Matin Khalili, Hamid GholamHosseini, Andrew Lowe, Matthew M Y Kuo
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引用次数: 0
Abstract
Current research focuses on improving electrocardiogram (ECG) monitoring systems to enable real-time and long-term usage, with a specific focus on facilitating remote monitoring of ECG data. This advancement is crucial for improving cardiovascular health by facilitating early detection and management of cardiovascular disease (CVD). To efficiently meet these demands, user-friendly and comfortable ECG sensors that surpass wet electrodes are essential. This has led to increased interest in ECG capacitive electrodes, which facilitate signal detection without requiring gel preparation or direct conductive contact with the body. This feature makes them suitable for wearables or integrated measurement devices. However, ongoing research is essential as the signals they measure often lack sufficient clinical accuracy due to susceptibility to interferences, particularly Motion Artifacts (MAs). While our primary focus is on studying MAs, we also address other limitations crucial for designing a high Signal-to-Noise Ratio (SNR) circuit and effectively mitigating MAs. The literature on the origins and models of MAs in capacitive electrodes is insufficient, which we aim to address alongside discussing mitigation methods. We bring attention to digital signal processing approaches, especially those using reference signals like Electrode-Tissue Impedance (ETI), as highly promising. Finally, we discuss its challenges, proposed solutions, and offer insights into future research directions.
目前的研究重点是改进心电图(ECG)监测系统,以实现实时和长期使用,特别是促进心电图数据的远程监测。这一进步对于通过促进心血管疾病(CVD)的早期检测和管理来改善心血管健康至关重要。为了有效地满足这些需求,超越湿电极的用户友好型和舒适型心电图传感器至关重要。因此,人们对心电图电容电极的兴趣与日俱增,因为这种电极无需制备凝胶或与人体直接导电接触,即可进行信号检测。这一特点使其适用于可穿戴设备或集成测量设备。然而,由于易受干扰,特别是运动伪差(MAs)的影响,它们测量的信号往往缺乏足够的临床准确性,因此持续的研究至关重要。虽然我们的主要重点是研究运动伪影,但我们也探讨了对设计高信噪比(SNR)电路和有效缓解运动伪影至关重要的其他限制因素。有关电容电极中 MA 的起源和模型的文献不足,我们在讨论缓解方法的同时,也致力于解决这一问题。我们将关注数字信号处理方法,尤其是使用电极-组织阻抗 (ETI) 等参考信号的方法,因为这些方法前景广阔。最后,我们讨论了其面临的挑战、建议的解决方案,并对未来的研究方向提出了见解。
期刊介绍:
Founded in 1963, Medical & Biological Engineering & Computing (MBEC) continues to serve the biomedical engineering community, covering the entire spectrum of biomedical and clinical engineering. The journal presents exciting and vital experimental and theoretical developments in biomedical science and technology, and reports on advances in computer-based methodologies in these multidisciplinary subjects. The journal also incorporates new and evolving technologies including cellular engineering and molecular imaging.
MBEC publishes original research articles as well as reviews and technical notes. Its Rapid Communications category focuses on material of immediate value to the readership, while the Controversies section provides a forum to exchange views on selected issues, stimulating a vigorous and informed debate in this exciting and high profile field.
MBEC is an official journal of the International Federation of Medical and Biological Engineering (IFMBE).
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