Cheifetz I M, Craig D M, Kern F H, Black D R, Hillman N D, Greeley W J, Ungerleider R M, Smith P K, Meliones J N
Department of Pediatrics, Duke Children's Hospital, Duke University Medical Center, Durham, NC 27710, USA.
Crit Care Med. 1996 Sep;24(9):1554-61. doi: 10.1097/00003246-199609000-00021.
To test the hypothesis that in a swine model of acute respiratory distress syndrome (ARDS) with permissive hypercapnia, inhaled nitric oxide would improve transpulmonary vascular mechanics and right ventricular workload while not changing intrinsic right ventricular contractility.
Prospective, randomized, controlled laboratory trial.
University research laboratory.
Eleven swine (30 to 46 kg).
The swine were anesthetized, intubated, and paralyzed. After median sternotomy, pressure transducers were placed in the right ventricle, pulmonary artery, and left atrium. An ultrasonic flow probe was placed around the pulmonary artery. Ultrasonic dimension transducers were sutured onto the heart at the base, apex, left ventricle (anterior, posterior, free wall), and right ventricle (free wall). An additional transducer was placed in the interventricular septum. A surfactant depletion model of ARDS was created by saline lung lavage. Nitric oxide was administered at 2, 4, and 6 parts per million (ppm), in a random order, under the condition of permissive hypercapnia (Paco2 55 to 75 torr [7.3 to 10.0 kPa]).
We evaluated the pulmonary vascular and right ventricular effects of permissive hypercapnia, with and without inhaled nitric oxide, by measuring variables of transpulmonary vascular mechanics and right ventricular function. These variables included mean pulmonary arterial pressure, right ventricular total power, right ventricular stroke work, transpulmonary vascular efficiency, and right ventricular intrinsic contractility. Data were obtained after lung injury under the following conditions: a) normocapnia (Paco2 35 to 45 torr [4.7 to 6.0 kPa]) and nitric oxide at 0 ppm; b) hypercapnia and nitric oxide at 0 ppm; c) hypercapnia and nitric oxide at 2, 4, and 6 ppm; and d) repeat measurements with hypercapnia and nitric oxide at 0 ppm. In ARDS with permissive hypercapnia, inhaled nitric oxide therapy (2 to 6 ppm) improved transpulmonary vascular mechanics and right ventricular workload by lowering pulmonary arterial pressure (29.6 +/- 1.3 vs. 24.6 +/- 1.0 mm Hg, p = .0001), increasing transpulmonary vascular efficiency (13.9 +/- 0.5 vs. 16.1 +/- 0.7 L/W-min, p = .0001), decreasing right ventricular total power (142 +/- 9 vs. 115 +/- 9 mW, p = .001), and decreasing right ventricular stroke work (653 +/- 37 vs. 525 +/- 32 ergs x 10(3), p = .001). Inhaled nitric oxide did not change right ventricular contractility, as measured by preload-recruitable stroke work.
Inhaled nitric oxide ameliorated any negative effects of hypoxic and hypercapnic pulmonary vasoconstriction. The beneficial effects of inhaled nitric oxide are related to alterations in right ventricular afterload and not intrinsic right ventricular contractility. The improved cardiopulmonary effects of inhaled nitric oxide with permissive hypercapnia potentially expand the use of nitric oxide in ARDS and other conditions in which this strategy is employed.
验证如下假说:在允许性高碳酸血症的急性呼吸窘迫综合征(ARDS)猪模型中,吸入一氧化氮可改善跨肺血管力学和右心室负荷,而不改变右心室固有收缩力。
前瞻性、随机、对照实验室试验。
大学研究实验室。
11头猪(30至46千克)。
猪麻醉、插管并使用肌肉松弛剂。经正中胸骨切开术后,将压力传感器分别置于右心室、肺动脉和左心房。在肺动脉周围放置超声流量探头。将超声尺寸传感器缝在心脏的基部、心尖、左心室(前壁、后壁、游离壁)和右心室(游离壁)。在室间隔放置另一个传感器。通过盐水肺灌洗建立ARDS的表面活性剂耗竭模型。在允许性高碳酸血症(动脉血二氧化碳分压55至75托[7.3至10.0千帕])条件下,以随机顺序给予2、4和6 ppm的一氧化氮。
通过测量跨肺血管力学和右心室功能变量,我们评估了允许性高碳酸血症(有无吸入一氧化氮)对肺血管和右心室的影响。这些变量包括平均肺动脉压、右心室总功率、右心室搏功、跨肺血管效率和右心室固有收缩力。在以下条件下肺损伤后获取数据:a)正常碳酸血症(动脉血二氧化碳分压35至45托[4.7至6.0千帕])且一氧化氮为0 ppm;b)高碳酸血症且一氧化氮为0 ppm;c)高碳酸血症且一氧化氮为2、4和6 ppm;d)重复测量高碳酸血症且一氧化氮为0 ppm的情况。在允许性高碳酸血症的ARDS中,吸入一氧化氮治疗(2至6 ppm)通过降低肺动脉压(29.6±1.3对24.6±1.0毫米汞柱,p = .0001)、提高跨肺血管效率(13.9±0.5对16.1±0.7升/瓦-分钟,p = .0001)、降低右心室总功率(142±9对115±9毫瓦,p = .001)和降低右心室搏功(653±37对525±32尔格×10³,p = .001),改善了跨肺血管力学和右心室负荷。吸入一氧化氮并未改变右心室收缩力,以预负荷可增加搏功衡量。
吸入一氧化氮改善了低氧和高碳酸血症性肺血管收缩的任何负面影响。吸入一氧化氮的有益作用与右心室后负荷的改变有关,而非右心室固有收缩力。允许性高碳酸血症时吸入一氧化氮改善心肺效应,这可能扩大一氧化氮在ARDS及采用该策略的其他病症中的应用。
