Nasal CPAP therapy: effects of different CPAP levels on pressure transmission into the trachea and pulmonary oxygen transfer

Background: Nasal continuous positive airway pressure (nCPAP) is considered useful for prophylaxis and treatment of respiratory complications following major thoracic surgery. It is unknown, however, which CPAP levels are required to avoid alveolar derecruitment and to consistently improve pulmonary...

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Published in:Acta anaesthesiologica Scandinavica 2002-08, Vol.46 (7), p.860-865
Main Authors: Kindgen-Milles, D., Buhl, R., Loer, S. A., Müller, E.
Format: Article
Language:English
Subjects:
Aged
Anesthesia
Anesthesia depending on type of surgery
Anesthesia. Intensive care medicine. Transfusions. Cell therapy and gene therapy
Biological and medical sciences
Female
Hemodynamics
Humans
intensive care
Male
Medical sciences
nasal continuous positive airway pressure
Oxygen - physiology
Positive-Pressure Respiration
Postoperative Care
Pressure
Pulmonary Gas Exchange
pulmonary oxygen transfer
Thoracic and cardiovascular surgery. Cardiopulmonary bypass
Thoracic Surgical Procedures
thoracotomy
Trachea - physiology
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Summary:Background: Nasal continuous positive airway pressure (nCPAP) is considered useful for prophylaxis and treatment of respiratory complications following major thoracic surgery. It is unknown, however, which CPAP levels are required to avoid alveolar derecruitment and to consistently improve pulmonary oxygen transfer in patients following thoracotomy. We therefore studied the effects of different nCPAP levels on pressure transmission into the trachea as well as on pulmonary oxygen transfer. Methods:   In 10 consecutive patients after cardiac or thoracic vascular surgery, following extubation in the ICU, nCPAP was generated by means of a high‐flow gas source and applied randomly at levels of 5 or 10 cm H2O. Airway pressure was recorded continuously in the nasal mask and the trachea. The PaO2/FiO2ratio was calculated from the tracheal oxygen concentration, and PaO2 was determined while breathing at an ambient and elevated airway pressure. Haemodynamic variables (heart rate, arterial blood pressure, central venous pressure) were also recorded. Results:   Mean pressures in the nasal mask were 5.4±0.1 and 9.7±0.3 cm H2O. Corresponding tracheal pressures were 2.8±1.0 vs. 7.2±1.1 cm H2O (P=0.007). With higher mask pressure, the fraction of pressure transferred from the nasal mask into the trachea was larger (0.75±0.03 vs. 0.52±0.05; P=0.04), and tracheal pressures remained positive during the entire respiratory cycle in all patients. In contrast, with 5.4 cm H20, negative pressure changes during inspiration occurred in five out of 10 patients. The PaO2/FiO2 ratio increased from 183±53 (ambient pressure) to 199±74 (nCPAP 5.4 cm H2O; P=0.25) and to 333±54 (nCPAP 9.7 cm H2O; P=0.003). Nasal CPAP did not alter hemodynamics. Conclusion: Nasal CPAP is an effective non‐invasive means of increasing tracheal and thus intrathoracic pressure without adverse hemodynamic effects. Only mask pressures of 9–10 cm H2O were sufficient to consistently improve pulmonary oxygen transfer in patients following thoracotomy.
ISSN:0001-5172
1399-6576
DOI:10.1034/j.1399-6576.2002.460717.x