人工智能检测远程监控数据中的噪声事件

IF 2.2 Q2 CARDIAC & CARDIOVASCULAR SYSTEMS Journal of Arrhythmia Pub Date : 2024-04-11 DOI:10.1002/joa3.13037

Nobuhiro Nishii MD, PhD, Kensuke Baba PhD, Ken'ichi Morooka PhD, Haruto Shirae, Tomofumi Mizuno MD, Takuro Masuda MD, Akira Ueoka MD, PhD, Saori Asada MD, PhD, Masakazu Miyamoto MD, Kentaro Ejiri MD, PhD, Satoshi Kawada MD, PhD, Koji Nakagawa MD, PhD, Kazufumi Nakamura MD, PhD, Hiroshi Morita MD, PhD, Shinsuke Yuasa MD, PhD

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引用次数: 0

摘要

心脏植入式电子设备（CIED）的远程监控（RM）可以及早发现各种事件。然而，CIED 的诊断能力还不够，尤其是对导联线故障的诊断能力。导联故障的首次通知几乎都是噪音事件，这些事件被 CIED 检测为心律失常。人类必须分析心内电图才能准确检测出导联失效。然而，心律失常事件的数量太大，人类无法进行分析。我们分析了 21 918 个 RM 数据，其中美敦力和波士顿科学的数据分别为 12 925 个和 1884 个。我们分析了 21 918 个 RM 数据，包括 12 925 个美敦力数据和 1884 个波士顿科学数据，其中美敦力数据和波士顿科学数据分别有 153 个和 52 个被人工分析诊断为噪声事件。在美敦力公司的数据中，有 306 个事件（包括 153 个噪声事件和从 12 692 个非噪声事件中随机抽取的 153 个事件）通过卷积神经网络进行了五倍交叉验证分析。美敦力的精确率、召回率、F1 分数、准确率和曲线下面积分别为 85.8 ± 4.0%、91.6 ± 6.7%、88.4 ± 2.0%、88.0 ± 2.0% 和 0.958 ± 0.021；波士顿科学的精确率、召回率、F1 分数、准确率和曲线下面积分别为 88.4 ± 12.8%、81.0 ± 9.3%、84.1 ± 8.3%、84.2 ± 8.3% 和 0.928 ± 0.041。使用加权损失函数进行五倍交叉验证可提高召回率。人工智能分析可能有助于早期准确检测出导联故障事件。

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Artificial intelligence to detect noise events in remote monitoring data

Background

Remote monitoring (RM) of cardiac implantable electrical devices (CIEDs) can detect various events early. However, the diagnostic ability of CIEDs has not been sufficient, especially for lead failure. The first notification of lead failure was almost noise events, which were detected as arrhythmia by the CIED. A human must analyze the intracardiac electrogram to accurately detect lead failure. However, the number of arrhythmic events is too large for human analysis. Artificial intelligence (AI) seems to be helpful in the early and accurate detection of lead failure before human analysis.

Objective

To test whether a neural network can be trained to precisely identify noise events in the intracardiac electrogram of RM data.

Methods

We analyzed 21 918 RM data consisting of 12 925 and 1884 Medtronic and Boston Scientific data, respectively. Among these, 153 and 52 Medtronic and Boston Scientific data, respectively, were diagnosed as noise events by human analysis. In Medtronic, 306 events, including 153 noise events and randomly selected 153 out of 12 692 nonnoise events, were analyzed in a five-fold cross-validation with a convolutional neural network. The Boston Scientific data were analyzed similarly.

Results

The precision rate, recall rate, F1 score, accuracy rate, and the area under the curve were 85.8 ± 4.0%, 91.6 ± 6.7%, 88.4 ± 2.0%, 88.0 ± 2.0%, and 0.958 ± 0.021 in Medtronic and 88.4 ± 12.8%, 81.0 ± 9.3%, 84.1 ± 8.3%, 84.2 ± 8.3% and 0.928 ± 0.041 in Boston Scientific. Five-fold cross-validation with a weighted loss function could increase the recall rate.