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Tracheal Gas Insufflation Reduces Requirements for Mechanical Ventilation in a Rabbit Model of Respiratory Distress Syndrome
Author(s) -
Marc-André Bernath,
Robert H. Henning
Publication year - 1997
Publication title -
anaesthesia and intensive care
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 0.494
H-Index - 62
eISSN - 1448-0271
pISSN - 0310-057X
DOI - 10.1177/0310057x9702500103
Subject(s) - insufflation , medicine , tidal volume , anesthesia , ventilation (architecture) , respiratory distress , mechanical ventilation , airway , intensive care , respiratory minute volume , respiratory system , expiration , artificial ventilation , continuous positive airway pressure , peak inspiratory pressure , lung , respiratory disease , intensive care medicine , obstructive sleep apnea , engineering , mechanical engineering
Tracheal gas insufflation is known to lower P a co 2 in larger animal models of respiratory distress syndrome, but its ability to reduce the ventilator pressures and tidal volume needed to achieve an acceptable P a co 2 has not been examined in small animals using modes of ventilation employed in neonatal intensive care. In this study, the effect of insufflating humidified gas into the lower trachea was examined in a saline lung lavage model of respiratory distress syndrome in rabbits, while the peak airway pressure during conventional pressure-limited ventilation was adjusted to keep the P a co 2 approximately constant. Tracheal gas insufflation significantly reduced the peak airway pressure required and reduced the delivered tidal volume but did not affect the AaDO 2 . The effects were more marked at a ventilator rate of 30 breaths per minute than at 60 bpm and more during continuous insufflation than when gas was insufflated only during expiration. These results suggest that tracheal gas insufflation may reduce the risk of ventilation-induced lung disease in the newborn.

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