Wearable Multi-Channel Pulse Signal Acquisition System Based on Flexible MEMS Sensor Arrays with TSV Structure

Kang, Xiaoxiao; Huang, Lin; Zhang, Yitao; Yun, Shichang; Jiao, Binbin; Liu, Xin; Zhang, Jun; Li, Zhiqiang; Zhang, Haiying

doi:10.3390/biomimetics8020207

Biomimetics

2023

DOI: 10.3390/biomimetics8020207

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Wearable Multi-Channel Pulse Signal Acquisition System Based on Flexible MEMS Sensor Arrays with TSV Structure

Xiaoxiao Kang,

Lin Huang,

Yitao Zhang

et al.

Abstract: Micro-electro-mechanical system (MEMS) pressure sensors play a significant role in pulse wave acquisition. However, existing MEMS pulse pressure sensors bound with a flexible substrate by gold wire are vulnerable to crush fractures, leading to sensor failure. Additionally, establishing an effective mapping between the array sensor signal and pulse width remains a challenge. To solve the above problems, we propose a 24-channel pulse signal acquisition system based on a novel MEMS pressure sensor with a through-… Show more

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2024

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Cited by 2 publications

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A Novel Stable and High-Fidelity T-Structured Pulse Sensing System for Human Health Assessment

Yang,

Wu,

Qie

et al. 2024

IEEE Sensors J.

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A Novel Stable and High-Fidelity T-Structured Pulse Sensing System for Human Health Assessment

Yang,

Wu,

Qie

et al. 2024

IEEE Sensors J.

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Objective Evaluation of Pulse Width Using an Array Pulse Diagram

Bi,

Cui,

Yao

et al. 2024

J Evid Based Complementary Altern Med

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Background Pulse width, which can reflect qi, blood excess, and deficiency, has been used for diagnosing diseases and determining the prognosis in traditional Chinese medicine (TCM). This study aimed to devise an objective method to measure the pulse width based on an array pulse diagram for objective diagnosis. Methods The channel 6, the region wherein the pulse wave signal is the strongest, is located in the middle of the pulse sensor array and at the guan position of cunkou during data collection. Therefore, the main wave (h1) time of the pulse wave was collected from the channel 6 through calculation. The left h1 time was collected from the remaining 11 channels. The amplitudes at these time points were extracted as the h1 amplitudes for each channel. However, the pulse width could not be calculated accurately at 12 points. Consequently, a bioharmonic spline interpolation algorithm was used to interpolate the h1 amplitude data obtained from the horizontal and vertical points, yielding 651 (31 × 21) h1 amplitude data. The 651 data points were converted into a heat map to intuitively calculate the pulse width. The pulse width was calculated by multiplying the number of grids on the vertical axis with the unit length of the grid. The pulse width was determined by TCM doctors to verify the pulse width measurement accuracy. Meanwhile, a color Doppler ultrasound examination of the volunteers’ radial arteries was performed and the intravascular meridian widths of the radial artery compared with the calculated pulse widths to determine the reliability. Results The pulse width determined using the maximal h1 amplitude method was comparable with the radial artery intravascular meridian widths measured using color Doppler ultrasound. The h1 amplitude was higher in the high blood pressure group and the pulse width was greater. Conclusions The pulse width determined using the maximal h1 amplitude was objective and accurate. Comparison between the pulse widths of the normal and high blood pressure groups verified the reliability of the method.

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Wearable Multi-Channel Pulse Signal Acquisition System Based on Flexible MEMS Sensor Arrays with TSV Structure

Cited by 2 publications

References 39 publications

A Novel Stable and High-Fidelity T-Structured Pulse Sensing System for Human Health Assessment

A Novel Stable and High-Fidelity T-Structured Pulse Sensing System for Human Health Assessment

Objective Evaluation of Pulse Width Using an Array Pulse Diagram

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