联合异常心音检测,标记弱或无标记。

IF 10.5 Q1 ENGINEERING, BIOMEDICAL Cyborg and bionic systems (Washington, D.C.) Pub Date : 2024-09-10 eCollection Date: 2024-01-01 DOI:10.34133/cbsystems.0152
Wanyong Qiu, Chen Quan, Yongzi Yu, Eda Kara, Kun Qian, Bin Hu, Björn W Schuller, Yoshiharu Yamamoto
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引用次数: 0

摘要

心血管疾病是导致死亡的主要原因,因此需要及早预防和诊断。利用人工智能(AI)模型,心音分析成为评估心血管健康状况的一种无创、普遍适用的方法。然而,现实世界的医疗数据分散在各个医疗机构,由于安全原因,数据共享受到限制,形成了 "数据孤岛"。为此,联合学习(FL)被广泛应用于医疗领域,它能有效地跨多个机构建模。此外,传统的监督分类方法需要完全标记的数据类别,例如,二元分类需要标记阳性和阴性样本。然而,标注医疗数据的过程耗时耗力,可能会导致误标注阴性样本。在本研究中,我们利用天真的正向无标记(PU)学习策略验证了 FL 框架。半监督 FL 模型可以直接从有限的正向样本集和大量的未标记样本池中学习。我们的重点是纵向 FL,以加强具有不同医疗记录特征空间的机构之间的合作。此外,我们的贡献还扩展到了特征重要性分析,我们探索了 6 种方法,并为检测异常心音提供了实用建议。这项研究的准确率高达 84%,与监督学习的结果不相上下,从而推动了 FL 在异常心音检测中的应用。
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Federated Abnormal Heart Sound Detection with Weak to No Labels.

Cardiovascular diseases are a prominent cause of mortality, emphasizing the need for early prevention and diagnosis. Utilizing artificial intelligence (AI) models, heart sound analysis emerges as a noninvasive and universally applicable approach for assessing cardiovascular health conditions. However, real-world medical data are dispersed across medical institutions, forming "data islands" due to data sharing limitations for security reasons. To this end, federated learning (FL) has been extensively employed in the medical field, which can effectively model across multiple institutions. Additionally, conventional supervised classification methods require fully labeled data classes, e.g., binary classification requires labeling of positive and negative samples. Nevertheless, the process of labeling healthcare data is time-consuming and labor-intensive, leading to the possibility of mislabeling negative samples. In this study, we validate an FL framework with a naive positive-unlabeled (PU) learning strategy. Semisupervised FL model can directly learn from a limited set of positive samples and an extensive pool of unlabeled samples. Our emphasis is on vertical-FL to enhance collaboration across institutions with different medical record feature spaces. Additionally, our contribution extends to feature importance analysis, where we explore 6 methods and provide practical recommendations for detecting abnormal heart sounds. The study demonstrated an impressive accuracy of 84%, comparable to outcomes in supervised learning, thereby advancing the application of FL in abnormal heart sound detection.

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来源期刊
CiteScore
7.70
自引率
0.00%
发文量
0
审稿时长
21 weeks
期刊最新文献
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