Abstract
For many prevalent complex diseases, treatment regimens are frequently ineffective. For example, despite multiple available immunomodulators and immunosuppressants, inflammatory bowel disease (IBD) remains difficult to treat. Heterogeneity in the disease across patients makes it challenging to select the optimal treatment regimens, and some patients do not respond to any of the existing treatment choices. Drug repurposing strategies for IBD have had limited clinical success and have not typically offered individualized patient-level treatment recommendations. In this work, we present NetPTP, a Network-based Personalized Treatment Prediction framework which models measured drug effects from gene expression data and applies them to patient samples to generate personalized ranked treatment lists. To accomplish this, we combine publicly available network, drug target, and drug effect data to generate treatment rankings using patient data. These ranked lists can then be used to prioritize existing treatments and discover new therapies for individual patients. We demonstrate how NetPTP captures and models drug effects, and we apply our framework to individual IBD samples to provide novel insights into IBD treatment.
Highlights
Drug development is an expensive and lengthy endeavor, on average costing approximately a billion dollars to successfully bring a drug to market [1]
Offering personalized treatment results is an important tenant of precision medicine, in complex diseases which have high variability in disease manifestation and treatment response
We have developed a novel framework, network-based personalized treatment prediction (NetPTP) (Network-based Personalized Treatment Prediction), for making personalized drug ranking lists for patient samples
Summary
Drug development is an expensive and lengthy endeavor, on average costing approximately a billion dollars to successfully bring a drug to market [1]. Drug repurposing, known as drug repositioning, has become an important avenue for discovering existing treatments for new indications, saving time and money in the quest for new therapies. Multiple existing computational approaches for drug repurposing are based on constructing representations of diseases and drugs and assessing their similarity. Heterogeneous diseases, there are frequently multiple avenues of treatment targeting different aspects of the disease, and many patients do not respond to the same set of therapies. Such diseases could benefit from a generative method that produces more personalized therapeutic strategies that target an individual’s disease state
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