Allen Gilman B, Pavone Lucio A, DiRocco Joseph D, Bates Jason H T, Nieman Gary F
Department of Medicine, Vermont Lung Center, 149 Beaumont Avenue, Burlington, VT 05405-0075, USA.
J Appl Physiol (1985). 2005 Aug;99(2):723-30. doi: 10.1152/japplphysiol.01339.2004. Epub 2005 Apr 14.
The mechanical derangements in the acutely injured lung have long been ascribed, in large part, to altered mechanical function at the alveolar level. This has not been directly demonstrated, however, so we investigated the issue in a rat model of overinflation injury. After thoracotomy, rats were mechanically ventilated with either 1) high tidal volume (Vt) or 2) low Vt with periodic deep inflations (DIs). Forced oscillations were used to measure pulmonary impedance every minute, from which elastance (H) and hysteresivity (eta) were derived. Subpleural alveoli were imaged every 15 min using in vivo video microscopy. Cross-sectional areas of individual alveoli were measured at peak inspiration and end exhalation, and the percent change was used as an index of alveolar instability (%I-EDelta). Low Vt never led to an increase in %I-EDelta but did result in progressive atelectasis that coincided with an increase in H but not eta. DI reversed atelectasis due to low Vt, returning H to baseline. %I-EDelta, H, and eta all began to rise by 30 min of high Vt and were not reduced by DI. We conclude that simultaneous increases in both H and eta are reflective of lung injury in the form of alveolar instability, whereas an isolated and reversible increase in H during low Vt reflects merely derecruitment of alveoli.
长期以来,急性损伤肺的机械性紊乱在很大程度上被归因于肺泡水平的机械功能改变。然而,这一点尚未得到直接证实,因此我们在过度充气损伤的大鼠模型中研究了这个问题。开胸术后,大鼠分别接受以下两种机械通气方式:1)高潮气量(Vt);2)低潮气量并伴有周期性深吸气(DI)。每分钟使用强迫振荡法测量肺阻抗,并由此得出弹性(H)和滞后率(η)。每隔15分钟使用体内视频显微镜对胸膜下肺泡进行成像。在吸气峰值和呼气末测量单个肺泡的横截面积,其变化百分比用作肺泡不稳定性指标(%I-EDelta)。低潮气量从未导致%I-EDelta增加,但确实导致了进行性肺不张,同时H增加而η未增加。DI可逆转因低潮气量导致的肺不张,使H恢复到基线水平。高潮气量通气30分钟时,%I-EDelta、H和η均开始升高,且DI不能使其降低。我们得出结论,H和η同时升高反映了以肺泡不稳定性形式存在的肺损伤,而低潮气量期间H单独且可逆的升高仅反映了肺泡的萎陷。
