Rapid effects of corticosterone on cardiovascular neurons in the rostral ventrolateral medulla of rats.

The present study has explored possible fast actions of corticosteroid hormones on activity of cardiovascular neurons of the rostral ventrolateral medulla. Experiments were conducted in 60 urethane-anesthetized, artificially ventilated adult rats. Extracellular recordings of unitary firings were made from the RVLM with multi- or single-barreled microelectrodes. Barosensitive cardiovascular neurons were identified through activation of the baroreceptor reflex by electrical stimulation of the aortic nerve and by intravenous injection of phenylephrine. In 52 barosensitive cardiovascular neurons, iontophoretically applied corticosterone sulfate increased the ongoing activity of 30 (57.7%) neurons, the other 22 (42.3%) neurons being unaffected. In 16 bulbospinal pre-sympathetic neurons, iontophorized corticosterone increased the firing rate of 12 neurons. Intravenously applied corticosterone (0.2 mg) increased the firing rates of 5 out of 12 bulbospinal pre-sympathetic neurons. The average baseline activity of cardiovascular neurons sensitive to corticosterone was found to be significantly less than that of the cardiovascular neurons insensitive to corticosterone. In 64 non-cardiovascular neurons, the firing rate of 13 (20.3%) neurons increased, 23 (36.0%) decreased and 28 (43.7%) remained unchanged following local application of corticosterone. The changes in firing rates of RVLM neurons following application of corticosterone occurred rapidly and were dependent on the doses of the agent. RU-38486 was able to reduce or block the rapid effects of corticosterone on cardiovascular and non-cardiovascular neurons. The results demonstrated that corticosterone may fast, non-genomically, modulate the activity of central regulators of the cardiovascular system and suggested that fast non-genomic actions of corticosteroid hormones may be an important mechanism in the integration of the autonomic nervous and the cardiovascular systems during some conditions such as stress.