A signal sensing system for monitoring the movement of human respiratory muscle based on the thin-film varistor_Journal of Biomedical Engineering

Authors：

 YUAN Yueyang ¹ , ZHANG Zhongping ¹ , XIE Lixin ² , HUANG Haoxuan ³ , LIU Wei ³

1. Innovation Base of Intelligent Diagnostic and Therapeutic in Respiration, Hunan City University, Yiyang, Hunan 413099, P. R. China;
2. Department of Respiratory and Critical Care Medicine, Chinese PLA General Hospital, Beijing 100853, P. R. China;
3. Department of Research and Development, Hunan Micomme Medical Development Co., Ltd, Changsha 410000, P. R. China;

Corresponding author：

YUAN Yueyang, Email: yuanyueyang@hncu.edu.cn

Keywords：

Thin-film varistor; Respiratory muscle movement; Patient-ventilator synchrony

DOI：

10.7507/1001-5515.202407055

Video：

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In order to accurately capture the respiratory muscle movement and extract the synchronization signals corresponding to the breathing phases, a comprehensive signal sensing system for sensing the movement of the respiratory muscle was developed with applying the thin-film varistor FSR402 IMS-C07A in this paper. The system integrated a sensor, a signal processing circuit, and an application program to collect, amplify and denoise electronic signals. Based on the respiratory muscle movement sensor and a STM32F107 development board, an experimental platform was designed to conduct experiments. The respiratory muscle movement data and respiratory airflow data were collected from 3 healthy adults for comparative analysis. In this paper, the results demonstrated that the method for determining respiratory phase based on the sensing the respiratory muscle movement exhibited strong real-time performance. Compared to traditional airflow-based respiratory phase detection, the proposed method showed a lead times ranging from 33 to 210 ms [(88.3 ± 47.9) ms] for expiration switched into inspiration and 17 to 222 ms [(92.9 ± 63.8) ms] for inspiration switched into expiration, respectively. When this system is applied to trigger the output of the ventilator, it will effectively improve the patient-ventilator synchrony and facilitate the ventilation treatment for patients with respiratory diseases.

1.	张巍, 胡知诿, 马小建. 机械通气中患者人机不同步研究进展. 中国医疗器械信息, 2023, 29(13): 39-42,165.
2.	Shevade M, Apte K. Patient-ventilator asynchrony: the power struggle. IJRC, 2015, 4(2): 594-598.
3.	Gonzalez-Bermejo J, Janssens J P, Rabec C, et al. Framework for patient-ventilator asynchrony during long-term non-invasive ventilation. Thorax, 2019, 74: 715-717.
4.	Lucia M, Gilda C, Roberta C, et al. Patient-ventilator asynchronies: clinical implications and practical solutions. Resp Care, 2020, 65(11): 1751-1766.
5.	Bruno D O, Nahla A, Ahmed T, et al. Patient-ventilator dyssynchrony in critically ill patients. J Clin Med, 2021, 4550(10): 1-14.
6.	Elvira-Markela A, Dimitris G S, Evangelia A. Patient-ventilator dyssynchrony. Korean J Crit Care Med, 2017, 32(4): 307-322.
7.	张建恒, 罗群, 张会锦, 等. 无创比例辅助通气与压力支持通气不同辅助水平对慢性阻塞性肺疾病患者呼吸做功的影响. 中华结核和呼吸杂志, 2017, 40(6): 450-456.
8.	陈宇清, 周新. 压力控制通气的发展演变与临床应用. 中华结核和呼吸杂志, 2014, 37(2): 156-158.
9.	周娟, 吴昊, 曹德森. 三种新型呼吸机压力支持模式下的人机同步性能研究. 生物医学工程学杂志, 2014, 31(4): 793-797.
10.	孙秀梅, 陈光强, 杨燕琳, 等. 辅助通气时应用食道测压管的气囊压力-容积曲线校正食道压的可行性研究. 中华危重病急救医学, 2020, 32(7): 808-813.
11.	Bailey J M. Management of patient-ventilator asynchrony. ANES, 2021, 134(4): 629-636.
12.	吴晓燕, 殷静静, 於江泉, 等. 不同机械通气模式对人机同步性以及膈肌功能影响的实验研究. 中华医学杂志, 2020, 100(21): 1662-1667.
13.	Liu L, Xu X T, Yu Y, et al. Neural control of pressure support ventilation improved patient-ventilator synchrony in patients with different respiratory system mechanical properties: a prospective, crossover trial. CMJ, 2021, 134(3): 281-291.
14.	Fang S J, Chen C C, Liao D L, et al. Neurally adjusted ventilatory assist in infants: A review article. Pediatr Neonatol, 2023, 64(1): 5-11.

1. 张巍, 胡知诿, 马小建. 机械通气中患者人机不同步研究进展. 中国医疗器械信息, 2023, 29(13): 39-42,165.
2. Shevade M, Apte K. Patient-ventilator asynchrony: the power struggle. IJRC, 2015, 4(2): 594-598.
3. Gonzalez-Bermejo J, Janssens J P, Rabec C, et al. Framework for patient-ventilator asynchrony during long-term non-invasive ventilation. Thorax, 2019, 74: 715-717.
4. Lucia M, Gilda C, Roberta C, et al. Patient-ventilator asynchronies: clinical implications and practical solutions. Resp Care, 2020, 65(11): 1751-1766.
5. Bruno D O, Nahla A, Ahmed T, et al. Patient-ventilator dyssynchrony in critically ill patients. J Clin Med, 2021, 4550(10): 1-14.
6. Elvira-Markela A, Dimitris G S, Evangelia A. Patient-ventilator dyssynchrony. Korean J Crit Care Med, 2017, 32(4): 307-322.
7. 张建恒, 罗群, 张会锦, 等. 无创比例辅助通气与压力支持通气不同辅助水平对慢性阻塞性肺疾病患者呼吸做功的影响. 中华结核和呼吸杂志, 2017, 40(6): 450-456.
8. 陈宇清, 周新. 压力控制通气的发展演变与临床应用. 中华结核和呼吸杂志, 2014, 37(2): 156-158.
9. 周娟, 吴昊, 曹德森. 三种新型呼吸机压力支持模式下的人机同步性能研究. 生物医学工程学杂志, 2014, 31(4): 793-797.
10. 孙秀梅, 陈光强, 杨燕琳, 等. 辅助通气时应用食道测压管的气囊压力-容积曲线校正食道压的可行性研究. 中华危重病急救医学, 2020, 32(7): 808-813.
11. Bailey J M. Management of patient-ventilator asynchrony. ANES, 2021, 134(4): 629-636.
12. 吴晓燕, 殷静静, 於江泉, 等. 不同机械通气模式对人机同步性以及膈肌功能影响的实验研究. 中华医学杂志, 2020, 100(21): 1662-1667.
13. Liu L, Xu X T, Yu Y, et al. Neural control of pressure support ventilation improved patient-ventilator synchrony in patients with different respiratory system mechanical properties: a prospective, crossover trial. CMJ, 2021, 134(3): 281-291.
14. Fang S J, Chen C C, Liao D L, et al. Neurally adjusted ventilatory assist in infants: A review article. Pediatr Neonatol, 2023, 64(1): 5-11.

Journal of Biomedical Engineering

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