Zobel G, Dacar D, Rödl S
Department of Pediatrics and Cardiac Surgery, University of Graz, Austria.
Crit Care Med. 1994 Oct;22(10):1624-30.
To determine the hemodynamic effects of four different modes of mechanical ventilation in an animal model of acute cardiac and pulmonary failure.
Prospective, randomized, crossover design.
University research laboratory.
Twelve piglets weighing 10 to 16 kg.
The experimental protocol consisted of three stable 30-min periods: when ventricular and pulmonary functions were normal (control), after the induction of acute cardiac failure by the administration of a beta-adrenergic receptor blocker, and after pulmonary failure induced by repeated lung lavage. Modes of mechanical ventilation included controlled mechanical ventilation, high-frequency oscillation, synchronized high-frequency jet ventilation, and external negative pressure oscillation combined with pressure support ventilation. Each mode of respiratory support was randomly and sequentially applied to each animal with the assessment of cardiopulmonary function at the end of each period.
Continuous monitoring included electrocardiogram, right atrial, left ventricular end-diastolic, pulmonary arterial, intrathoracic aortic, arterial, esophageal, and transpulmonary pressures and arterial and mixed venous oxygen saturation measurements. In addition, cardiac output using the thermodilution technique was measured intermittently. Whereas in the control period cardiac index was significantly (p < .05) higher during synchronized high-frequency jet ventilation (193 +/- 19.3 mL/kg/min) than during controlled mechanical ventilation (151 +/- 12.1 mL/kg/min) and high-frequency oscillation (151 +/- 18.1 mL/kg/min), there was no significant hemodynamic difference between the four modes of mechanical ventilation in the cardiac and pulmonary failure periods. In the pulmonary failure period, transpulmonary pressure was significantly higher during high-frequency oscillation (7.1 +/- 1.6 mm Hg) than during controlled mechanical ventilation (5.6 +/- 0.6 mm Hg), high-frequency ventilation (4.1 +/- 0.4 mm Hg), and external negative pressure oscillation combined with pressure support ventilation (5.3 +/- 0.5 mm Hg).
Synchronized high-frequency ventilation improves cardiac performance in control conditions. No hemodynamic difference is present between the four modes of mechanical ventilation in the cardiac and pulmonary failure periods. External negative pressure oscillation combined with pressure support ventilation has moderate hemodynamic advantages over controlled mechanical ventilation and high-frequency oscillation in different clinical settings, but it also results in a deterioration of pulmonary gas exchange during the pulmonary failure period.
在急性心功能和肺功能衰竭动物模型中确定四种不同机械通气模式的血流动力学效应。
前瞻性、随机、交叉设计。
大学研究实验室。
12头体重10至16千克的仔猪。
实验方案包括三个稳定的30分钟时段:心室和肺功能正常时(对照)、给予β-肾上腺素能受体阻滞剂诱发急性心力衰竭后、以及反复肺灌洗诱发肺功能衰竭后。机械通气模式包括控制机械通气、高频振荡、同步高频喷射通气、以及外部负压振荡联合压力支持通气。每种呼吸支持模式随机且依次应用于每只动物,并在每个时段结束时评估心肺功能。
连续监测包括心电图、右心房、左心室舒张末期、肺动脉、胸主动脉、动脉、食管及跨肺压测量,以及动脉和混合静脉血氧饱和度测量。此外,间歇测量采用热稀释技术的心输出量。在对照时段,同步高频喷射通气期间的心指数(193±19.3毫升/千克/分钟)显著高于控制机械通气(151±12.1毫升/千克/分钟)和高频振荡(151±18.1毫升/千克/分钟)(p<0.05),但在心功能和肺功能衰竭时段,四种机械通气模式之间无显著血流动力学差异。在肺功能衰竭时段,高频振荡期间的跨肺压(7.1±1.6毫米汞柱)显著高于控制机械通气(5.6±0.6毫米汞柱)、高频通气(4.1±0.4毫米汞柱)和外部负压振荡联合压力支持通气(5.3±0.5毫米汞柱)。
同步高频通气在对照条件下可改善心脏功能。在心功能和肺功能衰竭时段,四种机械通气模式之间无血流动力学差异。在不同临床环境中,外部负压振荡联合压力支持通气相对于控制机械通气和高频振荡具有适度的血流动力学优势,但在肺功能衰竭时段也会导致肺气体交换恶化。
