BeatProfiler:心脏功能的多模态体外分析实现了疾病和药物的机器学习分类

IF 2.7 Q3 ENGINEERING, BIOMEDICAL
Youngbin Kim;Kunlun Wang;Roberta I. Lock;Trevor R. Nash;Sharon Fleischer;Bryan Z. Wang;Barry M. Fine;Gordana Vunjak-Novakovic
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引用次数: 0

摘要

目标:收缩反应和钙处理是了解心脏功能和生理学的核心,然而量化这些指标的现有分析方法往往耗时长、容易出错,或者需要专业设备/许可证。我们开发了一套心脏分析工具 BeatProfiler,旨在量化多个体外心脏模型的收缩功能、钙处理和发力情况,并应用下游机器学习方法进行深度表型和分类。方法:我们首先用一个固定数据集与现有工具进行比对,验证 BeatProfiler 的准确性、稳健性和速度。我们还进一步证实了它能够稳健地描述疾病特征和剂量依赖性药物反应。然后,我们证明了自动采集管道获得的数据可进一步用于机器学习(ML)分析,对限制性心肌病的疾病模型进行表型,并分析心肌活性药物的功能反应。为了对这些生物信号进行准确分类,我们应用了基于特征的 ML 和深度学习模型(时序卷积-双向长短期记忆模型或 TCN-BiLSTM)。结果与现有工具的基准测试表明,BeatProfiler 通过提高低信号数据的灵敏度、减少误报率以及将分析速度提高 7 到 50 倍,比现有工具更好地检测和分析了收缩和钙信号。在已发表方法(PMs)准确检测到的信号中,BeatProfiler 提取的特征与 PMs 显示出很高的相关性,这证实了它的可靠性以及与 PMs 的一致性。BeatProfiler 提取的特征对限制性心肌病心肌细胞和同源健康对照进行了分类,准确率高达 98%,并将松弛 90 识别为最主要的区分特征,这与之前的研究结果一致。我们还表明,我们的 TCN-BiLSTM 模型能够以 96% 的准确率对无药物对照和 4 种具有不同作用机制的心脏病药物进行分类。我们进一步在基于卷积的模型上应用 Grad-CAM 来识别这些药物对钙信号扰动的特征区域。结论:我们预计 BeatProfiler 的功能将有助于通过快速表型推进心脏生物学的体外研究,揭示心脏健康和疾病的内在机制,并对心脏疾病和药物反应进行客观分类。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
BeatProfiler: Multimodal In Vitro Analysis of Cardiac Function Enables Machine Learning Classification of Diseases and Drugs
Goal: Contractile response and calcium handling are central to understanding cardiac function and physiology, yet existing methods of analysis to quantify these metrics are often time-consuming, prone to mistakes, or require specialized equipment/license. We developed BeatProfiler, a suite of cardiac analysis tools designed to quantify contractile function, calcium handling, and force generation for multiple in vitro cardiac models and apply downstream machine learning methods for deep phenotyping and classification. Methods: We first validate BeatProfiler's accuracy, robustness, and speed by benchmarking against existing tools with a fixed dataset. We further confirm its ability to robustly characterize disease and dose-dependent drug response. We then demonstrate that the data acquired by our automatic acquisition pipeline can be further harnessed for machine learning (ML) analysis to phenotype a disease model of restrictive cardiomyopathy and profile cardioactive drug functional response. To accurately classify between these biological signals, we apply feature-based ML and deep learning models (temporal convolutional-bidirectional long short-term memory model or TCN-BiLSTM). Results: Benchmarking against existing tools revealed that BeatProfiler detected and analyzed contraction and calcium signals better than existing tools through improved sensitivity in low signal data, reduction in false positives, and analysis speed increase by 7 to 50-fold. Of signals accurately detected by published methods (PMs), BeatProfiler's extracted features showed high correlations to PMs, confirming that it is reliable and consistent with PMs. The features extracted by BeatProfiler classified restrictive cardiomyopathy cardiomyocytes from isogenic healthy controls with 98% accuracy and identified relax90 as a top distinguishing feature in congruence with previous findings. We also show that our TCN-BiLSTM model was able to classify drug-free control and 4 cardiac drugs with different mechanisms of action at 96% accuracy. We further apply Grad-CAM on our convolution-based models to identify signature regions of perturbations by these drugs in calcium signals. Conclusions: We anticipate that the capabilities of BeatProfiler will help advance in vitro studies in cardiac biology through rapid phenotyping, revealing mechanisms underlying cardiac health and disease, and enabling objective classification of cardiac disease and responses to drugs.
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来源期刊
CiteScore
9.50
自引率
3.40%
发文量
20
审稿时长
10 weeks
期刊介绍: The IEEE Open Journal of Engineering in Medicine and Biology (IEEE OJEMB) is dedicated to serving the community of innovators in medicine, technology, and the sciences, with the core goal of advancing the highest-quality interdisciplinary research between these disciplines. The journal firmly believes that the future of medicine depends on close collaboration between biology and technology, and that fostering interaction between these fields is an important way to advance key discoveries that can improve clinical care.IEEE OJEMB is a gold open access journal in which the authors retain the copyright to their papers and readers have free access to the full text and PDFs on the IEEE Xplore® Digital Library. However, authors are required to pay an article processing fee at the time their paper is accepted for publication, using to cover the cost of publication.
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