Clingan Sean P, Reagor James A, Ollberding Nicholas J
Department of Cardiovascular Perfusion, Cincinnati Children's Hospital Medical Center, Cincinnati, Ohio.
Department of Pediatrics, University of Cincinnati College of Medicine, Cincinnati, Ohio; and.
J Extra Corpor Technol. 2020 Jun;52(2):112-117. doi: 10.1182/ject-2000004.
The optimal setting to achieve a suitable PaCO value of 35-45 mmHg upon initiating cardiopulmonary bypass (CPB) in the pediatric population is undefined in the literature. Sweep gas is set upon initiating and modified throughout CPB to reduce potential complications related to compensatory metabolic acidosis or metabolic alkalosis and associated cerebral blood flow fluctuations. This study retrospectively examined 1,077 CPB cases for which PaCO values were no less than 30 mmHg and no greater than 50 mmHg on the pre-CPB blood gas result. Through an observation of the results, we attempted to determine the optimal sweep gas setting upon initiating CPB to obtain a physiologic PaCO value of 35-45 mmHg. The probability of achieving an optimal PaCO value was modeled as a function of the average sweep gas to blood flow ratio during the period before the first blood gas on CPB. The median sweep gas to blood flow ratio (V/Q) was .64 (.51; .76), with a median first PaCO value on CPB of 42 mmHg (38.8; 45). A .6 V/Q had an odds ratio (OR) of 1.57 of obtaining a PaCO value between 35 and 45 mmHg on the first CPB blood gas when compared with a .4 V/Q (Figure 1Figure 1.Bivariate associations between PaCO and the V/Q ratio. (A) Spike histogram with loess curve showing the proportion of patients with a first PaCO value on CPB between 35 and 45 mmHg according to the V/Q ratio. (B) Scatterplot and loess curve (gray line) for PaCO on CPB according to the V/Q ratio. Dashed lines indicate the target range of 35-45 mmHg. (C) Model-based estimate of the predicted probability and 95% CI for PaCO on CPB between 35 and 45 mmHg according to the V/Q ratio obtained from logistic regression. (D) Model-based estimate of the predicted PaCO on CPB according to the V/Q ratio obtained from ordinal regression. Prop, proportion.). A .9 V/Q had a 1.76 OR when compared with a .4 and a 1.12 OR when compared with .6. Using a .6 V/Q ratio achieved a PaCO value within normal physiologic limits with no significant advantage to a higher V/Q ratio overall. However, younger or smaller patients required a higher V/Q to achieve similar probabilities of being within limits and similar PaCO values when compared with the older or larger patients.
在儿科人群中,启动体外循环(CPB)时达到35 - 45 mmHg适宜动脉血二氧化碳分压(PaCO)值的最佳设置在文献中尚无定论。在启动CPB时设置并在整个CPB过程中调整扫气,以减少与代偿性代谢性酸中毒或代谢性碱中毒及相关脑血流波动有关的潜在并发症。本研究回顾性分析了1077例CPB病例,这些病例在CPB前血气结果中PaCO值不低于30 mmHg且不高于50 mmHg。通过观察结果,我们试图确定启动CPB时获得35 - 45 mmHg生理PaCO值的最佳扫气设置。将达到最佳PaCO值的概率建模为CPB首次血气检查前期间平均扫气与血流比的函数。扫气与血流比(V/Q)的中位数为0.64(0.51;0.76),CPB时首次PaCO值的中位数为42 mmHg(38.8;45)。与0.4的V/Q相比,0.6的V/Q在CPB首次血气检查时获得35至45 mmHg之间PaCO值的优势比(OR)为1.57(图1图1.PaCO与V/Q比之间的双变量关联。(A)带有局部加权回归曲线的尖峰直方图,显示根据V/Q比CPB时首次PaCO值在35至45 mmHg之间的患者比例。(B)根据V/Q比绘制的CPB时PaCO的散点图和局部加权回归曲线(灰色线)。虚线表示35 - 45 mmHg的目标范围。(C)根据逻辑回归获得的V/Q比,基于模型估计的CPB时PaCO在35至45 mmHg之间的预测概率和95%置信区间。(D)根据有序回归获得的V/Q比,基于模型估计的CPB时预测PaCO。Prop,比例。)。与0.4的V/Q相比,0.9的V/Q的OR为1.76,与0.6的V/Q相比为1.12。使用0.6的V/Q比可使PaCO值达到正常生理范围内,总体上与更高的V/Q比相比无显著优势。然而,与年龄较大或体型较大的患者相比,年龄较小或体型较小的患者需要更高的V/Q才能达到在范围内的相似概率和相似的PaCO值。
