A non-invasive method to monitor respiratory muscle effort during mechanical ventilation.

IF 2 3区医学 Q2 ANESTHESIOLOGY

Journal of Clinical Monitoring and Computing Pub Date : 2024-10-01 Epub Date: 2024-05-11 DOI:10.1007/s10877-024-01164-z

Guillermo Gutierrez

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引用次数: 0

Abstract

Purpose: This study introduces a method to non-invasively and automatically quantify respiratory muscle effort (P_mus) during mechanical ventilation (MV). The methodology hinges on numerically solving the respiratory system's equation of motion, utilizing measurements of airway pressure (P_aw) and airflow (F_aw). To evaluate the technique's effectiveness, P_mus was correlated with expected physiological responses. In volume-control (VC) mode, where tidal volume (V_T) is pre-determined, P_mus is expected to be linked to P_aw fluctuations. In contrast, during pressure-control (PC) mode, where P_aw is held constant, P_mus should correlate with V_T variations.

Methods: The study utilized data from 250 patients on invasive MV. The data included detailed recordings of P_aw and F_aw, sampled at 31.25 Hz and saved in 131.1-second epochs, each covering 34 to 41 breaths. The algorithm identified 51,268 epochs containing breaths on either VC or PC mode exclusively. In these epochs, P_mus and its pressure-time product (P_musPTP) were computed and correlated with P_aw's pressure-time product (P_awPTP) and V_T, respectively.

Results: There was a strong correlation of P_musPTP with P_awPTP in VC mode (R² = 0.91 [0.76, 0.96]; n = 17,648 epochs) and with V_T in PC mode (R² = 0.88 [0.74, 0.94]; n = 33,620 epochs), confirming the hypothesis. As expected, negligible correlations were observed between P_musPTP and V_T in VC mode (R² = 0.03) and between P_musPTP and P_awPTP in PC mode (R² = 0.06).

Conclusion: The study supports the feasibility of assessing respiratory effort during MV non-invasively through airway signal analysis. Further research is warranted to validate this method and investigate its clinical applications.

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在机械通气过程中监测呼吸肌用力的无创方法。

目的：本研究介绍了一种无创自动量化机械通气（MV）过程中呼吸肌用力（Pmus）的方法。该方法利用气道压力（Paw）和气流（Faw）的测量值，对呼吸系统的运动方程进行数值求解。为了评估该技术的有效性，Pmus 与预期的生理反应相关联。在潮气量（VT）预先确定的容量控制（VC）模式下，Pmus 预计与 Paw 波动相关。相反，在压力控制（PC）模式下，Paw 保持不变，Pmus 应与 VT 变化相关：研究利用了 250 名使用有创 MV 的患者的数据。数据包括 Paw 和 Faw 的详细记录，采样频率为 31.25 Hz，以 131.1 秒的时间序列保存，每个序列涵盖 34 到 41 次呼吸。该算法识别出了 51,268 个完全包含 VC 或 PC 模式呼吸的时间段。在这些历时中，计算了 Pmus 及其压力-时间乘积 (PmusPTP)，并分别与 Paw 的压力-时间乘积 (PawPTP) 和 VT 相关：在 VC 模式下，PmusPTP 与 PawPTP 有很强的相关性（R² = 0.91 [0.76, 0.96]；n = 17,648 个时程），在 PC 模式下，PmusPTP 与 VT 有很强的相关性（R² = 0.88 [0.74, 0.94]；n = 33,620 个时程），证实了假设。正如所料，在 VC 模式下，PmusPTP 与 VT 之间的相关性可忽略不计（R² = 0.03），在 PC 模式下，PmusPTP 与 PawPTP 之间的相关性可忽略不计（R² = 0.06）：该研究支持通过气道信号分析无创评估 MV 期间呼吸努力的可行性。该研究支持通过气道信号分析无创评估 MV 期间呼吸努力的可行性，有必要进一步研究验证该方法并调查其临床应用。

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

Journal of Clinical Monitoring and Computing ANESTHESIOLOGY-

CiteScore

4.30

自引率

13.60%

发文量

144

审稿时长

6-12 weeks

期刊介绍： The Journal of Clinical Monitoring and Computing is a clinical journal publishing papers related to technology in the fields of anaesthesia, intensive care medicine, emergency medicine, and peri-operative medicine. The journal has links with numerous specialist societies, including editorial board representatives from the European Society for Computing and Technology in Anaesthesia and Intensive Care (ESCTAIC), the Society for Technology in Anesthesia (STA), the Society for Complex Acute Illness (SCAI) and the NAVAt (NAVigating towards your Anaestheisa Targets) group. The journal publishes original papers, narrative and systematic reviews, technological notes, letters to the editor, editorial or commentary papers, and policy statements or guidelines from national or international societies. The journal encourages debate on published papers and technology, including letters commenting on previous publications or technological concerns. The journal occasionally publishes special issues with technological or clinical themes, or reports and abstracts from scientificmeetings. Special issues proposals should be sent to the Editor-in-Chief. Specific details of types of papers, and the clinical and technological content of papers considered within scope can be found in instructions for authors.