Computer tomographic assessment of perfluorocarbon and gas distribution during partial liquid ventilation for acute respiratory failure

The average in vivo chest computed tomographic (CT) attenuation number (air = -1,000, soft tissue = 0, perflubron = +2,300 Hounsfield units [HU]) of 10 ventrodorsal-oriented lung segments was calculated to assess the distribution of gas and perflubron in 14 oleic acid lung-injured adult sheep during...

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Bibliographic Details
Published in:American journal of respiratory and critical care medicine 1998-07, Vol.158 (1), p.249-255
Main Authors: QUINTEL, M, HIRSCHL, R. B, ROTH, H, LOOSE, R, VAN ACKERN, K
Format: Article
Language:English
Subjects:
Acute Disease
Anesthesia. Intensive care medicine. Transfusions. Cell therapy and gene therapy
Animals
Biological and medical sciences
Disease Models, Animal
Emergency and intensive respiratory care
Fluorocarbons - administration & dosage
Fluorocarbons - pharmacokinetics
Intensive care medicine
Lung - diagnostic imaging
Medical sciences
Oleic Acid
Pulmonary Gas Exchange
Respiration, Artificial - methods
Respiratory Insufficiency - physiopathology
Respiratory Insufficiency - therapy
Sheep
Tomography, X-Ray Computed
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Summary:The average in vivo chest computed tomographic (CT) attenuation number (air = -1,000, soft tissue = 0, perflubron = +2,300 Hounsfield units [HU]) of 10 ventrodorsal-oriented lung segments was calculated to assess the distribution of gas and perflubron in 14 oleic acid lung-injured adult sheep during partial liquid ventilation (PLV, n = 7) or gas ventilation (GV, n = 7). Partial liquid ventilation was associated with a significant decrease in shunt fraction (PLV = 40 +/- 12%, GV = 76 +/- 12%, p = 0.004). Computed tomographic attenuation data during expiration (HUexp) demonstrated minimal gas aeration in GV animals in the dependent (segments 6-10) lung zones (HUexp = -562 +/- 108 for segments 1-5, HUexp = -165 +/- 104 for segments 6-10, p = 0.015). During PLV, perflubron was predominantly distributed to the dependent lung regions (HUexp = 579 +/- 338 for segments 1-5, HUexp = 790 +/- 149 for segments 6-10, p = 0.04). The ratio of the inspiratory to expiratory HU (HUinsp/exp) was greater in dependent than nondependent regions (mean HUinsp/exp segments 1-5 = 0.56, segments 6-10 = 0.81, p = 0.01), indicating that during inspiration relatively more gas than perflubron was distributed to the nondependent lung regions. We conclude that during PLV in this lung injury model, (1) gas exchange is improved when compared with gas ventilation, (2) perflubron is distributed predominantly to the dependent regions of the lung, and (3) although gas is distributed throughout the lung with each inspiration, more gas than perflubron goes to the nondependent lung regions.
ISSN:1073-449X
1535-4970
DOI:10.1164/ajrccm.158.1.9605062