Journal of Applied Physiology, Vol 75, Issue 3 1129-1139, Copyright © 1993 by American Physiological Society

ARTICLES

Effects of rapid-eye-movement sleep on the apneic threshold in dogs

L. Xi, C. A. Smith, K. W. Saupe, K. S. Henderson and J. A. Dempsey
John Rankin Laboratory of Pulmonary Medicine, Department of Preventive Medicine, University of Wisconsin, Madison 53705.

We determined whether the apneic threshold after active hyperventilation was different in rapid-eye-movement (REM) vs. non-REM (NREM) sleep. Sleeping dogs were repeatedly exposed to 35-45 s of hypoxia of varying severity (end-tidal PO2 40-60 Torr) that was abruptly terminated with 100% O2. Changes in breathing pattern after brief hypoxia were compared with those after a normoxia-to-hyperoxia transition, i.e., control conditions. In NREM sleep, hypoxic hyperventilation was consistently followed by central apnea, the duration of which was linearly related to the corresponding hypocapnia and/or increase in tidal volume (VT) during hypoxia. After hypoxia, expiratory duration averaged 3.5 x control value at -5-Torr change in end-tidal PCO2 and twofold increase in VT; mean expiratory duration was 5 x control value at -10-Torr change in end-tidal PCO2 and fourfold increase in VT. In REM sleep, central apnea of varying duration did occur on occasion after brief hypoxic hyperventilation, but there was no systematic relationship with magnitude of hypocapnia or increase in VT. Breathing pattern during or after hypoxia in REM was not related to temporal changes in either eye movement density or electroencephalogram frequency. Thus, in contrast to NREM sleep, in REM sleep ("phasic" or "tonic") a posthyperventilation apneic threshold was not present. We attribute this effect of REM to 1) a reduced VT response to hypoxia that would minimize inhibitory "memory" effect from lung stretch and 2) attenuated inhibitory response to any given magnitude of hypocapnia or increased VT. Active hyperventilation-induced apneic threshold may be "masked" by actions of nonchemoreceptor and nonmechanoreceptor inputs affecting respiratory motor output in REM sleep. These data are consistent with the relative absence of central apnea and periodic breathing in humans in REM sleep.

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