An Untethered Heart Rhythm Monitoring System with Automated AI-Based Arrhythmia Detection for Closed-Loop Experimental Application

Shanliang Deng, Bram L den Ouden, Tim De Coster, Cindy I Bart, Wilhelmina H Bax, René H Poelma, Antoine AF de Vries, Guo Qi Zhang, Vincent Portero, Daniël A Pijnappels
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Abstract

The heart produces bioelectrical signals, which can be measured as an electrocardiogram (ECG) for the detection of rhythm disturbances. Rapid and precise detection of these arrhythmias is crucial for their termination by closed-looped therapeutic interventions to counteract detrimental effects. However, there is a current lack of such systems tailored for experimental cardiovascular applications. This hampers not only in-depth mechanistic studies but also translational testing of new therapeutic strategies, especially in an untethered manner in awake animal models. To break new ground, recent advances to develop a non-invasive AI-supported heart rhythm monitoring system for untethered automated arrhythmia detection in a continuous manner is combined. This system is housed in a lightweight jacket for mobile use and includes an on-skin ECG sensor, a low-power microprocessor unit, a massive data storage unit, and a power-management system. By implementing a novel hybrid algorithm based on so-called heart rate (R-R) variability and a case-specific AI model, 100% sensitivity and 95% specificity is achieved in detecting atrial arrhythmias within 2 s upon initiation in adult rats. Thereby, the novel system sets the stage for advanced mechanistic studies and therapeutic testing, including closed-loop applications aiming for the termination of a broad range of atrial arrhythmias.

Abstract Image

用于闭环实验应用的基于人工智能的自动心律失常检测的无系留心律监测系统
心脏会产生生物电信号,这些信号可以通过心电图(ECG)进行测量,以检测心律失常。快速、精确地检测出这些心律失常对于通过闭环治疗干预来终止心律失常以消除有害影响至关重要。然而,目前还缺乏为心血管实验应用量身定制的此类系统。这不仅阻碍了深入的机理研究,也阻碍了新治疗策略的转化测试,尤其是在清醒动物模型中以非捆绑方式进行的测试。为了开辟新天地,我们结合最近在开发无创人工智能支持的心律监测系统方面取得的进展,以连续的方式进行不受约束的自动心律失常检测。该系统安装在轻便的外套中,适合移动使用,包括一个皮肤心电图传感器、一个低功耗微处理器单元、一个海量数据存储单元和一个电源管理系统。通过采用基于所谓心率(R-R)变异性和特定病例人工智能模型的新型混合算法,在成年大鼠心律失常发生后 2 秒内检测心房心律失常的灵敏度达到 100%,特异性达到 95%。因此,该新型系统为先进的机理研究和治疗测试(包括旨在终止各种房性心律失常的闭环应用)奠定了基础。
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