Journal of Applied Physiology, Vol 79, Issue 1 312-323, Copyright © 1995 by American Physiological Society

ARTICLES

Neuromechanical regulation of respiratory motor output in ventilator-dependent C1-C3 quadriplegics

P. M. Simon, A. M. Leevers, J. L. Murty, J. B. Skatrud and J. A. Dempsey
Medical Research Service, William S. Middleton Memorial Veterans Hospital, Madison 53705, USA.

To evaluate the role of phrenic and sternocleidomastoid afferents as alternate sources of inhibitory feedback during mechanical ventilation, we studied five C2-C3 quadriplegics with sensory denervation of the rib cage and diaphragm, six C1-C2 quadriplegics with additional loss of sensory feedback from the neck muscles, and seven normal subjects. We compared the return of inspiratory muscle activity [the recruitment threshold (PCO2RT)] during mechanical ventilation between subject groups after stepwise increases in end-tidal PCO2 (PETCO2) either by increasing the inspired fraction of CO2 (FICO2), decreasing tidal volume (VT; 50 ml/min), or decreasing frequency (f; 1 breath/2 min). Normal subjects were mechanically hyperventilated via a nasal mask until inspiratory activity was undetectable. Efferent input to the sternocleidomastoid was intact at both levels of spinal cord injury, but phasic activity was not evident at the quadriplegics' baseline resting ventilation. The PCO2RT was defined as the level of PETCO2 at which phasic activity of the diaphragm in normal subjects and of the sternocleidomastoid in C1-C2 and C2-C3 quadriplegics recurred. The mean PCO2RT (in response to raising PETCO2 via increased FICO2 while maintaining a high VT and f) was not significantly different (P = 0.6) between normal subjects (43 +/- 3 Torr) and C2-C3 quadriplegics (38 +/- 5 Torr). Both subject groups demonstrated a frequency- and volume-related inhibition, as evidenced by a substantially lower PCO2RT when PETCO2 was raised by reducing either VT or f. In contrast to the C2-C3 quadriplegics, the C1-C2 quadriplegics responded with a similar PCO2RT among the three different mechanical ventilation trials, independent of whether PETCO2 was raised with high VT and f, with reduced VT, or with reduced f. We conclude that feedback from at least some part of the chest wall is required to produce a volume- and frequency-dependent inhibition of inspiratory muscle activity observed during mechanical ventilation.

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