To investigate the sequence and nature of the peripheral vascular responses during the prodromal period of heat stroke, rats were implanted with Doppler flow probes on the superior mesenteric (SMA), left iliac (LIA) or left renal (LRA), and external caudal (ECA) arteries. Studies were performed in unanesthetized rats (n = 6) exposed to 46 degrees C and in chloralose-anesthetized animals (n = 11) at 40 degrees C. Core (Tc) and tail-skin temperatures, heart rate, and mean arterial blood pressure (MAP) were also monitored. In both groups, prolonged (70-150 min) exposure progressively elevated Tc from 37.0 to 44.0 degrees C. MAP rose to a plateau then fell precipitously as Tc exceeded 41.5 degrees C. SMA resistance increased throughout the early stages of heating, with a sharp decline from this elevated level 10-15 min before the precipitous fall in MAP. ECA resistance fell initially but increased in the terminal stage of heating. In unanesthetized animals, LIA resistance progressively declined. In chloralose-anesthetized animals LRA resistance rose progressively, then increased markedly as Tc exceeded 41.5 degrees C. These data support the hypothesis that a selective loss of compensatory splanchnic vasoconstriction may trigger the cascade of events that characterize heat stroke. This differential vascular response was similar in both unanesthetized and anesthetized animals.
SUMMARY1. Renal sympathetic nerve activity (RNA), heart rate (HR), arterial blood pressure (AP), and force development were measured simultaneously during voluntary static (isometric) exercise performed by conscious cats. The cats were operantly trained to press a bar with one forelimb. When the force applied to the bar exceeded a predetermined value (threshold), a sound was emitted by a buzzer for audio-feedback. If the cat continued to produce the appropriate force for a period of 26-55 s, food was given as a reward.2. A total of eighty-nine exercise trials were performed by seven cats. The peak force applied to the bar was 468 + 28 g (mean + S.E.M.). RNA, HR, and AP increased significantly from the control value during static exercise by 102 + 14%, 23 + 2 beats/min, and 11 + 1 mmHg, respectively.3. The increase in RNA had both an initial and a late component. The initial component occurred at or immediately before the onset of force development and lasted for 10 s, while the late component gradually increased 14 s after the onset of static exercise and was sustained until the exercise was terminated.4. HR also increased at the beginning of static exercise with a similar time course as RNA. Then, HR returned to the control value and remained at that level during the remainder of exercise. The increase in AP was delayed by 10 s from the initial increase in RNA and then continued to rise throughout the period of exercise.5. The sound of the buzzer was emitted during rest to determine any influence of anticipation or conditioning on the response. RNA and AP increased slightly, but HR did not change. The increases in RNA and AP were much smaller than the increases obtained during static exercise. Thus, the increases in RNA, HR and AP during static exercise appeared to be associated with the exercise itself and not due to anticipation and/or conditioning.6. When AP was elevated by a bolus injection of noradrenaline, RNA during rest was almost abolished and the increase of RNA during static exercise was markedly inhibited. Thus the arterial baroreflex significantly influences RNA both during rest and during static exercise.7. This study suggests that the initial increases in RNA and HR at the beginning
Reflex response of cardiac sympathetic nerve activity (CSNA) during static contraction of the triceps surae muscle was studied using anesthetized cats. A 1-min contraction was evoked by stimulating the peripheral ends of the cut L7 and S1 ventral roots. CSNA increased 48 +/- 13% immediately after the onset of contraction, which was abolished by cutting the L4-S1 dorsal roots. This rapid increase in CSNA preceded rises in heart rate (13 +/- 1 beats/min) and arterial blood pressure (33 +/- 6 mmHg). When tension development was altered by changing the frequency of ventral root stimulation or the initial muscle length, the CSNA increase depended on the tension developed. Passive stretch of the muscle, which primarily activates mechanoreceptors, increased CSNA by 41 +/- 22%. When the contraction was sustained for 5 min, CSNA remained elevated throughout the contraction despite a fall in tension, suggesting that the later increase in CSNA is caused by factors other than a mechanical event of contraction (e.g., metabolic products). Thus it is suggested that cardiac sympathetic outflow is stimulated due to a reflex arising from the contracting muscle. The increase in CSNA at the initiation of contraction is likely to be caused by a reflex from muscle mechanoreceptors, which is followed by a subsequent increase due to a reflex from muscle metaboreceptors.
Renal sympathetic nerve activity (RSNA), arterial blood pressure (AP), and heart rate (HR) were measured during isometric muscle contraction of a hindlimb in chloralose-anesthetized cats. In 14 cats RSNA, AP, and HR increased during a 1-min contraction by 45%, 39 mmHg, and 11 beats/min, respectively; however, in three cats there was a brief initial decrease in RSNA followed by an increase. In 11 cats isometric contraction was maintained for 5 min by alternate stimulation of the L7 and S1 ventral roots. In the first 1 min of sustained contraction, there was a positive correlation (gamma = 0.58, P less than 0.005) between RSNA and tension development. Thereafter RSNA remained elevated despite a tension decrease, and there was no significant correlation between these changes. The RSNA response to contraction of both hindlimbs was greater than that to contraction of either hindlimb alone. Passive stretch of the hindlimb muscle significantly increased RSNA. Thus the initial increase in RSNA during sustained contraction is likely due to activation of muscle mechanoreceptors, whereas the later increase is probably caused by activation of the muscle metaboreceptors.
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