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Auteurs principaux: Islam, Jesse, Turgeon, Maxime, Sladek, Robert, Bhatnagar, Sahir
Format: Preprint
Publié: 2023
Sujets:
Accès en ligne:https://arxiv.org/abs/2301.06535
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author Islam, Jesse
Turgeon, Maxime
Sladek, Robert
Bhatnagar, Sahir
author_facet Islam, Jesse
Turgeon, Maxime
Sladek, Robert
Bhatnagar, Sahir
contents In the context of survival analysis, data-driven neural network-based methods have been developed to model complex covariate effects. While these methods may provide better predictive performance than regression-based approaches, not all can model time-varying interactions and complex baseline hazards. To address this, we propose Case-Base Neural Networks (CBNNs) as a new approach that combines the case-base sampling framework with flexible neural network architectures. Using a novel sampling scheme and data augmentation to naturally account for censoring, we construct a feed-forward neural network that includes time as an input. CBNNs predict the probability of an event occurring at a given moment to estimate the full hazard function. We compare the performance of CBNNs to regression and neural network-based survival methods in a simulation and three case studies using two time-dependent metrics. First, we examine performance on a simulation involving a complex baseline hazard and time-varying interactions to assess all methods, with CBNN outperforming competitors. Then, we apply all methods to three real data applications, with CBNNs outperforming the competing models in two studies and showing similar performance in the third. Our results highlight the benefit of combining case-base sampling with deep learning to provide a simple and flexible framework for data-driven modeling of single event survival outcomes that estimates time-varying effects and a complex baseline hazard by design. An R package is available at https://github.com/Jesse-Islam/cbnn.
format Preprint
id arxiv_https___arxiv_org_abs_2301_06535
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle Case-Base Neural Networks: survival analysis with time-varying, higher-order interactions
Islam, Jesse
Turgeon, Maxime
Sladek, Robert
Bhatnagar, Sahir
Machine Learning
In the context of survival analysis, data-driven neural network-based methods have been developed to model complex covariate effects. While these methods may provide better predictive performance than regression-based approaches, not all can model time-varying interactions and complex baseline hazards. To address this, we propose Case-Base Neural Networks (CBNNs) as a new approach that combines the case-base sampling framework with flexible neural network architectures. Using a novel sampling scheme and data augmentation to naturally account for censoring, we construct a feed-forward neural network that includes time as an input. CBNNs predict the probability of an event occurring at a given moment to estimate the full hazard function. We compare the performance of CBNNs to regression and neural network-based survival methods in a simulation and three case studies using two time-dependent metrics. First, we examine performance on a simulation involving a complex baseline hazard and time-varying interactions to assess all methods, with CBNN outperforming competitors. Then, we apply all methods to three real data applications, with CBNNs outperforming the competing models in two studies and showing similar performance in the third. Our results highlight the benefit of combining case-base sampling with deep learning to provide a simple and flexible framework for data-driven modeling of single event survival outcomes that estimates time-varying effects and a complex baseline hazard by design. An R package is available at https://github.com/Jesse-Islam/cbnn.
title Case-Base Neural Networks: survival analysis with time-varying, higher-order interactions
topic Machine Learning
url https://arxiv.org/abs/2301.06535