Abstract
The biological processes involved in a drug’s mechanisms of action are oftentimes dynamic, complex and difficult to discern. Time-course gene expression data is a rich source of information that can be used to unravel these complex processes, identify biomarkers of drug sensitivity and predict the response to a drug. However, the majority of previous work has not fully utilized this temporal dimension. In these studies, the gene expression data is either considered at one time-point (before the administration of the drug) or two time-points (before and after the administration of the drug). This is clearly inadequate in modeling dynamic gene–drug interactions, especially for applications such as long-term drug therapy. In this work, we present a novel REcursive Prediction (REP) framework for drug response prediction by taking advantage of time-course gene expression data. Our goal is to predict drug response values at every stage of a long-term treatment, given the expression levels of genes collected in the previous time-points. To this end, REP employs a built-in recursive structure that exploits the intrinsic time-course nature of the data and integrates past values of drug responses for subsequent predictions. It also incorporates tensor completion that can not only alleviate the impact of noise and missing data, but also predict unseen gene expression levels (GEXs). These advantages enable REP to estimate drug response at any stage of a given treatment from some GEXs measured in the beginning of the treatment. Extensive experiments on two datasets corresponding to multiple sclerosis patients treated with interferon are included to showcase the effectiveness of REP.
Highlights
The biological processes involved in a drug’s mechanisms of action are oftentimes dynamic, complex and difficult to discern
The time-course gene expression data contains the gene expression levels (GEXs) of different patients over a series of time points, which can be indexed as patient-gene-time and represented as a three-dimensional tensor
Our supporting hypothesis is that genes never function in an isolated way, but oftentimes groups of genes interact together to maintain the complex biological process, which results in correlation in the GEX data[24]
Summary
The biological processes involved in a drug’s mechanisms of action are oftentimes dynamic, complex and difficult to discern. For many diseases (e.g. cancers) the response to a drug changes over time due to various reasons such as the development of drug resistance or changes in the progress of the disease To capture such changes at a molecular level, a collection of temporal gene expression profiles of samples over a series of time-points during the course of a biological process is necessary to provide more insights than a single (or two) time-point(s)[10]. With the advancement of gene sequencing technologies, collecting gene expression levels (GEXs) over multiple time-points and their matched drug response values is feasible In parallel with these technological developments, there has been growing interest in the application of machine learning methods to analyze the time-course gene expression data. This method discards samples with missing values, causing unnecessary information loss
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
