Effects of aortic nerve on hemodynamic response to obstructive apnea in sedated pigs

In this study we test the hypothesis that aortic nerve traffic is responsible for the pressor response to periodic apneas. In nine intubated, sedated chronically instrumented pigs, periodic obstructive apneas were caused by occlusion of the endotracheal tube for 30 s, followed by spontaneous breathing for 30 s. This was done under control (C) conditions, after section of the aortic nerve (ANS), and after bilateral cervical vagotomy (Vagot). Blood-gas tensions and airway pressure changed similarly under all conditions: Po 2 decreased to 50–60 Torr, Pco 2 increased to ∼55 Torr, and airway pressure decreased by 40–50 mmHg during apnea. With C, mean arterial pressure (MAP) increased from 111 ± 4 mmHg at baseline to 120 ± 5 mmHg at late apnea ( P < 0.01). After ANS and Vagot, there was no change in MAP with apneas compared with baseline. Relative to baseline, cardiac output and stroke volume decreased with C but not with ANS or Vagot during apneas. Increased MAP was due to increased systemic vascular resistance. Heart rate behaved similarly with C and ANS, being greater at early interapnea than late apnea. With Vagot, heart rate increased throughout the apnea-interapnea cycle relative to baseline. We conclude that, in sedated pigs, aortic nerve traffic mediates the increase in MAP and systemic vascular resistance observed during periodic apneas. Increase in MAP is responsible for decreased cardiac output and stroke volume. Additional vagal reflexes, most likely parasympathetic efferents, are responsible for interacting with sympathetic excitatory influences in modulating heart rate.

Subthreshold aortic nerve inputs to neurons in nucleus of the solitary tract

Subthreshold aortic nerve (AN) inputs to neurons receiving a monosynaptic AN-evoked input (MSNs: respond to each of two AN stimuli separated by 5 ms) and neurons receiving a polysynaptic AN input (PSNs) in the nucleus of the solitary tract (NTS) were identified in anesthetized rats. In extracellular recordings from 24 MSNs and 49 PSNs, 12% of MSNs and 29% of PSNs only responded to AN stimulation during the application of excitatory amino acids. In intracellular recordings from 24 MSNs and 22 PSNs, 12% of MSNs and 14% of PSNs responded to AN stimulation with excitatory postsynaptic potentials that did not evoke action potential discharge. Reductions in arterial pressure produced minimal changes in the spontaneous discharge of suprathreshold AN-evoked neurons, suggesting that these neurons receive excitatory inputs from nonbaroreceptor sources. The results suggest that some baroreflex-related NTS neurons exist in a “reserve state” and can be changed to an active state or vice versa. This will change the number of neurons involved in baroreflex circuits and provides a novel mechanism for regulating baroreflex function independently of alterations in peripheral afferent input.

Estrogen enhancement of baroreflex sensitivity is centrally mediated

We have recently shown that estrogen enhances baroreceptor control of reflex bradycardia in conscious rats. The present study replicated this finding in pentobarbital sodium-anesthetized rats, and the study was extended to investigate whether this effect of estrogen is centrally or peripherally mediated. Hemodynamic responses to electrical stimulation of the central end of the aortic depressor or the vagal efferent nerve were evaluated in pentobarbital sodium-anesthetized sham-operated (SO), ovariectomized (OVX), and OVX estradiol-treated Sprague-Dawley rats. Phenylephrine (1–16 μg/kg iv) elicited dose-dependent pressor and bradycardic responses. Regression analysis of the baroreflex curves, relating changes in mean arterial pressure and heart rate, revealed a significantly smaller baroreflex sensitivity in OVX compared with SO anesthetized rats (−0.54 ± 0.05 and −0.91 ± 0.12 beats ⋅ min−1 ⋅ mmHg−1, respectively; P < 0.05). Treatment of OVX rats with 17β-estradiol (E2, 50 μg ⋅ kg−1 ⋅ day−1for 2 days subcutaneously) significantly enhanced baroreflex sensitivity to a level similar to that of SO rats ( P < 0.05). The enhancing effect of E2 on the baroreflex-mediated bradycardia, observed in conscious and anesthetized rats, seems to be selective because the baroreflex-mediated tachycardic responses measured in a separate group of conscious rats were not altered by ovariectomy or E2 administration. Electrical stimulation of the aortic nerve elicited frequency-dependent depressor and bradycardic responses that were significantly smaller in OVX compared with SO values ( P < 0.05). Treatment of OVX rats with E2 restored the hemodynamic responses to aortic stimulation to near SO levels. On the other hand, hemodynamic responses to vagal stimulation were not affected by OVX or treatment with E2. These findings suggest that enhancement of reflex bradycardia by estrogen is centrally mediated and involves interaction with central projections of the aortic nerve.

Effects of aortic nerve stimulation on discharges of sympathetic neurons innervating rat tail artery and vein

Activity was recorded from postganglionic sympathetic neurons (PSNs) innervating either the caudal ventral artery (CVA) or a lateral vein (LV) of the tail circulation of anesthetized rats. The study sought to determine whether sympathetic activity directed at the CVA and LV was influenced by cardiovascular mechanoreceptor afferents and whether this effect was differential. Cardiac rhythmicity was not a robust component of either CVA PSN activity or LV PSN activity. Stimulation of an aortic nerve with short trains was followed by a decreased probability of discharge in both CVA and LV PSNs that was followed by a series of peaks that showed a constant periodicity that was not significantly different from that revealed by autocorrelogram analysis over the same data set. The latter dominant periodicity is referred to in this and related previous publications as the T rhythm. Furthermore, blood volume expansion and long-train aortic nerve stimulation produced a significant decrease in the frequency of the T rhythm. It is concluded that the CVA and LV sympathetic activity can be influenced by inputs from cardiovascular mechanoreceptors and that this effect is mediated in part by a modulation of the T rhythm.