He Xinrong, Su Fuhong, Xie Keliang, Taccone Fabio Silvio, Donadello Katia, Vincent Jean-Louis
1Department of Intensive Care, Erasme University Hospital, Université Libre de Bruxelles, Brussels, Belgium. 2Department of Intensive Care, Sun Yat-sen University Cancer Center, Guangzhou, China. 3Anesthesia and Intensive Care B, Department of Surgery, Dentistry, Pediatrics and Gynecology, University of Verona, AOUI-University Hospital Integrated Trust of Verona, Verona, Italy.
Crit Care Med. 2017 Oct;45(10):e1060-e1067. doi: 10.1097/CCM.0000000000002524.
Optimizing oxygen delivery is an important part of the hemodynamic resuscitation of septic shock, but concerns have been raised over the potentially deleterious effects of hyperoxia. We evaluated the impact of hyperoxia on hemodynamics, the microcirculation, and cerebral and renal metabolism in an ovine model of septic shock.
Randomized animal study.
University hospital animal research laboratory.
Fourteen adult female sheep.
After induction of fecal peritonitis, sheep were randomized to ventilation with an FIO2 of 100% (n = 7) or an FIO2 adjusted to maintain PaO2 between 90 and 120 mm Hg (n = 7, control). All animals were fluid resuscitated and observed until death.
In addition to hemodynamic measurements, we assessed the sublingual microcirculation, renal and cerebral microdialysis and microvascular perfusion, and brain tissue oxygen pressure. Hyperoxic animals initially had a higher mean arterial pressure than control animals. After onset of shock, hyperoxia blunted the decrease in stroke volume index observed in the control group. Hyperoxia was associated with a higher sublingual microcirculatory flow over time, with higher cerebral perfusion and brain tissue oxygen pressure and with a lower cerebral lactate-to-pyruvate ratio than in control animals. Hyperoxia was also associated with preserved renal microvascular perfusion, lower renal lactate-to-pyruvate ratio, and higher PaO2/FIO2 ratio.
In this acute peritonitis model, hyperoxia induced during resuscitation provided better hemodynamics and peripheral microvascular flow and better preserved cerebral metabolism, renal function, and gas exchange. These observations are reassuring with recent concerns about excessive oxygen therapy in acute diseases.
优化氧输送是感染性休克血流动力学复苏的重要组成部分,但高氧血症的潜在有害影响引发了人们的关注。我们在绵羊感染性休克模型中评估了高氧血症对血流动力学、微循环以及脑和肾代谢的影响。
随机动物研究。
大学医院动物研究实验室。
14只成年雌性绵羊。
诱发粪性腹膜炎后,将绵羊随机分为两组,一组给予100%的吸入氧分数(FIO2)通气(n = 7),另一组将FIO2调整至维持动脉血氧分压(PaO2)在90至120 mmHg之间(n = 7,对照组)。所有动物均进行液体复苏并观察直至死亡。
除血流动力学测量外,我们还评估了舌下微循环、肾和脑微透析及微血管灌注以及脑组织氧分压。高氧组动物最初的平均动脉压高于对照组动物。休克发生后,高氧血症减弱了对照组观察到的每搏量指数下降。随着时间推移,高氧血症与较高的舌下微循环血流量、较高的脑灌注和脑组织氧分压以及较低的脑乳酸与丙酮酸比值相关,高于对照组动物。高氧血症还与肾微血管灌注的维持、较低的肾乳酸与丙酮酸比值以及较高的PaO2/FIO2比值相关。
在这个急性腹膜炎模型中,复苏期间诱发的高氧血症提供了更好的血流动力学和外周微血管血流,并更好地维持了脑代谢、肾功能和气体交换。这些观察结果对于近期对急性疾病中过度氧疗的担忧而言是令人安心的。
