A lightweight network based on multi-feature pseudo-color mapping for arrhythmia recognition.

IF 4.7 3区医学 Q1 MEDICAL INFORMATICS

Health Information Science and Systems Pub Date : 2024-09-04 eCollection Date: 2024-12-01 DOI:10.1007/s13755-024-00304-8

Yijun Ma, Junyan Li, Jinbiao Zhang, Jilin Wang, Guozhen Sun, Yatao Zhang

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引用次数: 0

Abstract

Heartbeats classification is a crucial tool for arrhythmia diagnosis. In this study, a multi-feature pseudo-color mapping (MfPc Mapping) was proposed, and a lightweight FlexShuffleNet was designed to classify heartbeats. MfPc Mapping converts one-dimensional (1-D) electrocardiogram (ECG) recordings into corresponding two-dimensional (2-D) multi-feature RGB graphs, and it offers good excellent interpretability and data visualization. FlexShuffleNet is a lightweight network that can be adapted to classification tasks of varying complexity by tuning hyperparameters. The method has three steps. The first step is data preprocessing, which includes de-noising the raw ECG recordings, removing baseline drift, extracting heartbeats, and performing data balancing, the second step is transforming the heartbeats using MfPc Mapping. Finally, the FlexShuffleNet is employed to classify heartbeats into 14 categories. This study was evaluated on the test set of the MIT-BIH arrhythmia database (MIT/BIH DB), and it yielded the results i.e., accuracy of 99.77%, sensitivity of 94.60%, precision of 89.83% and specificity of 99.85% and F1-score of 0.9125 in 14-category classification task. Additionally, validation on Shandong Province Hospital database (SPH DB) yielded the results i.e., accuracy of 92.08%, sensitivity of 93.63%, precision of 91.25% and specificity of 99.85% and F1-score of 0.9315. The results show the satisfied performance of the proposed method.

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基于多特征伪彩色映射的轻量级心律失常识别网络。

心跳分类是心律失常诊断的重要工具。本研究提出了一种多特征伪彩色映射（MfPc Mapping），并设计了一个轻量级的 FlexShuffleNet 来对心跳进行分类。MfPc Mapping 可将一维（1-D）心电图（ECG）记录转换成相应的二维（2-D）多特征 RGB 图形，具有良好的可解释性和数据可视化。FlexShuffleNet 是一种轻量级网络，可通过调整超参数适应不同复杂度的分类任务。该方法分为三个步骤。第一步是数据预处理，包括对原始心电图记录进行去噪、去除基线漂移、提取心搏和进行数据平衡；第二步是使用 MfPc 映射转换心搏。最后，使用 FlexShuffleNet 将心跳分为 14 类。这项研究在 MIT-BIH 心律失常数据库（MIT/BIH DB）的测试集上进行了评估，结果显示，在 14 类分类任务中，准确率为 99.77%，灵敏度为 94.60%，精确度为 89.83%，特异性为 99.85%，F1 分数为 0.9125。此外，山东省医院数据库（SPH DB）的验证结果为：准确率 92.08%，灵敏度 93.63%，精确度 91.25%，特异性 99.85%，F1 分数 0.9315。这些结果表明，拟议方法的性能令人满意。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Health Information Science and Systems MEDICAL INFORMATICS-

CiteScore

11.30

自引率

5.00%

发文量

期刊介绍： Health Information Science and Systems is a multidisciplinary journal that integrates artificial intelligence/computer science/information technology with health science and services, embracing information science research coupled with topics related to the modeling, design, development, integration and management of health information systems, smart health, artificial intelligence in medicine, and computer aided diagnosis, medical expert systems. The scope includes: i.) smart health, artificial Intelligence in medicine, computer aided diagnosis, medical image processing, medical expert systems ii.) medical big data, medical/health/biomedicine information resources such as patient medical records, devices and equipments, software and tools to capture, store, retrieve, process, analyze, optimize the use of information in the health domain, iii.) data management, data mining, and knowledge discovery, all of which play a key role in decision making, management of public health, examination of standards, privacy and security issues, iv.) development of new architectures and applications for health information systems.