Ca. Smith et al., VENTILATORY EFFECTS OF SPECIFIC CAROTID-BODY HYPOCAPNIA AND HYPOXIA IN AWAKE DOGS, Journal of applied physiology, 82(3), 1997, pp. 791-798
Specific carotid body (CB) hypocapnia in the - 10-Torr (less than eupn
eic) range reduced ventilation in the awake and sleeping dog to the sa
me degree as did CB hyperoxia [CB PO2 (PCBO2); >500 Torr; C. A. Smith,
K. W. Saupe, K. S. Henderson, and J. A. Dempsey J. Appl. Physiol. 79:
689-699, 1995], suggesting a powerful inhibitory effect of hypocapnia
at the carotid chemosensor over a range of PCO2 encountered commonly
in physiological hyperpneas. The primary purpose of this study was to
assess the ventilatory effect of CB hypocapnia on the ventilatory resp
onse to concomitant CB hypoxia. The secondary purpose was to assess th
e relative gains of the CB and central chemoreceptors to hypocapnia. I
n eight awake female dogs the vascularly isolated CB was perfused with
hypoxic blood (mild, PCBO2 congruent to 50 Torr or severe, PCBO2 cong
ruent to 36 Torr) in a background of normocapnia or hypocapnia (10 Tor
r less than eupneic arterial PCO2) in the perfusate. The systemic (and
brain) circulation was normoxic throughout, and arterial PCO2 was not
controlled (poikilocapnia). With CB hypocapnia, the peak ventilation
(range 19-27 s) in response to hypoxic CB perfusion increased 48% (mil
d) and 77% (severe) due to increased tidal volume. When CB hypocapnia
was present, these increases in ventilation were reduced to 21 and 27%
, respectively. With systemic hypocapnia, with the isolated CB maintai
ned normocapnic and hypoxic for >70 s, the steady-state poikilocapnic
ventilatory response (i.e., to systemic hypocapnia alone) decreased 15
% (mild CB hypoxia) and 27% (severe CB hypoxia) from the peak response
, respectively. We conclude that carotid body hypocapnia can be a majo
r source of inhibitory feedback to respiratory motor output during the
hyperventilatory response to hypoxic carotid body stimulation.