Abstract
BackgroundModern genomic and proteomic profiling methods produce large amounts of data from tissue and blood-based samples that are of potential utility for improving patient care. However, the design of precision medicine tests for unmet clinical needs from this information in the small cohorts available for test discovery remains a challenging task. Obtaining reliable performance assessments at the earliest stages of test development can also be problematic. We describe a novel approach to classifier development designed to create clinically useful tests together with reliable estimates of their performance. The method incorporates elements of traditional and modern machine learning to facilitate the use of cohorts where the number of samples is less than the number of measured patient attributes. It is based on a hierarchy of classification and information abstraction and combines boosting, bagging, and strong dropout regularization.ResultsWe apply this dropout-regularized combination approach to two clinical problems in oncology using mRNA expression and associated clinical data and compare performance with other methods of classifier generation, including Random Forest. Performance of the new method is similar to or better than the Random Forest in the two classification tasks used for comparison. The dropout-regularized combination method also generates an effective classifier in a classification task with a known confounding variable. Most importantly, it provides a reliable estimate of test performance from a relatively small development set of samples.ConclusionsThe flexible dropout-regularized combination approach is able to produce tests tailored to particular clinical questions and mitigate known confounding effects. It allows the design of molecular diagnostic tests addressing particular clinical questions together with reliable assessment of whether test performance is likely to be fit-for-purpose in independent validation at the earliest stages of development.
Highlights
Modern genomic and proteomic profiling methods produce large amounts of data from tissue and blood-based samples that are of potential utility for improving patient care
Ten-year survival for prostate cancer: testing the ability of the classifier development method to work well with small datasets The classification task was to differentiate patients with prostate cancer still alive after 10 years of follow up from those dying within the 10-year period. Messenger Ribonucleic Acid (mRNA) expression data for 343 genes were available for a development cohort (GSE16560) and a validation cohort (GSE10645)
Parameters defining the dropout-regularized combination (DRC) approach were held fixed throughout this investigation with no tuning to improve performance
Summary
Modern genomic and proteomic profiling methods produce large amounts of data from tissue and blood-based samples that are of potential utility for improving patient care. The method incorporates elements of traditional and modern machine learning to facilitate the use of cohorts where the number of samples is less than the number of measured patient attributes It is based on a hierarchy of classification and information abstraction and combines boosting, bagging, and strong dropout regularization. Prospective studies designed to collect specimens from large cohorts of subjects in which the test is intended to be used are expensive and hard to justify when probability of successful test generation may be low. It is often necessary, at least in a feasibility or pilot stage, to make use of retrospectively collected sample sets.
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