David Matthias, Karmrodt Jens, Bletz Carsten, David Sybil, Herweling Annette, Kauczor Hans-Ulrich, Markstaller Klaus
Department of Anesthesiology, Johannes Gutenberg-University, Mainz, Germany.
Chest. 2005 Nov;128(5):3757-70. doi: 10.1378/chest.128.5.3757.
To study the dynamics of lung compartments by dynamic CT (dCT) imaging during uninterrupted pressure-controlled ventilation (PCV) and different positive end-expiratory pressure (PEEP) settings in healthy and damaged lungs.
Experimental animal investigation.
Experimental animal facility of a university department.
In seven anesthetized pigs, static inspiratory pressure volume curves were obtained to identify the individual lower inflection point (LIP) before and after saline solution lung lavage. During PCV, PEEP was adjusted 5 millibars (mbar) below the individually determined LIP (LIP - 5), at the LIP, and 5 mbar above the LIP (LIP + 5).
Measurements were repeated before and after induction of lung damage. Hemodynamics, arterial and mixed venous blood gases, and dCT imaging in one juxtadiaphragmatic slice (effective temporal resolution of 100 ms) were assessed during uninterrupted PCV in series of three successive respiratory cycles. The mean fractional area (FA) of the hyperinflated lung (FA-H), mean FA of ventilated lung, mean FA of poorly ventilated lung, and mean FA of nonventilated lung (FA-NV), and the change in FA of the whole lung area (DeltaFA) were compared at different PEEP settings. Calculated pulmonary shunt (Qs/Qt) was compared to FA-NV. LIP + 5 decreased the amount of atelectasis (FA-NV) and increased hyperinflation (FA-H) in healthy and injured lungs. Cyclic changes of atelectasis (DeltaFA-NV) and hyperinflation (DeltaFA-H) were observed in both healthy and injured lungs. In the injured but not in the healthy lungs, the amount of cyclic changes of atelectasis and hyperinflation were independent from the adjusted PEEP level. FA-NV correlated with the calculated Qs/Qt, with a slight overestimation (mean +/- SEM, 2.1 +/- 4.1%).
dCT imaging allows the following: (1) the quantification of the extent of atelectasis, ventilated, poorly ventilated, and hyperinflated lung parenchyma during ongoing mechanical ventilation; (2) the detection and quantification of repeated recruitment and derecruitment, as well as hyperinflation; and (3) an estimation of Qs/Qt. dCT adds promising functional information for the respiratory treatment of early ARDS.
通过动态CT(dCT)成像研究健康肺和受损肺在持续压力控制通气(PCV)及不同呼气末正压(PEEP)设置下肺区室的动态变化。
实验动物研究。
大学某系的实验动物设施。
对7只麻醉猪,在生理盐水肺灌洗前后获取静态吸气压力-容积曲线,以确定个体的低位拐点(LIP)。在PCV期间,将PEEP调整至低于个体确定的LIP 5毫巴(mbar)(LIP - 5)、处于LIP水平以及高于LIP 5 mbar(LIP + 5)。
在诱导肺损伤前后重复测量。在连续三个呼吸周期的持续PCV期间,评估血流动力学、动脉血和混合静脉血气以及一个膈旁层面的dCT成像(有效时间分辨率为100毫秒)。比较不同PEEP设置下过度充气肺的平均分数面积(FA)(FA-H)、通气肺的平均FA、通气不良肺的平均FA和未通气肺的平均FA(FA-NV),以及全肺面积FA的变化(DeltaFA)。将计算得到的肺内分流(Qs/Qt)与FA-NV进行比较。LIP + 5可减少健康肺和损伤肺的肺不张量(FA-NV)并增加过度充气(FA-H)。在健康肺和损伤肺中均观察到肺不张(DeltaFA-NV)和过度充气(DeltaFA-H)的周期性变化。在损伤肺而非健康肺中,肺不张和过度充气的周期性变化量与调整后的PEEP水平无关。FA-NV与计算得到的Qs/Qt相关,略有高估(均值±标准误,2.1±4.1%)。
dCT成像能够:(1)在进行机械通气时对肺不张、通气、通气不良和过度充气的肺实质范围进行量化;(2)检测和量化反复的肺复张和萎陷以及过度充气;(3)估算Qs/Qt。dCT为早期急性呼吸窘迫综合征的呼吸治疗增添了有前景的功能信息。
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