Enhancing visual seismocardiography in noisy environments with adaptive bidirectional filtering for Cardiac Health Monitoring.

IF 3.3 3区 医学 Q2 MEDICAL INFORMATICS
Geetha N, C Rohith Bhat, Mahesh Tr, Temesgen Engida Yimer
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Abstract

Background: Wearable sensors have revolutionized cardiac health monitoring, with Seismocardiography (SCG) at the forefront due to its non-invasive nature. However, the substantial motion artefacts have hindered the translation of SCG-based medical applications, primarily induced by walking. In contrast, our innovative technique, Adaptive Bidirectional Filtering (ABF), surpasses these challenges by refining SCG signals more effectively than any motion-induced noise. ABF leverages a noise-cancellation algorithm, operating on the benefits of the Redundant Multi-Scale Wavelet Decomposition (RMWD) and the bidirectional filtering framework, to achieve optimal signal quality.

Methodology: The ABF technique is a two-stage process that diminishes the artefacts emanating from motion. The first step by RMWD is the identification of the heart-associated signals and the isolating samples with those related frequencies. Subsequently, the adaptive bidirectional filter operates in two dimensions: it uses Time-Frequency masking that eliminates temporal noise while engaging in non-negative matrix Decomposition to ensure spatial correlation and dorsoventral vibration reduction jointly. The main component that is altered from the other filters is the recursive structure that changes to the motion-adapted filter, which uses vertical axis accelerometer data to differentiate better between accurate SCG signals and motion artefacts.

Outcome: Our empirical tests demonstrate exceptional signal improvement with the application of our ABF approach. The accuracy in heart rate estimation reached an impressive r-squared value of 0.95 at - 20 dB SNR, significantly outperforming the baseline value, which ranged from 0.1 to 0.85. The effectiveness of the motion-artifact-reduction methodology is also notable at an SNR of - 22 dB. Consequently, ECG inputs are not required. This method can be seamlessly integrated into noisy environments, enhancing ECG filtering, automatic beat detection, and rhythm interpretation processes, even in highly variable conditions. The ABF method effectively filters out up to 97% of motion-related noise components within the SCG signal from implantable devices. This advancement is poised to become an integral part of routine patient monitoring.

利用自适应双向滤波增强嘈杂环境中的可视化地震心动图,用于心脏健康监测。
背景:可穿戴传感器给心脏健康监测带来了革命性的变化,其中地震心动图(SCG)因其无创性而处于领先地位。然而,大量的运动伪影阻碍了基于 SCG 的医疗应用的转化,这些运动伪影主要是由行走引起的。与此相反,我们的创新技术--自适应双向滤波(ABF)--超越了这些挑战,比任何运动引起的噪音都能更有效地细化 SCG 信号。ABF 利用冗余多尺度小波分解(RMWD)和双向滤波框架的优势,采用噪音消除算法,以达到最佳信号质量:ABF 技术分为两个阶段,可减少运动产生的伪影。RMWD 的第一步是识别与心脏相关的信号,并分离出与这些相关频率的样本。随后,自适应双向滤波器从两个维度进行操作:使用时间-频率掩蔽消除时间噪声,同时进行非负矩阵分解以确保空间相关性,并共同减少背腹振动。与其他滤波器不同的主要部分是递归结构,它改变为运动适应滤波器,利用垂直轴加速度计数据更好地区分准确的 SCG 信号和运动伪影:我们的实证测试表明,应用 ABF 方法后,信号得到了显著改善。在 - 20 dB SNR 条件下,心率估计的准确性达到了令人印象深刻的 0.95 r 平方值,明显优于 0.1 至 0.85 之间的基线值。在信噪比为 - 22 dB 时,运动伪影减少方法的效果也很明显。因此,不需要心电图输入。这种方法可以无缝集成到嘈杂环境中,增强心电图滤波、自动节拍检测和心律解读过程,即使在高度多变的条件下也是如此。ABF 方法可有效滤除植入式设备 SCG 信号中高达 97% 的运动相关噪声成分。这一进步有望成为常规病人监护不可或缺的一部分。
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
CiteScore
7.20
自引率
5.70%
发文量
297
审稿时长
1 months
期刊介绍: BMC Medical Informatics and Decision Making is an open access journal publishing original peer-reviewed research articles in relation to the design, development, implementation, use, and evaluation of health information technologies and decision-making for human health.
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