用于预测液体反应性的伴有呼吸机诱导变化的脉搏波传播时间

Pulse-wave transit time with ventilator-induced variation for the prediction of fluid responsiveness.

作者信息

Yamashita Koichi

机构信息

Division of Critical Care Center Kochi Red Cross Hospital Kochi Japan.

出版信息

Acute Med Surg. 2020 Jan 27;7(1). doi: 10.1002/ams2.484. eCollection 2020 Jan-Dec.

DOI:10.1002/ams2.484

PMID:32002187

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC6985177/

Abstract

AIM

Although pulse pressure variation is a good predictor of fluid responsiveness, its measurement is invasive. Therefore, a technically simple, non-invasive method is needed for evaluating circulatory status to prevent fluid loading and optimize hemodynamic status. We focused in the pulse-wave transit time (PWTT) defined as the time interval between electrocardiogram R wave to plethysmograph upstroke, which has been recently introduced to non-invasively assess cardiovascular response. In the present study, we evaluated the efficacy of pulse-wave transit time (PWTT) with ventilator-induced variation (PWTTV) in predicting fluid responsiveness.

METHODS

We evaluated six domestic pigs weighing 46.0 ± 3.5 kg. After anesthesia induction, electrocardiogram, femoral arterial blood pressure, plethysmograph on the tail, and carotid artery blood flow were monitored and hemorrhage was induced by withdrawing 20 mL/kg blood over 20 min; 5 mL/kg blood volume was then autotransfused over 10 min. Then PWTTV and pulse pressure variation were measured at tidal volumes of 6 and 12 mL/kg.

RESULTS

Area under the receiver operating curve values for the prediction of a >10% change in carotid artery blood flow were 0.979 for pulse pressure variation and 0.993 for PWTTV at a tidal volume of 6 mL/kg and 0.979 and 0.979, respectively, at a tidal volume of 12 mL/kg (all < 0.0001).

CONCLUSIONS

Measured non-invasively, PWTTV showed similar utility to pulse pressure variation in predicting >10% changes in carotid artery blood flow induced by autotransfusion.

摘要

目的

尽管脉压变异是液体反应性的良好预测指标，但其测量具有侵入性。因此，需要一种技术上简单的非侵入性方法来评估循环状态，以防止液体负荷过重并优化血流动力学状态。我们关注的是脉搏波传播时间（PWTT），它被定义为心电图R波到体积描记图上升支之间的时间间隔，最近已被用于非侵入性评估心血管反应。在本研究中，我们评估了带有呼吸机诱导变异的脉搏波传播时间（PWTTV）在预测液体反应性方面的有效性。

方法

我们评估了6头体重为46.0±3.5千克的家猪。诱导麻醉后，监测心电图、股动脉血压、尾部体积描记图和颈动脉血流，并在20分钟内抽取20毫升/千克血液诱导出血；然后在10分钟内自体回输5毫升/千克血容量。然后在潮气量为6和12毫升/千克时测量PWTTV和脉压变异。

结果

在潮气量为6毫升/千克时，预测颈动脉血流变化>10%的受试者工作特征曲线下面积值，脉压变异为0.979，PWTTV为0.993；在潮气量为12毫升/千克时，分别为0.979和0.979（均<0.0001）。

结论

通过非侵入性测量，PWTTV在预测自体回输引起的颈动脉血流>10%变化方面显示出与脉压变异相似的效用。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/4712/6985177/c4339f2bd29d/AMS2-7-0-g001.jpg

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用于预测液体反应性的伴有呼吸机诱导变化的脉搏波传播时间

Pulse-wave transit time with ventilator-induced variation for the prediction of fluid responsiveness.

作者信息

机构信息

出版信息

AIM

METHODS

RESULTS

CONCLUSIONS

目的

方法

结果

结论

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