Data-Driven Simulator for Mechanical Circulatory Support with Domain Adversarial Neural Process
Abstract
We propose a data-driven simulator for Mechanical Circulatory Support (MCS) devices, implemented as a probabilistic deep sequence model. Existing mechanical simulators for MCS rely on oversimplifying assumptions and are insensitive to patient-specific behavior, limiting their applicability to real-world treatment scenarios. To address these shortcomings, our model Domain Adversarial Neural Process (DANP) employs a neural process architecture, allowing it to capture the probabilistic relationship between MCS pump levels and aortic pressure measurements with uncertainty. We use domain adversarial training to combine real-world and simulation data, resulting in a more realistic and diverse representation of potential outcomes. Empirical results with an improvement of 19% in non-stationary trend prediction establish DANP as an effective tool for clinicians to understand and make informed decisions regarding MCS patient treatment.
Cite
Text
Sun et al. "Data-Driven Simulator for Mechanical Circulatory Support with Domain Adversarial Neural Process." Proceedings of the 6th Annual Learning for Dynamics & Control Conference, 2024.Markdown
[Sun et al. "Data-Driven Simulator for Mechanical Circulatory Support with Domain Adversarial Neural Process." Proceedings of the 6th Annual Learning for Dynamics & Control Conference, 2024.](https://mlanthology.org/l4dc/2024/sun2024l4dc-datadriven/)BibTeX
@inproceedings{sun2024l4dc-datadriven,
title = {{Data-Driven Simulator for Mechanical Circulatory Support with Domain Adversarial Neural Process}},
author = {Sun, Sophia and Chen, Wenyuan and Zhou, Zihao and Fereidooni, Sonia and Jortberg, Elise and Yu, Rose},
booktitle = {Proceedings of the 6th Annual Learning for Dynamics & Control Conference},
year = {2024},
pages = {1513-1525},
volume = {242},
url = {https://mlanthology.org/l4dc/2024/sun2024l4dc-datadriven/}
}