Open-lung protective ventilation with Pressure control ventilation, high-frequency oscillation, and intratracheal pulmonary ventilation results in similar gas exchange, hemodynamics, and lung mechanics

Pressure control ventilation (PCV), high-frequency oscillation (HFO), and intratracheal pulmonary ventilation (ITPV) may all be used to provide lung protective ventilation in acute respiratory distress syndrome, but the specific approach that is optimal remains controversial. Saline lavage was used...

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Bibliographic Details
Published in:Anesthesiology (Philadelphia) 2003-11, Vol.99 (5), p.1102-1111
Main Authors: SEDEEK, Khaled A, TAKEUCHI, Muneyuki, SUCHODOLSKI, Klaudiusz, VARGAS, Sara O, SHIMAOKA, Motomu, SCHNITZER, Jay J, KACMAREK, Robert M
Format: Article
Language:English
Subjects:
Air Pressure
Algorithms
Anesthesia. Intensive care medicine. Transfusions. Cell therapy and gene therapy
Animals
Biological and medical sciences
Emergency and intensive respiratory care
Exudates and Transudates - metabolism
Granulocytes - physiology
Hemodynamics - physiology
Hemorrhage - etiology
Hemorrhage - physiopathology
High-Frequency Ventilation
Intensive care medicine
Interleukin-1 - metabolism
Interleukin-8 - metabolism
Intubation, Intratracheal
Lung - physiology
Medical sciences
Oxygen - blood
Peak Expiratory Flow Rate
Pulmonary Alveoli - physiology
Pulmonary Gas Exchange - physiology
Respiration, Artificial - instrumentation
Respiration, Artificial - methods
Respiratory Mechanics - physiology
Sheep
Tidal Volume - physiology
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Summary:Pressure control ventilation (PCV), high-frequency oscillation (HFO), and intratracheal pulmonary ventilation (ITPV) may all be used to provide lung protective ventilation in acute respiratory distress syndrome, but the specific approach that is optimal remains controversial. Saline lavage was used to produce acute respiratory distress syndrome in 21 sheep randomly assigned to receive PCV, HFO, or ITPV as follows: positive end-expiratory pressure (PCV and ITPV) and mean airway pressure (HFO) were set in a pressure-decreasing manner after lung recruitment that achieved a ratio of Pao2/Fio2 > 400 mmHg. Respiratory rates were 30 breaths/min, 120 breaths/min, and 8 Hz, respectively, for PCV, ITPV, and HFO. Eucapnia was targeted with peak carinal pressure of no more than 35 cm H2O. Animals were then ventilated for 4 h. There were no differences among groups in gas exchange, lung mechanics, or hemodynamics. Tidal volume (PCV, 8.9 +/- 2.1 ml/kg; ITPV, 2.7 +/- 0.8 ml/kg; HFO, approximately 2.0 ml/kg) and peak carinal pressure (PCV, 30.6 +/- 2.6 cm H2O; ITPV, 22.3 +/- 4.8 cm H2O; HFO, approximately 24.3 cm H2O) were higher in PCV. Pilot histologic data showed greater interstitial hemorrhage and alveolar septal expansion in PCV than in HFO or ITPV. These data indicate that HFO, ITPV, and PCV when applied with an open-lung protective ventilatory strategy results in the same gas exchange, lung mechanics, and hemodynamic response, but pilot data indicate that lung injury may be greater with PCV.
ISSN:0003-3022
1528-1175
DOI:10.1097/00000542-200311000-00016