CO2 homeostasis during periodic breathing in obstructive sleep apnea

Division of Pulmonary and Critical Care Medicine and Bellevue Hospital Chest Service, Department of Medicine, New York University School of Medicine, New York, New York 10016 The contribution of apnea to chronic hypercapnia in obstructive sleep apnea (OSA) has not been clarified. Using a model (D. M. Rapoport, R. G. Norman, and R. M. Goldring. J. Appl. Physiol. 75: 2302-2309, 1993), we previously illustrated failure of CO 2 homeostasis during periodic breathing resulting from temporal dissociation between ventilation and perfusion ("temporal / mismatch"). This study measures acute kinetics of CO 2 during periodic breathing and addresses interapnea ventilatory compensation for maintenance of CO 2 homeostasis in 11 patients with OSA during daytime sleep (37-171 min). Ventilation and expiratory CO 2 and O 2 fractions were measured on a breath-by-breath basis by means of a tight-fitting full facemask. Calculations included CO 2 excretion, metabolic CO 2 production, and CO 2 balance (metabolic CO 2 production exhaled CO 2 ). CO 2 balance was tabulated for each apnea/hypopnea event-interevent cycle and as a cumulative value during sleep. Cumulative CO 2 balance varied ( 3,570 to +1,388 ml). Positive cumulative CO 2 balance occurred in the absence of overall hypoventilation during sleep. For each cycle, positive CO 2 balance occurred despite increased interevent ventilation to rates as high as 45 l/min. This failure of CO 2 homeostasis was dependent on the event-to-interevent duration ratio. The results demonstrate that 1 ) periodic breathing provides a mechanism for acute hypercapnia in OSA, 2 ) acute hypercapnia during periodic breathing may occur without a decrease in average minute ventilation, supporting the presence of temporal / mismatch, as predicted from our model, and 3 ) compensation for CO 2 accumulation during apnea/hypopnea may be limited by the duration of the interevent interval. The relationship of this acute hypercapnia to sustained chronic hypercapnia in OSA remains to be further explored. carbon dioxide; blood; hypercapnia (physiopathology); respiration; sleep apnea syndromes (physiopathology); pulmonary gas exchange (physiology)