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Main Authors: Virkud, Arti, Edwards, Jessie K., Funk, Michele Jonsson, Chang, Patricia, Kshirsagar, Abhijit V., Gower, Emily W., Kosorok, Michael R.
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2501.07789
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author Virkud, Arti
Edwards, Jessie K.
Funk, Michele Jonsson
Chang, Patricia
Kshirsagar, Abhijit V.
Gower, Emily W.
Kosorok, Michael R.
author_facet Virkud, Arti
Edwards, Jessie K.
Funk, Michele Jonsson
Chang, Patricia
Kshirsagar, Abhijit V.
Gower, Emily W.
Kosorok, Michael R.
contents Identifying optimal medical treatments to improve survival has long been a critical goal of pharmacoepidemiology. Traditionally, we use an average treatment effect measure to compare outcomes between treatment plans. However, new methods leveraging advantages of machine learning combined with the foundational tenets of causal inference are offering an alternative to the average treatment effect. Here, we use three unique, precision medicine algorithms (random forests, residual weighted learning, efficient augmentation relaxed learning) to identify optimal treatment rules where patients receive the optimal treatment as indicated by their clinical history. First, we present a simple hypothetical example and a real-world application among heart failure patients using Medicare claims data. We next demonstrate how the optimal treatment rule improves the absolute risk in a hypothetical, three-modifier setting. Finally, we identify an optimal treatment rule that optimizes the time to outcome in a real-world heart failure setting. In both examples, we compare the average time to death under the optimized, tailored treatment rule with the average time to death under a universal treatment rule to show the benefit of precision medicine methods. The improvement under the optimal treatment rule in the real-world setting is greatest (additional ~9 days under the tailored rule) for survival time free of heart failure readmission.
format Preprint
id arxiv_https___arxiv_org_abs_2501_07789
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Using Statistical Precision Medicine to Identify Optimal Treatments in a Heart Failure Setting
Virkud, Arti
Edwards, Jessie K.
Funk, Michele Jonsson
Chang, Patricia
Kshirsagar, Abhijit V.
Gower, Emily W.
Kosorok, Michael R.
Applications
Identifying optimal medical treatments to improve survival has long been a critical goal of pharmacoepidemiology. Traditionally, we use an average treatment effect measure to compare outcomes between treatment plans. However, new methods leveraging advantages of machine learning combined with the foundational tenets of causal inference are offering an alternative to the average treatment effect. Here, we use three unique, precision medicine algorithms (random forests, residual weighted learning, efficient augmentation relaxed learning) to identify optimal treatment rules where patients receive the optimal treatment as indicated by their clinical history. First, we present a simple hypothetical example and a real-world application among heart failure patients using Medicare claims data. We next demonstrate how the optimal treatment rule improves the absolute risk in a hypothetical, three-modifier setting. Finally, we identify an optimal treatment rule that optimizes the time to outcome in a real-world heart failure setting. In both examples, we compare the average time to death under the optimized, tailored treatment rule with the average time to death under a universal treatment rule to show the benefit of precision medicine methods. The improvement under the optimal treatment rule in the real-world setting is greatest (additional ~9 days under the tailored rule) for survival time free of heart failure readmission.
title Using Statistical Precision Medicine to Identify Optimal Treatments in a Heart Failure Setting
topic Applications
url https://arxiv.org/abs/2501.07789