Comparison of the value of bedside lung ultrasound and lung stretch index in guiding optimal positive end-expiratory pressure during lung recruitment in patients with acute respiratory distress syndrome_Chinese Journal of Respiratory and Critical Care Medicine

Authors：

 LIU Xiaojing , WANG Wentao , LI Jiachen , ZHENG Naisheng

Department of Critical Care Medicine, Second Affiliated Hospital of Zhengzhou University, Zhengzhou, Henan 450003, P. R. China;

Corresponding?author：

LIU Xiaojing, Email: liuxiaojingzzs@163.com

Keywords：

Acute respiratory distress syndrome; lung recruitment; positive end-expiratory pressure; bedside lung ultrasound; pulmonary stretch index

DOI：

10.7507/1671-6205.202401038

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Objective To investigate the guiding value of bedside lung ultrasound and lung stretch index for optimal positive end-expiratory pressure (PEEP) in lung recruitment of patients with acute respiratory distress syndrome (ARDS). Methods From February 2020 to October 2023, 90 patients with ARDS requiring invasive mechanical ventilation were selected from the Department of Critical Care Medicine, the Second Affiliated Hospital of Zhengzhou University. According to the setting method of PEEP after lung recruitment, they were randomly divided into an ultrasound group (45 cases) and a stretch group (45 cases). Both groups were treated with PEEP incremental method for lung recruitment, and the ultrasound group was treated with bedside ultrasound-guided method to set PEEP after lung recruitment. PEEP was set by lung stretch index method in the stretch group. The dynamic changes of oxygenation index (PaO₂/FiO₂), dynamic compliance (Cdyn), mean airway pressure and peak airway pressure were monitored before lung recruitment and 15 min, 1 h, 6 h and 24 h after lung recruitment. Heart rate, mean arterial pressure and central venous pressure were monitored before and 24 h after lung recruitment in the two groups. The optimal PEEP value and the corresponding volume at the end of recruitment were explored. The mechanical ventilation time, ICU hospitalization time, incidence of barotrauma, incidence of extrapulmonary organ failure, and 28-day mortality were recorded as well. Results After lung recruitment, the oxygenation index, Cdyn, mean airway pressure, and peak airway pressure in the ultrasound group were higher than those in the stretch group at 15 min, 1 h, 6 h, and 24 h after recruitment (all P<0.05). There was no significant difference in heart rate, mean arterial pressure or central venous pressure between the two groups at 24 h after lung recruitment (all P>0.05). After lung recruitment, the optimal PEEP value and the corresponding volume at the end of recruitment in the ultrasound group were higher than those in the distraction group (both P<0.05). The mechanical ventilation time and ICU stay in the ultrasound group were shorter than those in the stretch group (both P<0.05). There was no significant difference in the incidence of barotrauma, extrapulmonary organ failure rate or 28-day mortality between the two groups (all P>0.05). Conclusions Both bedside lung ultrasound-guided PEEP and lung stretch index-guided PEEP can improve oxygenation and respiratory compliance, and have no adverse effects on hemodynamics. Bedside lung ultrasound-guided PEEP can make the alveoli fully expand, which is more conducive to improving patients’ oxygenation and respiratory compliance, and the guiding value is higher than the lung stretch index.

Citation： LIU Xiaojing, WANG Wentao, LI Jiachen, ZHENG Naisheng. Comparison of the value of bedside lung ultrasound and lung stretch index in guiding optimal positive end-expiratory pressure during lung recruitment in patients with acute respiratory distress syndrome. Chinese Journal of Respiratory and Critical Care Medicine, 2024, 23(7): 470-477. doi: 10.7507/1671-6205.202401038 Copy

1.	Joseph A, Petit M, Vieillard-Baron A. Hemodynamic effects of positive end-expiratory pressure. Curr Opin Crit Care, 2024, 30(1): 10-19.
2.	Fossali T, Pavlovsky B, Ottolina D, et al. Effects of Prone position on lung recruitment and ventilation-perfusion matching in patients with COVID-19 acute respiratory distress syndrome: a combined CT scan/electrical impedance tomography study. Crit Care Med, 2022, 50(5): 723-732.
3.	盧巖, 涂學平, 馬超, 等. 床旁超聲指導下肺保護通氣對ARDS患者氧合指數的影響研究. 臨床肺科雜志, 2021, 26(6): 896-900.
4.	Nakayama R, Bunya N, Katayama S, et al. Correlation between the hysteresis of the pressure-volume curve and the recruitment-to-inflation ratio in patients with coronavirus disease 2019. Ann Intensive Care, 2022, 12(1): 106.
5.	The ARDS Definition Task Force, Ranieri VM, Rubenfeld GD, et al. Acute respiratory distress syndrome: the Berlin Definition. JAMA, 2012, 307(23): 2526-2533.
6.	羅前程, 劉瑞, 曲凱麗, 等. 即時肺部超聲結合壓力-容積曲線設定PEEP對ARDS肺復張的臨床評價. 寧夏醫科大學學報, 2021, 43(1): 22-28.
7.	劉天亞, 喬惠婷, 許麗嬙, 等. 基于肺的靜態壓強—容積曲線估計肺復張特性的研究. 生物醫學工程學雜志, 2021, 38(2): 326-332.
8.	陳佳祥, 史曉莉, 梁昌盛, 等. 肺動態順應性導向呼氣末正壓滴定法用于肺保護性通氣策略的研究進展. 臨床麻醉學雜志, 2023, 39(9): 987-990.
9.	Grasselli G, Calfee CS, Camporota L, et al. European Society of Intensive Care Medicine Taskforce on ARDS. ESICM guidelines on acute respiratory distress syndrome: definition, phenotyping and respiratory support strategies. Intensive Care Med, 2023, 49(7): 727-759.
10.	Taenaka H, Yoshida T, Hashimoto H, et al. Personalized ventilatory strategy based on lung recruitablity in COVID-19-associated acute respiratory distress syndrome: a prospective clinical study. Crit Care, 2023, 27(1): 152.
11.	Cammarota G, Bruni A, Morettini G, et al. Lung ultrasound to evaluate aeration changes in response to recruitment maneuver and prone positioning in intubated patients with COVID-19 pneumonia: preliminary study. Ultrasound J, 2023, 15(1): 3.
12.	Kowalczyk D, Turkowiak M, Piotrowski WJ, et al. Ultrasound on the frontlines: empowering paramedics with lung ultrasound for dyspnea diagnosis in adults-a pilot study. Diagnostics(Basel), 2023, 13(22): 3412.
13.	Capasso L, Pacella D, Migliaro F, et al. Can lung ultrasound score accurately predict surfactant replacement? A systematic review and meta-analysis of diagnostic test studies. Pediatr Pulmonol, 2023, 58(5): 1427-1437.
14.	王旭東, 孫延虎, 劉雅文, 等. 床旁超聲對ARDS患者肺復張后的最佳PEEP設置探討. 中國衛生標準管理, 2023, 14(22): 108-111.
15.	Bouhemad B, Brisson H, Le-Guen M, et al. Bedside ultrasound assessment of positive end-expiratory pressure-induced lung recruitment. Am J Respir Crit Care Med, 2011, 183(3): 341-347.
16.	丁媛, 倪佳園, 徐榮鵬, 等. 肺部超聲在重癥患者的應用及研究進展. 中國呼吸與危重監護雜志, 2021, 20(7): 522-527.
17.	李根, 榮令, 趙美景, 等. 床旁超聲導向的最佳呼氣末正壓對急性呼吸窘迫綜合征患者氧合指數及血流動力學的影響研究. 中國全科醫學, 2019, 22(5): 616-620.
18.	程江麗, 楊杰, 康焰. 急性呼吸窘迫綜合征機械通氣患者呼氣末正壓設定的方法. 中國呼吸與危重監護雜志, 2019, 18(6): 591-594.
19.	Roldán R, Barriga F, Villamonte R, et al. The use of the oxygenation stretch index to predict outcomes in mechanically ventilated patients with COVID-19 ARDS. Respir Care, 2023, 68(12): 1683-1692.
20.	Formenti P, Graf J, Santos A, et al. Non-pulmonary factors strongly influence the stress index. Intensive Care Med, 2011, 37(4): 594-600.
21.	Plataki M, Hubmayr RD. Should mechanical ventilation be guided by esophageal pressure measurements? Curr Opin Crit Care, 2011, 17(3): 275-280.
22.	韓宇, 陳軍, 范鳳尾, 等. 跨肺壓導向滴定呼氣末正壓治療ARDS的療效及安全性的Meta分析. 現代臨床醫學, 2023, 49(1): 47-51.
23.	狄萍萍, 王晉平. 跨肺壓滴定個體化呼氣末正壓對行腹腔鏡結直腸癌根治術患者肺功能的影響. 新鄉醫學院學報, 2023, 40(8): 779-783,790.
24.	Mongodi S, De Luca D, Colombo A, et al. Quantitative lung ultrasound: technical aspects and clinical applications. Anesthesiology, 2021, 134(6): 949-965.

1. Joseph A, Petit M, Vieillard-Baron A. Hemodynamic effects of positive end-expiratory pressure. Curr Opin Crit Care, 2024, 30(1): 10-19.
2. Fossali T, Pavlovsky B, Ottolina D, et al. Effects of Prone position on lung recruitment and ventilation-perfusion matching in patients with COVID-19 acute respiratory distress syndrome: a combined CT scan/electrical impedance tomography study. Crit Care Med, 2022, 50(5): 723-732.
3. 盧巖, 涂學平, 馬超, 等. 床旁超聲指導下肺保護通氣對ARDS患者氧合指數的影響研究. 臨床肺科雜志, 2021, 26(6): 896-900.
4. Nakayama R, Bunya N, Katayama S, et al. Correlation between the hysteresis of the pressure-volume curve and the recruitment-to-inflation ratio in patients with coronavirus disease 2019. Ann Intensive Care, 2022, 12(1): 106.
5. The ARDS Definition Task Force, Ranieri VM, Rubenfeld GD, et al. Acute respiratory distress syndrome: the Berlin Definition. JAMA, 2012, 307(23): 2526-2533.
6. 羅前程, 劉瑞, 曲凱麗, 等. 即時肺部超聲結合壓力-容積曲線設定PEEP對ARDS肺復張的臨床評價. 寧夏醫科大學學報, 2021, 43(1): 22-28.
7. 劉天亞, 喬惠婷, 許麗嬙, 等. 基于肺的靜態壓強—容積曲線估計肺復張特性的研究. 生物醫學工程學雜志, 2021, 38(2): 326-332.
8. 陳佳祥, 史曉莉, 梁昌盛, 等. 肺動態順應性導向呼氣末正壓滴定法用于肺保護性通氣策略的研究進展. 臨床麻醉學雜志, 2023, 39(9): 987-990.
9. Grasselli G, Calfee CS, Camporota L, et al. European Society of Intensive Care Medicine Taskforce on ARDS. ESICM guidelines on acute respiratory distress syndrome: definition, phenotyping and respiratory support strategies. Intensive Care Med, 2023, 49(7): 727-759.
10. Taenaka H, Yoshida T, Hashimoto H, et al. Personalized ventilatory strategy based on lung recruitablity in COVID-19-associated acute respiratory distress syndrome: a prospective clinical study. Crit Care, 2023, 27(1): 152.
11. Cammarota G, Bruni A, Morettini G, et al. Lung ultrasound to evaluate aeration changes in response to recruitment maneuver and prone positioning in intubated patients with COVID-19 pneumonia: preliminary study. Ultrasound J, 2023, 15(1): 3.
12. Kowalczyk D, Turkowiak M, Piotrowski WJ, et al. Ultrasound on the frontlines: empowering paramedics with lung ultrasound for dyspnea diagnosis in adults-a pilot study. Diagnostics(Basel), 2023, 13(22): 3412.
13. Capasso L, Pacella D, Migliaro F, et al. Can lung ultrasound score accurately predict surfactant replacement? A systematic review and meta-analysis of diagnostic test studies. Pediatr Pulmonol, 2023, 58(5): 1427-1437.
14. 王旭東, 孫延虎, 劉雅文, 等. 床旁超聲對ARDS患者肺復張后的最佳PEEP設置探討. 中國衛生標準管理, 2023, 14(22): 108-111.
15. Bouhemad B, Brisson H, Le-Guen M, et al. Bedside ultrasound assessment of positive end-expiratory pressure-induced lung recruitment. Am J Respir Crit Care Med, 2011, 183(3): 341-347.
16. 丁媛, 倪佳園, 徐榮鵬, 等. 肺部超聲在重癥患者的應用及研究進展. 中國呼吸與危重監護雜志, 2021, 20(7): 522-527.
17. 李根, 榮令, 趙美景, 等. 床旁超聲導向的最佳呼氣末正壓對急性呼吸窘迫綜合征患者氧合指數及血流動力學的影響研究. 中國全科醫學, 2019, 22(5): 616-620.
18. 程江麗, 楊杰, 康焰. 急性呼吸窘迫綜合征機械通氣患者呼氣末正壓設定的方法. 中國呼吸與危重監護雜志, 2019, 18(6): 591-594.
19. Roldán R, Barriga F, Villamonte R, et al. The use of the oxygenation stretch index to predict outcomes in mechanically ventilated patients with COVID-19 ARDS. Respir Care, 2023, 68(12): 1683-1692.
20. Formenti P, Graf J, Santos A, et al. Non-pulmonary factors strongly influence the stress index. Intensive Care Med, 2011, 37(4): 594-600.
21. Plataki M, Hubmayr RD. Should mechanical ventilation be guided by esophageal pressure measurements? Curr Opin Crit Care, 2011, 17(3): 275-280.
22. 韓宇, 陳軍, 范鳳尾, 等. 跨肺壓導向滴定呼氣末正壓治療ARDS的療效及安全性的Meta分析. 現代臨床醫學, 2023, 49(1): 47-51.
23. 狄萍萍, 王晉平. 跨肺壓滴定個體化呼氣末正壓對行腹腔鏡結直腸癌根治術患者肺功能的影響. 新鄉醫學院學報, 2023, 40(8): 779-783,790.
24. Mongodi S, De Luca D, Colombo A, et al. Quantitative lung ultrasound: technical aspects and clinical applications. Anesthesiology, 2021, 134(6): 949-965.

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Comparison of the value of bedside lung ultrasound and lung stretch index in guiding optimal positive end-expiratory pressure during lung recruitment in patients with acute respiratory distress syndrome

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