Muscle mechanoreflex induces the pressor response by resetting the arterial baroreflex neural arc

The effects of the muscle mechanoreflex on the arterial baroreflex neural control have not previously been analyzed over the entire operating range of the arterial baroreflex. In anesthetized, vagotomized, and aortic-denervated rabbits (n = 8), we isolated carotid sinuses and changed intracarotid sinus pressure (CSP) from 40 to 160 mmHg in increments of 20 mmHg every minute while recording renal sympathetic nerve activity (SNA) and arterial pressure (AP). Muscle mechanoreflex was induced by passive muscle stretch (5 kg of tension) of the hindlimb. Muscle stretch shifted the CSP-SNA relationship (neural arc) to a higher SNA, whereas it did not affect the SNA-AP relationship (peripheral arc). SNA was almost doubled [from 63 +/- 15 to 118 +/- 14 arbitrary units (au), P < 0.05] at the CSP level of 93 +/- 8 mmHg, and AP was increased approximately 50% by muscle stretch. When the baroreflex negative feedback loop was closed, muscle stretch increased SNA from 63 +/- 15 to 81 +/- 21 au (P < 0.05) and AP from 93 +/- 8 to 109 +/- 12 mmHg (P < 0.05). In conclusion, the muscle mechanoreflex resets the neural arc to a higher SNA, which moves the operating point towards a higher SNA and AP under baroreflex closed-loop conditions. Analysis of the baroreflex equilibrium diagram indicated that changes in the neural arc induced by the muscle mechanoreflex might compensate for pressure falls resulting from exercise-induced vasodilatation.     

Muscle chemoreflex alters carotid sinus baroreflex response in humans

Papelier, Y., P. Escourrou, F. Helloco, and L. B. Rowell.Muscle chemoreflex alters carotid sinus baroreflex response inhumans. J. Appl. Physiol. 82(2):577-583, 1997.The arterial baroreflex opposes pressor responsesto muscle ischemia (muscle chemoreflex). Our experiments sought toquantify the unknown effects of muscle chemoreflex on carotid sinusbaroreflex (CSB) sensitivity. We generated CSB stimulus-response (S-R)curves by pulsatile application (triggered by each electrocardiogram Rwave) of positive and negative neck pressure (from 60 to 80 mmHgin 20-mmHg steps of 20 s each) in seven normal young men. S-R curveswere obtained at rest (upright), during the last 3 min of upright cycleergometer exercise (150 W), and at the first minute of postexerciserecovery with leg circulation free (control). A second study repeatedthe same procedures, except that leg circulation was occluded 20 sbefore the end of exercise to elicit muscle chemoreflex, and occlusionwas maintained during recovery measurements (~3- to 4-min duration).S-R curves for CSB were shifted upward and rightward (25 mmHg) tohigher arterial blood pressure (BP) by exercise and less so (10 mmHg) in recovery (free leg flow). Postexercise occlusion (musclechemoreflex) raised BP and shifted S-R curves above exercise curves.CSB gain rose from 0.26 ± 0.06 (control) to 0.44 ± 0.08 (occlusion) during positive neck pressure application andwas reduced from 0.14 ± 0.04 to zero (0.04 ± 0.03) during negative neck pressure. Heart rate responses duringpostexercise muscle chemoreflex were not significantly different fromcontrol. Results reveal a nonlinear summation of CSB and musclechemoreflex effects on BP. BP-raising capability of muscle chemoreflexenhances CSB responses to hypotension but overpowers baroreflexopposition to hypertension.

     

Hypoxia augments muscle sympathetic neural response to leg cycling

It was demonstrated that acute hypoxia increased muscle sympathetic nerve activity (MSNA) by using a microneurographic method at rest, but its effects on dynamic leg exercise are unclear. The purpose of this study was to clarify changes in MSNA during dynamic leg exercise in hypoxia. To estimate peak oxygen uptake (Vo(2 peak)), two maximal exercise tests were conducted using a cycle ergometer in a semirecumbent position in normoxia [inspired oxygen fraction (Fi(O(2)) = 0.209] and hypoxia (Fi(O(2)) = 0.127). The subjects performed four submaximal exercise tests; two were MSNA trials in normoxia and hypoxia, and two were hematological trials under each condition. In the submaximal exercise test, the subjects completed two 15-min exercises at 40% and 60% of their individual Vo(2 peak) in normoxia and hypoxia. During the MSNA trials, MSNA was recorded via microneurography of the right median nerve at the elbow. During the hematological trials, the subjects performed the same exercise protocol as during the MSNA trials, but venous blood samples were obtained from the antecubital vein to assess plasma norepinephrine (NE) concentrations. MSNA increased at 40% Vo(2 peak) exercise in hypoxia, but not in normoxia. Plasma NE concentrations did not increase at 40% Vo(2 peak) exercise in hypoxia. MSNA at 40% and 60% Vo(2 peak) exercise were higher in hypoxia than in normoxia. These results suggest that acute hypoxia augments muscle sympathetic neural activation during dynamic leg exercise at mild and moderate intensities. They also suggest that the MSNA response during dynamic exercise in hypoxia could be different from the change in plasma NE concentrations.     

Exercise training augments the dynamic heart rate response to vagal but not sympathetic stimulation in rats

We examined the transfer function of autonomic heart rate (HR) control in anesthetized sedentary and exercise-trained (16 wk, treadmill for 1 h, 5 times/wk at 15 m/min and 15-degree grade) rats for comparison to HR variability assessed in the conscious resting state. The transfer function from sympathetic stimulation to HR response was similar between groups (gain, 4.2 ± 1.5 vs. 4.5 ± 1.5 beats·min(-1)·Hz(-1); natural frequency, 0.07 ± 0.01 vs. 0.08 ± 0.01 Hz; damping coefficient, 1.96 ± 0.55 vs. 1.69 ± 0.15; and lag time, 0.7 ± 0.1 vs. 0.6 ± 0.1 s; sedentary vs. exercise trained, respectively, means ± SD). The transfer gain from vagal stimulation to HR response was 6.1 ± 3.0 in the sedentary and 9.7 ± 5.1 beats·min(-1)·Hz(-1) in the exercise-trained group (P = 0.06). The corner frequency (0.11 ± 0.05 vs. 0.17 ± 0.09 Hz) and lag time (0.1 ± 0.1 vs. 0.2 ± 0.1 s) did not differ between groups. When the sympathetic transfer gain was averaged for very-low-frequency and low-frequency bands, no significant group effect was observed. In contrast, when the vagal transfer gain was averaged for very-low-frequency, low-frequency, and high-frequency bands, exercise training produced a significant group effect (P < 0.05 by two-way, repeated-measures ANOVA). These findings suggest that, in the frequency domain, exercise training augments the dynamic HR response to vagal stimulation but not sympathetic stimulation, regardless of the frequency bands.     

Static interaction between muscle mechanoreflex and arterial baroreflex in determining efferent sympathetic nerve activity

Elucidation of the interaction between the muscle mechanoreflex and the arterial baroreflex is essential for better understanding of sympathetic regulation during exercise. We characterized the effects of these two reflexes on sympathetic nerve activity (SNA) in anesthetized rabbits (n = 7). Under open-loop baroreflex conditions, we recorded renal SNA at carotid sinus pressure (CSP) of 40, 80, 120, or 160 mmHg while passively stretching the hindlimb muscle at muscle tension (MT) of 0, 2, 4, or 6 kg. The MT-SNA relationship at CSP of 40 mmHg approximated a straight line. Increase in CSP from 40 to 120 and 160 mmHg shifted the MT-SNA relationship downward and reduced the response range (the difference between maximum and minimum SNA) to 43 +/- 10% and 19 +/- 6%, respectively (P < 0.01). The CSP-SNA relationship at MT of 0 kg approximated a sigmoid curve. Increase in MT from 0 to 2, 4, and 6 kg shifted the CSP-SNA relationship upward and extended the response range to 133 +/- 8%, 156 +/- 14%, and 178 +/- 15%, respectively (P < 0.01). A model of algebraic summation, i.e., parallel shift, with a threshold of SNA functionally reproduced the interaction of the two reflexes (y = 1.00x - 0.01; r(2) = 0.991, root mean square = 2.6% between estimated and measured SNA). In conclusion, the response ranges of SNA to baroreceptor and muscle mechanoreceptor input changed in a manner that could be explained by a parallel shift with threshold.     

The inhibition of efferent sympathetic activity by means of pressure stimulation of the carotid sinus pressoreceptors]

The influence of pressure stimulation of a barorecptor upon the activity of the sympathetic nerve branch terminating in the wall of the contralateral carotid bifurcation was studied on narcotized dogs. The potential activity of this branch is of efferent nature. On the average, 570 msec after the pressure load applied to the opposite carotid sinus preparation, a silent period occurred. The duration of this silent period and the activity of the sympathetic nerve branch depend on the internal pressure of the preparation. The influence of different structures (central and peripheral) on latency, total and partial inhibition of the sympathetic activity are discussed.     

Cardiac sympathetic afferent stimulation augments the arterial chemoreceptor reflex in anesthetized rats.

Chronic heart failure (CHF) is well known to be associated with both an enhanced chemoreceptor reflex and an augmented cardiac "sympathetic afferent reflex" (CSAR). The augmentation of the CSAR may play an important role in the enhanced chemoreceptor reflex in the CHF state because the same central areas are involved in the sympathetic outputs of both reflexes. We determined whether chemical and electrical stimulation of the CSAR augments chemoreceptor reflex function in normal rats. Under anesthesia, renal sympathetic nerve activity (RSNA) and mean arterial pressure (MAP) were recorded. The chemoreceptor reflex was tested by unilateral intra-carotid artery bolus injection of potassium cyanide (KCN) and nicotine. We found that 1) left ventricular epicardial application of capsaicin increased the pressor responses and the RSNA responses to chemoreflex activation induced by both KCN and nicotine; 2) when the central end of the left cardiac sympathetic nerve was electrically stimulated, both the pressor and the RSNA responses to chemoreflex activation induced by KCN were increased; 3) pretreatment with intracerebroventricular injection of losartan (500 nmol) completely prevented the enhanced chemoreceptor reflex induced by electrical stimulation of the cardiac sympathetic nerve; and 4) bilateral microinjection of losartan (250 pmol) into the nucleus tractus solitarii (NTS) completely abolished the enhanced chemoreceptor reflex by epicardial application of capsaicin. These results suggest that both the chemical and electrical stimulation of the CSAR augments chemoreceptor reflex and that central ANG II, specially located in the NTS, plays a major role in these reflex interactions.     

Central neural respiratory response to carotid sinus nerve stimulation in newborns

During exposure to hypoxia newborns hypoventilate following a brief period of hyperventilation. Failure of integration of the afferent signals from peripheral O2 chemoreceptors due to immaturity of the central respiratory centers could explain this paradoxical respiratory response. To test this hypothesis we have utilized anesthetized, paralyzed, mechanically ventilated newborn piglets and lambs (less than 11 days) and old piglets (19-35 days). The vagus nerves were cut in each animal. Respiratory activity was quantified by integration of phrenic neural activity. A carotid sinus nerve (CSN) was isolated and electrically stimulated for periods of 1-6 min. In all three groups of animals respiratory activity was continuously elevated throughout the period of CSN stimulation. After CSN stimulation respiratory activity immediately declined about 25% from the stimulated value. Thereafter respiratory activity declined in an exponential fashion toward the initial control level of respiratory activity. The time constant of this latter decay was 84.2 s in the young piglets, 83.2 s in the old piglets, and 63.0 s in the lambs. These results indicate that the respiratory centers of newborn piglets and lambs can maintain integration of continuous afferent CSN activity. Further, the respiratory afterdischarge that follows CSN stimulus cessation is similar to that of adults. These studies indicate that, during periods of O2 sufficiency, the central respiratory centers of newborns respond in a qualitatively similar manner to CSN stimulation as do adult cats.     

离体颈动脉窦压力感受器研究方法的改进——窦内压的自动控制

目的:创建一套离体颈动脉窦压力感受器研究中窦内压力的自动控制系统。方法:制备颈动脉窦-窦神经标本并对其进行灌流。在该系统中,引入一个重要的可接受电脑指令的压力控制装置(PRE-U,Hoerbiger,Deutschland),用以钳制窦内压。通过比较压力指令和相应产生的窦内压来鉴定本压力控制系统的可靠性。结果:利用该系统可以准确实现脉动式、斜坡式、阶跃式等多种窦内压力控制模式,并证实记录到压力依赖性窦神经放电活动。结论:应用这套颈动脉窦内压力控制系统可以实现多种压力模式的控制。该系统为深入研究压力感受器机电换能机制提供了有用且灵活的压力控制方法。     

Intermittent hypoxia augments carotid body and ventilatory response to hypoxia in neonatal rat pups.

Carotid bodies are functionally immature at birth and exhibit poor sensitivity to hypoxia. Previous studies have shown that continuous hypoxia at birth impairs hypoxic sensing at the carotid body. Intermittent hypoxia (IH) is more frequently experienced in neonatal life. Previous studies on adult animals have shown that IH facilitates hypoxic sensing at the carotid bodies. On the basis of these studies, in the present study we tested the hypothesis that neonatal IH facilitates hypoxic sensing of the carotid body and augments ventilatory response to hypoxia. Experiments were performed on 2-day-old rat pups that were exposed to 16 h of IH soon after the birth. The IH paradigm consisted of 15 s of 5% O2 (nadir) followed by 5 min of 21% O2 (9 episodes/h). In one group of experiments (IH and control, n = 6 pups each), sensory activity was recorded from ex vivo carotid bodies, and in the other (IH and control, n = 7 pups each) ventilation was monitored in unanesthetized pups by plethysmography. In control pups, sensory response of the carotid body was weak and was slow in onset (approximately 100 s). In contrast, carotid body sensory response to hypoxia was greater and the time course of the response was faster (approximately 30 s) in IH compared with control pups. The magnitude of the hypoxic ventilatory response was greater in IH compared with control pups, whereas changes in O2 consumption and CO2 production during hypoxia were comparable between both groups. The magnitude of ventilatory stimulation by hyperoxic hypercapnia (7% CO2-balance O2), however, was the same between both groups of pups. These results demonstrate that neonatal IH facilitates carotid body sensory response to hypoxia and augments hypoxic ventilatory chemoreflex.