Local Wavelet-Based Filtering of Electromyographic Signals to Eliminate the Electrocardiographic-Induced Artifacts in Patients with Spinal Cord Injury.

Matthew Nitzken, Nihit Bajaj, Sevda Aslan, Georgy Gimel'farb, Ayman El-Baz, Alexander Ovechkin
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引用次数: 14

Abstract

Surface Electromyography (EMG) is a standard method used in clinical practice and research to assess motor function in order to help with the diagnosis of neuromuscular pathology in human and animal models. EMG recorded from trunk muscles involved in the activity of breathing can be used as a direct measure of respiratory motor function in patients with spinal cord injury (SCI) or other disorders associated with motor control deficits. However, EMG potentials recorded from these muscles are often contaminated with heart-induced electrocardiographic (ECG) signals. Elimination of these artifacts plays a critical role in the precise measure of the respiratory muscle electrical activity. This study was undertaken to find an optimal approach to eliminate the ECG artifacts from EMG recordings. Conventional global filtering can be used to decrease the ECG-induced artifact. However, this method can alter the EMG signal and changes physiologically relevant information. We hypothesize that, unlike global filtering, localized removal of ECG artifacts will not change the original EMG signals. We develop an approach to remove the ECG artifacts without altering the amplitude and frequency components of the EMG signal by using an externally recorded ECG signal as a mask to locate areas of the ECG spikes within EMG data. These segments containing ECG spikes were decomposed into 128 sub-wavelets by a custom-scaled Morlet Wavelet Transform. The ECG-related sub-wavelets at the ECG spike location were removed and a de-noised EMG signal was reconstructed. Validity of the proposed method was proven using mathematical simulated synthetic signals and EMG obtained from SCI patients. We compare the Root-mean Square Error and the Relative Change in Variance between this method, global, notch and adaptive filters. The results show that the localized wavelet-based filtering has the benefit of not introducing error in the native EMG signal and accurately removing ECG artifacts from EMG signals.

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基于局部小波滤波的肌电信号消除脊髓损伤患者心电图伪影。
表面肌电图(EMG)是临床实践和研究中用于评估运动功能的标准方法,以帮助诊断人类和动物模型的神经肌肉病理。参与呼吸活动的躯干肌肉肌电图记录可作为脊髓损伤(SCI)或其他与运动控制缺陷相关疾病患者呼吸运动功能的直接测量。然而,从这些肌肉记录的肌电电位经常受到心诱发的心电图信号的污染。消除这些伪影对精确测量呼吸肌电活动起着至关重要的作用。本研究旨在寻找一种消除肌电图记录中心电伪影的最佳方法。常规的全局滤波可以用来减少心电诱发的伪影。然而,这种方法可以改变肌电信号和改变生理相关信息。我们假设,与全局滤波不同,局部去除心电伪影不会改变原始肌电信号。我们开发了一种方法,通过使用外部记录的ECG信号作为掩膜来定位EMG数据中ECG尖峰的区域,从而在不改变EMG信号的幅度和频率成分的情况下去除ECG伪影。利用自定义的Morlet小波变换将这些包含心电尖峰的片段分解成128个子小波。去除心电尖峰处与心电相关的子小波,重构去噪后的心电信号。利用数学模拟合成信号和脊髓损伤患者肌电信号验证了该方法的有效性。我们比较了该方法与全局滤波、陷波滤波和自适应滤波的均方根误差和相对方差变化。结果表明,基于局部小波的滤波方法不仅不会在原有的肌电信号中引入误差,而且能够准确地去除肌电信号中的心电伪影。
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