Clinically plausible hyperventilation does not exert adverse hemodynamic effects during CPR but markedly reduces end-tidal PCO2

Clinically plausible hyperventilation does not exert adverse hemodynamic effects during CPR but markedly reduces end-tidal PCO2

Abstract Aims Ventilation at high respiratory rates is considered detrimental during CPR because it may increase intrathoracic pressure limiting venous return and forward blood flow generation. We examined whether ventilation at high, yet clinically plausible, tidal volumes could also be detrimental...

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Bibliographic Details
Published in:Resuscitation Vol. 83; no. 2; pp. 259 - 264
Main Authors: Gazmuri, Raúl J, Ayoub, Iyad M, Radhakrishnan, Jeejabai, Motl, Jill, Upadhyaya, Madhav P
Format: Journal Article
Language:English
Published: Elsevier Ireland Ltd 01-02-2012
Subjects:
Animal
Cardiopulmonary resuscitation
Emergency
Hemodynamics
Swine
Ventilation
Ventricular fibrillation
Swine
Cardiopulmonary resuscitation
Animal
Ventilation
Models
Hemodynamics
Ventricular fibrillation
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Summary:Abstract Aims Ventilation at high respiratory rates is considered detrimental during CPR because it may increase intrathoracic pressure limiting venous return and forward blood flow generation. We examined whether ventilation at high, yet clinically plausible, tidal volumes could also be detrimental, and further examined effects on end-tidal pCO2 (PET CO2 ). Methods Sixteen domestic pigs were randomized to one of four ventilatory patterns representing two levels of respiratory rate (min−1 ) and two levels of tidal volume (ml/kg); i.e., 10/6, 10/18, 33/6, and 33/18 during chest compression after 8 min of untreated VF. Results Data (mmHg, mean ± SD) are presented in the order listed above. Ventilation at 33/18 prompted higher airway pressures ( p < 0.05) and persistent expiratory airway flow ( p < 0.05) before breath delivery demonstrating air trapping. The right atrial pressure during chest decompression showed a statistically insignificant increase with increasing minute-volume (7 ± 4, 10 ± 3, 12 ± 1, and 13 ± 3; p = 0.055); however, neither the coronary perfusion pressure (23 ± 1, 17 ± 6, 18 ± 6, and 21 ± 2; NS ) nor the cerebral perfusion pressure (32 ± 3, 23 ± 8, 30 ± 12, and 31 ± 3; NS ) was statistically different. Yet, increasing minute-volume reduced the PET CO2 demonstrating a high dependency on tidal volumes delivered at currently recommended respiratory rates. Conclusions Increasing respiratory rate and tidal volume up to a minute-volume 10-fold higher than currently recommended had no adverse hemodynamic effects during CPR but reduced PET CO2 suggesting that ventilation at controlled rate and volume could enhance the precision with which PET CO2 reflects CPR quality, predicts return of circulation, and serve to guide optimization of resuscitation interventions.
ISSN:0300-9572
1873-1570
DOI:10.1016/j.resuscitation.2011.07.034