models, entrepreneurship, transparency, and decision making to overcome each of the many problems during the drug discovery and development process and to more dynamically adjust for innovation challenges with broader scientific feedback.

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Section: Suggestions To Improve Translational Researchmentioning

confidence: 99%

Lost in translation: the valley of death across preclinical and clinical divide – identification of problems and overcoming obstacles

2019

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“…RepurposeDB (http://repurposedb.dudleylab.org) is a compendium of successful drug repositioning investigations that we previously developed to address a critical knowledge gap in computational drug discovery [9]. The motivation for developing RepurposeDB is to catalog…”

Section: Datasetmentioning

confidence: 99%

Prioritizing Small Molecule as Candidates for Drug Repositioning using Machine Learning

Shameer

Johnson

Glicksberg

et al. 2018

Preprint

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Drug repositioning, i.e. identifying new uses for existing drugs and research compounds, is a costeffective drug discovery strategy that is continuing to grow in popularity. Prioritizing and identifying drugs capable of being repositioned may improve the productivity and success rate of the drug discovery cycle, especially if the drug has already proven to be safe in humans. In previous work, we have shown that drugs that have been successfully repositioned have different chemical properties than those that have not. Hence, there is an opportunity to use machine learning to prioritize drug-like molecules as candidates for future repositioning studies. We have developed a feature engineering and machine learning that leverages data from publicly available drug discovery resources: RepurposeDB and DrugBank. ChemVec is the chemoinformatics-based feature engineering strategy designed to compile molecular features representing the chemical space of all drug molecules in the study. ChemVec was trained through a variety of supervised classification algorithms (Naïve Bayes, Random Forest, Support Vector Machines and an ensemble model combining the three algorithms). Models were created using various combinations of datasets as Connectivity Map based model, DrugBank Approved compounds based model, and DrugBank full set of compounds; of which RandomForest trained using Connectivity Map based data performed the best (AUC=0.674). Briefly, our study represents a novel approach to evaluate a small molecule for drug repositioning opportunity and may further improve discovery of pleiotropic drugs, or those to treat multiple indications.

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“…By conservative estimates, it takes about 15 years and $0.8-1.5 billion to bring a drug to market (Dudley et al, 2011;Yu et al, 2015), and during the development stage, almost 90% of the small molecules cannot pass the Phase I clinical trial and finally be eliminated (Wu et al, 2019). On the other hand, disease burden is increasing globally due to the growth of population, outbreak of infectious disease and emergence of antibiotic resistance (Shameer et al, 2018). In order to circumvent this dilemma, drug repositioning has become a promising alternative strategy for drug research and development (Wu et al, 2017).…”

Section: Introductionmentioning

confidence: 99%

Identification of Drug-Disease Associations Using Information of Molecular Structures and Clinical Symptoms via Deep Convolutional Neural Network

Huang

Chen

et al. 2020

Front. Chem.

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Identifying drug-disease associations is helpful for not only predicting new drug indications and recognizing lead compounds, but also preventing, diagnosing, treating diseases. Traditional experimental methods are time consuming, laborious and expensive. Therefore, it is urgent to develop computational method for predicting potential drug-disease associations on a large scale. Herein, a novel method was proposed to identify drug-disease associations based on the deep learning technique. Molecular structure and clinical symptom information were used to characterize drugs and diseases. Then, a novel two-dimensional matrix was constructed and mapped to a gray-scale image for representing drug-disease association. Finally, deep convolution neural network was introduced to build model for identifying potential drug-disease associations. The performance of current method was evaluated based on the training set and test set, and accuracies of 89.90 and 86.51% were obtained. Prediction ability for recognizing new drug indications, lead compounds and true drug-disease associations was also investigated and verified by performing various experiments. Additionally, 3,620,516 potential drug-disease associations were identified and some of them were further validated through docking modeling. It is anticipated that the proposed method may be a powerful large scale virtual screening tool for drug research and development. The source code of MATLAB is freely available on request from the authors.

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Systematic analyses of drugs and disease indications in RepurposeDB reveal pharmacological, biological and epidemiological factors influencing drug repositioning

Cited by 71 publications

References 125 publications

Lost in translation: the valley of death across preclinical and clinical divide – identification of problems and overcoming obstacles

Lost in translation: the valley of death across preclinical and clinical divide – identification of problems and overcoming obstacles

Prioritizing Small Molecule as Candidates for Drug Repositioning using Machine Learning

Identification of Drug-Disease Associations Using Information of Molecular Structures and Clinical Symptoms via Deep Convolutional Neural Network

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