Investigating the mechanism of the high frequency ventilation for the oscillation airflow between left and right lungs_Journal of Biomedical Engineering

Authors：

 YUAN Yueyang ¹ , CHEN Yuqing ² , XIAO Hui ² , DAI Zheng ³ , LIU Wei ³

1. School of Mechanical and electrical Engineering, Hunan City University, Yiyang, Hunan 413099, P.R.China;
2. Department of Respiratory medicine, Shanghai Chest Hospital, Affiliated Hospital of Shanghai Jiao Tong University, Shanghai 200030, P.R.China;
3. Hunan Micomme Medical Development Co., Ltd, Changsha 410000, P.R.China;

Corresponding author：

YUAN Yueyang, Email: sunmoonanfen@163.com

Keywords：

high frequency ventilation; ventilation mechanism; pendelluft ventilation

DOI：

10.7507/1001-5515.201810003

Video：

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Traditionally, adequate tidal volume is considered to be a necessary condition to support respiratory patient breathing. But the high frequency ventilation (HFV) with a small tidal volume can still support the respiratory patient breathing well. In order to further explore the mechanisms of HFV, the pendelluft ventilation between left and right lungs was proposed in this paper. And a test platform by using two fresh sheep lungs was developed for investigating the pendelluft ventilation between the left and right lungs. Furthermore, considering the viscous resistance (R), inertance (I) and lung compliance (C) in the lung, a second-order lung ventilation model was designed to inspect and evaluate the pendelluft ventilation between left lung and right lungs. On referring to both results of experiments in practice and simulation in MATLAB Simulink, between the left and right lungs, the phase difference in their airflow happens during HFV at some frequencies. And the pendelluft ventilation between the left and right lungs is resulted by the phase difference, even if the total airflow entering a whole lung is 0. Under HFV, the pendelluft ventilation between left and right lungs will benefit the lungs being more adequately ventilated, and will be improve the utilization rate of oxygen in the lungs.

Citation： YUAN Yueyang, CHEN Yuqing, XIAO Hui, DAI Zheng, LIU Wei. Investigating the mechanism of the high frequency ventilation for the oscillation airflow between left and right lungs. Journal of Biomedical Engineering, 2019, 36(3): 393-400. doi: 10.7507/1001-5515.201810003 Copy

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2.	Aktas S, Unal S, Aksu M, et al. Nasal HFOV with binasal cannula appears effective and feasible in ELBW newborns. J Trop Pediatr, 2016, 62(2): 165-168.
3.	Goffi A, Ferguson N D. High-frequency oscillatory ventilation for early acute respiratory distress syndrome in adults. Curr Opin Crit Care, 2014, 20(1): 77-85.
4.	刘超, 郭强, 王佳佳, 等. 短期使用高频振荡通气对重症人感染 H7N9禽流感合并 ARDS 患者氧合的临床观察. 中国急救医学, 2016, 36(1): 67-69.
5.	黄佳, 袁琳, 陈超. 新生儿无创高频振荡通气的研究进展. 中国当代儿科杂志, 2017, 19(5): 607-611.
6.	Fischer H S, Bohlin K, Buehrer C A, et al. Nasal high-frequency oscillation ventilation in neonates: a survey in five European countries. Eur J Pediatr, 2015, 174(4): 465-471.
7.	崔彦芹, 陈欣欣, 李凤香, 等. 高频振荡通气治疗小儿先天性心脏病术后严重肺出血的有效性及安全性. 中华胸心血管外科杂志, 2014, 30(1): 17-20.
8.	Pillow J J. High-frequency oscillatory ventilation: mechanisms of gas exchange and lung mechanics. Crit Care Med, 2005, 33(3 Suppl): S135-S141.
9.	封成芳. 高频震荡通气治疗新生儿呼吸窘迫综合征的机制及应用进展. 齐齐哈尔医学院学报, 2016, 37(3): 379-381.
10.	Otis A B, Mckerrow C B, Bartlett R A, et al. Mechanical factors in distribution of pulmonary ventilation. J Appl Physiol, 1956, 8(4): 427-443.
11.	Isabey D, Harf A, Chang H K. Alveolar ventilation during high-frequency oscillation: core dead space concept. Journal of Applied Physiology Respiratory Environmental & Exercise Physiology, 1984, 56(3): 700-907.
12.	Lehr J L, Butler J P, Westerman P A, et al. Photographic measurement of pleural surface motion during lung oscillation. J Appl Physiol, 1985, 59(2): 623-633.
13.	Lee W J, Kawahashi M, Hirahara H. Experimental analysis of pendelluft flow generated by HFOV in a human airway model. Physiol Meas, 2006, 27(8): 661-674.
14.	Greenblatt E E, Butler J P, Venegas J G. Pendelluft in the bronchial tree. J Appl Physiol, 2014, 117(9): 979-988.
15.	Yuan Yueyang, Sun J G, Wang Baicun, et al. A noninvasive high frequency oscillation ventilator: Achieved by utilizing a blower and a valve. Review of Scientific Instruments, 2016, 87(2): 38-45.
16.	Diong B, Nazeran H, Nava P, et al. Modeling human respiratory impedance. IEEE Engineering in Medicine Biology Magazine, 2007, 26(1): 48-55.
17.	高雨仁, 刘祯唐, 孙凤喈. 国人气管-支气管-肺段支气管长度, 直径和分支角度的研究(一). 山西医药杂志, 1981, 10(2): 20-24.
18.	朱香亭, 胡小丽. 国人气管、支气管、肺段支气管长度、矢径、横径、直径的测量及典型. 解剖学报, 1989, 20(4): 342-349.
19.	West J B. Respiratory Physiology: the essentials. 9th edition, Lippincott Williams & Wilkins, 2012: 1-23.
20.	Martin Rozanek, Karel Roubik. Modeling of the respiratory system in Maltab. (2014-05-28). https://www.researchgate.net/publication/237571338.
21.	Jongh de F H C. Ventilation modelling of the human lung. Handbook of Developmental Neurotoxicology, 1995: 439-450.
22.	Kacmarek R M, Dimas S, Mack Craig W. 袁月华, 郭丰(译). 呼吸治疗学精要. 第4版. 北京: 人民军医出版社, 2015: 66-75.
23.	Andrianopoulos V, Vanfleteren L E, Jarosch I, et al. Transcutaneous carbon-dioxide partial pressure trends during six-minute walk test in patients with very severe COPD. Respir Physiol Neurobiol, 2016, 233: 52-59.

1. 潘维伟, 童笑梅. 2007-2016年10年间早产儿肺出血的治疗与预后分析. 中国当代儿科杂志, 2018, 20(4): 255-260.
2. Aktas S, Unal S, Aksu M, et al. Nasal HFOV with binasal cannula appears effective and feasible in ELBW newborns. J Trop Pediatr, 2016, 62(2): 165-168.
3. Goffi A, Ferguson N D. High-frequency oscillatory ventilation for early acute respiratory distress syndrome in adults. Curr Opin Crit Care, 2014, 20(1): 77-85.
4. 刘超, 郭强, 王佳佳, 等. 短期使用高频振荡通气对重症人感染 H7N9禽流感合并 ARDS 患者氧合的临床观察. 中国急救医学, 2016, 36(1): 67-69.
5. 黄佳, 袁琳, 陈超. 新生儿无创高频振荡通气的研究进展. 中国当代儿科杂志, 2017, 19(5): 607-611.
6. Fischer H S, Bohlin K, Buehrer C A, et al. Nasal high-frequency oscillation ventilation in neonates: a survey in five European countries. Eur J Pediatr, 2015, 174(4): 465-471.
7. 崔彦芹, 陈欣欣, 李凤香, 等. 高频振荡通气治疗小儿先天性心脏病术后严重肺出血的有效性及安全性. 中华胸心血管外科杂志, 2014, 30(1): 17-20.
8. Pillow J J. High-frequency oscillatory ventilation: mechanisms of gas exchange and lung mechanics. Crit Care Med, 2005, 33(3 Suppl): S135-S141.
9. 封成芳. 高频震荡通气治疗新生儿呼吸窘迫综合征的机制及应用进展. 齐齐哈尔医学院学报, 2016, 37(3): 379-381.
10. Otis A B, Mckerrow C B, Bartlett R A, et al. Mechanical factors in distribution of pulmonary ventilation. J Appl Physiol, 1956, 8(4): 427-443.
11. Isabey D, Harf A, Chang H K. Alveolar ventilation during high-frequency oscillation: core dead space concept. Journal of Applied Physiology Respiratory Environmental & Exercise Physiology, 1984, 56(3): 700-907.
12. Lehr J L, Butler J P, Westerman P A, et al. Photographic measurement of pleural surface motion during lung oscillation. J Appl Physiol, 1985, 59(2): 623-633.
13. Lee W J, Kawahashi M, Hirahara H. Experimental analysis of pendelluft flow generated by HFOV in a human airway model. Physiol Meas, 2006, 27(8): 661-674.
14. Greenblatt E E, Butler J P, Venegas J G. Pendelluft in the bronchial tree. J Appl Physiol, 2014, 117(9): 979-988.
15. Yuan Yueyang, Sun J G, Wang Baicun, et al. A noninvasive high frequency oscillation ventilator: Achieved by utilizing a blower and a valve. Review of Scientific Instruments, 2016, 87(2): 38-45.
16. Diong B, Nazeran H, Nava P, et al. Modeling human respiratory impedance. IEEE Engineering in Medicine Biology Magazine, 2007, 26(1): 48-55.
17. 高雨仁, 刘祯唐, 孙凤喈. 国人气管-支气管-肺段支气管长度, 直径和分支角度的研究(一). 山西医药杂志, 1981, 10(2): 20-24.
18. 朱香亭, 胡小丽. 国人气管、支气管、肺段支气管长度、矢径、横径、直径的测量及典型. 解剖学报, 1989, 20(4): 342-349.
19. West J B. Respiratory Physiology: the essentials. 9th edition, Lippincott Williams & Wilkins, 2012: 1-23.
20. Martin Rozanek, Karel Roubik. Modeling of the respiratory system in Maltab. (2014-05-28). https://www.researchgate.net/publication/237571338.
21. Jongh de F H C. Ventilation modelling of the human lung. Handbook of Developmental Neurotoxicology, 1995: 439-450.
22. Kacmarek R M, Dimas S, Mack Craig W. 袁月华, 郭丰(译). 呼吸治疗学精要. 第4版. 北京: 人民军医出版社, 2015: 66-75.
23. Andrianopoulos V, Vanfleteren L E, Jarosch I, et al. Transcutaneous carbon-dioxide partial pressure trends during six-minute walk test in patients with very severe COPD. Respir Physiol Neurobiol, 2016, 233: 52-59.

Journal of Biomedical Engineering

Investigating the mechanism of the high frequency ventilation for the oscillation airflow between left and right lungs

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