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Hauptverfasser: Pakravan, Samira, Evangelou, Nikolaos, Usdin, Maxime, Brooks, Logan, Lu, James
Format: Preprint
Veröffentlicht: 2024
Schlagworte:
Online-Zugang:https://arxiv.org/abs/2403.03274
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author Pakravan, Samira
Evangelou, Nikolaos
Usdin, Maxime
Brooks, Logan
Lu, James
author_facet Pakravan, Samira
Evangelou, Nikolaos
Usdin, Maxime
Brooks, Logan
Lu, James
contents Digital health technologies (DHT), such as wearable devices, provide personalized, continuous, and real-time monitoring of patient. These technologies are contributing to the development of novel therapies and personalized medicine. Gaining insight from these technologies requires appropriate modeling techniques to capture clinically-relevant changes in disease state. The data generated from these devices is characterized by being stochastic in nature, may have missing elements, and exhibits considerable inter-individual variability - thereby making it difficult to analyze using traditional longitudinal modeling techniques. We present a novel pharmacology-informed neural stochastic differential equation (SDE) model capable of addressing these challenges. Using synthetic data, we demonstrate that our approach is effective in identifying treatment effects and learning causal relationships from stochastic data, thereby enabling counterfactual simulation.
format Preprint
id arxiv_https___arxiv_org_abs_2403_03274
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle From Noise to Signal: Unveiling Treatment Effects from Digital Health Data through Pharmacology-Informed Neural-SDE
Pakravan, Samira
Evangelou, Nikolaos
Usdin, Maxime
Brooks, Logan
Lu, James
Quantitative Methods
Artificial Intelligence
Machine Learning
Dynamical Systems
I.2; G.3
Digital health technologies (DHT), such as wearable devices, provide personalized, continuous, and real-time monitoring of patient. These technologies are contributing to the development of novel therapies and personalized medicine. Gaining insight from these technologies requires appropriate modeling techniques to capture clinically-relevant changes in disease state. The data generated from these devices is characterized by being stochastic in nature, may have missing elements, and exhibits considerable inter-individual variability - thereby making it difficult to analyze using traditional longitudinal modeling techniques. We present a novel pharmacology-informed neural stochastic differential equation (SDE) model capable of addressing these challenges. Using synthetic data, we demonstrate that our approach is effective in identifying treatment effects and learning causal relationships from stochastic data, thereby enabling counterfactual simulation.
title From Noise to Signal: Unveiling Treatment Effects from Digital Health Data through Pharmacology-Informed Neural-SDE
topic Quantitative Methods
Artificial Intelligence
Machine Learning
Dynamical Systems
I.2; G.3
url https://arxiv.org/abs/2403.03274