The role of endogenous angiotensin II (ANG II) at the level of the rostral (RVLM) and caudal ventrolateral medulla (CVLM) in the control of sympathetic baroreflex function was investigated in urethan-anesthetized rabbits. The baroreflex relationship between mean arterial pressure and integrated renal sympathetic nerve activity (RSNA) was compared before and during microinfusion of saralasin, an ANG II receptor antagonist into RVLM or CVLM. The infusion of saralasin (20 pmol/min) into RVLM reduced the upper plateau, the range, and the range-dependent gain of the baroreflex, as well as the resting level of RSNA. The infusion of saralasin into CVLM augmented the upper plateau, the reflex range, and the range-dependent gain, whereas it did not alter the resting level of RSNA or mean arterial pressure. These results suggest that 1) the ANG II networks in RVLM are tonically active, influencing the resting level of the sympathetic outflow and facilitating the sympathetic baroreflex function, and 2) the ANG II networks in CVLM do not significantly influence the sympathetic activity in the resting state but exert an inhibitory effect on the baroreflex response when arterial pressure falls below the resting level.
1. Renal and cardiac sympathetic baroreflex functions were studied in sodium pentobarbitone anaesthetized rabbits given succinylcholine, during constant artificial ventilation with air and with hypoxic gas mixtures. Mean arterial pressure (MAP) was raised and lowered between values of 40 and 140 mm Hg by means of aortic and vena caval periovascular balloons and integrated sympathetic nerve activity (SNA) was recordered. 2. The relationship between MAP and SNA was sigmoid, with upper and lower plateau levels. The curves were defined by calculating median blood pressure, SNA Range and reflex gain. In both renal and cardiac sympathetics section of the carotid sinus and aortic nerves completely abolished the MAP-related changes in SNA. 3. The renal baroreflex curves were reset from control levels during hypoxia. Median blood pressure increased, as did SNA Range and gain. These effects were due to central interactions between arterial baroreceptor, arterial chemoreceptor and vagal afferent activity. 4. The cardiac sympathetic baroreflex curves were shifted in the opposite direction from control with reduction in median blood pressure, SNA Range and reflex gain. These changes were due to chemoreceptor-arterial baroreceptor interactions. 5. Arterial hypoxia thus evokes a differentiated pattern of baroreflex resetting in the renal and cardiac sympathetic montoneuron pools with differing changes in neural response range and sensitivity to arterial pressure changes.
In the ears of anaesthetized rabbits cutaneous efferent sympathetic nerve activity (SkNA) and blood flow (Q) to capillaries have been measured during various thermal treatments. Warming the spinal cord or skin of the body midside caused a marked decrease in SkNA but capillary Q increased only slightly. Exposure to a warm environment or localized warming of the ear alone induced either a decrease, an increase, or no change in SkNA, but capillary Q always increased markedly. The usual slight increase in capillary Q during spinal warming, was abolished by preventing the usual marked increase in skin temperature. When the spinal cord of the conscious rat was warmed, a marked increase in temperature of the tail (which contains arteriovenous anastomoses, AVA's) indicated dilatation, whereas there was no change in ear temperature (where there are no AVA's). When these results are considered together with recently defined differential influences of reflex and direct effects of temperature on blood flow through cutaneous AVA's and capillaries, it is concluded: (1) That thermally-induced reflex changes in skin blood flow are mediated via sympathetic nervous action on AVA's; (2) Changes in blood flow evoked by direct heating take place through the capillaries, not the AVA's, quite independently of SkNA.
The patterns of regional changes of sympathetic efferent activity evoked by thermal stimulation of the spinal cord and by arterial and primary tissue hypoxia were investigated in decerebrated, anesthetized and immobilized rabbits. Decerebration was performed either at the mid- or infracollicular level. The responses of the decerebrated rabbits evoked by spinal thermal stimulation were the same as those of intact rabbits, i.e., splanchnic and cardiac sympathetic activity increased and cutaneous sympathetic activity decreased during warming, while the reverse response was elicited by cooling. It is concluded that the typical thermoregulatory response pattern of the sympathetic nervous system can be produced also after the loss of hypothalamic integration, i.e., by integrative mechanisms in the lower brain stem and the spinal cord. In contrast, the responses of decerebrated rabbits to arterial and primary tissue hypoxia differed from those of intact rabbits in that they consisted in an overall activation in all investigated sympathetic branches. It is confirmed by this result that suprabulbar integration is essential for the generation of the inhibitory components in the differential sympathetic responses to hypoxia, which typically consist in cutaneous and cardiac sympathetic inhibition with splanchnic activation during arterial hypoxia and in cutaneous sympathetic inhibition with cardiac and splanchnic sympathetic activation during primary tissue hypoxia.
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