Hypothalamic neurons responding to hemodynamic input and to stimulation in the pons may influence adrenocorticotropin release.

Experiments were designed to identify hemodynamically sensitive neurons in the mediodorsal hypothalamus and to determine if they were also sensitive to electrical stimulation of areas in the dorsal rostral pons that were implicated previously in the control of adrenocorticotropin (ACTH) release. Cats were anesthetized with chloralose and urethane, immobilized with gallamine, and artificially respired. Hemodynamic stimuli included constriction (CC) of the supradiaphragmatic inferior vena cava to reduce venous return and sinusoidal volume pulsation (RA) of the right atrium (1 ml peak at 1 Hz). Previously, CC was shown to facilitate and RA was shown to inhibit ACTH release. Electrical stimulation in the pons consisted of single shocks (500 microA DC, 0.05 msec, negative-to-tip) delivered on each of an array of three or four bipolar co-axial electrodes in the pons. Twenty-three neurons were tested with only RA. Of these, two were inhibited, two were facilitated, and 19 did not respond. Thirty-two neurons were tested with CC. Of these, nine were inhibited, nine were facilitated, and 14 did not respond. Seventeen neurons that responded either to RA or to CC were tested with stimulation in the pons. Of these, three were orthodromically activated and two were inhibited from a total of eight pontine sites. Six of the eight sites were within 300 microns of an area shown previously to contain neurons that responded to CC. Of 31 additional sites that were stimulated, but at which stimulation did not drive neurons that responded to hemodynamic stimuli, 26 were located more than 300 microns from this area (p less than 0.01, X2 test). The data suggest that some hypothalamic neurons involved in the hemodynamic control of ACTH release receive a projection from or through the dorsal raphe nucleus medially, and the ventral locus ceruleus, locus subceruleus, and underlying reticular formation laterally. However, other neurons may receive projections that bypass these regions.