Stimulation of renal sympathetic activity by static contraction: evidence for mechanoreceptor-induced reflexes from skeletal muscle

Static muscular contraction in anesthetized animals has been firmly established to reflexly increase arterial pressure. Although group III and IV muscle afferents are known to be responsible for this reflex pressor response, there is no evidence that the stimulation of muscle mechanoreceptors, many of which are supplied by group III fibers, plays a role in causing this contraction-induced reflex effect. To provide this evidence, we recorded renal sympathetic nerve activity in chloralose-anesthetized cats while contracting the triceps surae muscles. We found that static contraction tripled renal nerve activity within three seconds of its onset, an increase that was abolished by cutting the L6 and S2 dorsal roots. On average, the contraction-induced increase in renal nerve activity was observed 0.8 +/- 0.1 seconds after the onset of this maneuver. In addition, intermittent tetanic contractions synchronized renal nerve discharge so that a burst of activity was evoked by each contraction. A similarly synchronized renal nerve discharge was evoked in paralyzed cats by electrical stimulation of the tibial nerve at five times motor threshold, a current intensity that activates group III afferents. We conclude that, in anesthetized animal preparations, mechanoreceptors with group III afferents contribute to the reflex stimulation of renal sympathetic outflow evoked by muscular contraction.

Occlusion of pressor responses to posterior diencephalic stimulation and muscular contraction

Although neural occlusion has been suggested to occur between the central and reflex mechanisms increasing arterial pressure, evidence consistent with this phenomenon is lacking. To assess the possibility of neural occlusion we recorded, in chloralose-anesthetized cats, the pressor responses to statically contracting the hindlimb muscles and to electrically stimulating histologically confirmed sites in the posterior hypothalamus and subthalamus. We also recorded the pressor responses to topical application of capsaicin onto the intestine and to stimulation of these diencephalic sites. The pressor responses to simultaneous static contraction and diencephalic stimulation were significantly smaller than the algebraic sum of the pressor responses to contraction and diencephalic stimulation evoked separately. Likewise, the pressor responses to simultaneous capsaicin application and diencephalic stimulation were significantly smaller than the algebraic sum of the responses evoked separately. High intensity stimulation of the L7 dorsal root or the diencephalic sites evoked pressor responses similar in magnitude to the algebraic sum of the two responses evoked separately; thus, the inability of the simultaneous maneuvers to evoke pressor responses that summed algebraically was not due to the fact that they caused a maximal effect. Our findings are consistent with the hypothesis that neural occlusion occurs during stimulation of the posterior diencephalon and static muscular contraction.

Stimulation of H fields of Forel decreases total lung resistance in dogs

Although there is considerable evidence that the H fields of Forel of the posterior diencephalon play an important role in the regulation of cardiovascular function, little is known about the role these areas play in the control of airway caliber. In chloralose-anesthetized paralyzed dogs, we used both electrical and chemical means to stimulate the H fields of Forel, while we monitored breath-by-breath changes in total lung resistance (TLR), a functional index of airway caliber. Electrical stimulation (200-250 microA, 80 Hz, 0.75 ms) of 82 histologically confirmed sites significantly decreased TLR from 9.2 +/- 0.4 to 7.9 +/- 0.4 cmH2O.l-1.s (P less than 0.01). The bronchodilation evoked by electrical stimulation was unaffected by beta-adrenergic blockade with propranolol but was abolished by cholinergic blockade with atropine. The increases in airway caliber evoked by stimulation were often accompanied by increases in phrenic nerve activity. Chemical stimulation of 21 of 82 sites with microinjections of DL-homocysteic acid (83 nl, 0.2 and 0.5 M), which stimulates cell bodies but not fibers of passage, also decreased TLR from 8.3 +/- 0.5 to 7.3 +/- 0.5 cmH2O.l-1.s (P less than 0.03). We conclude that stimulation of cell bodies in the H fields of Forel produces bronchodilation by withdrawal of cholinergic tone to airway smooth muscle.

Pressor reflex response to static muscular contraction: its afferent arm and possible neurotransmitters

Static muscular contraction has been shown to increase cardiovascular and ventilatory function in reflex manner. The sensory arm of this reflex arc is comprised of group III and IV muscle afferents. The discharge properties of these muscle afferents whose activation causes the pressor reflex response to contraction were investigated. Group III afferents were more responsive to mechanical stimuli, such as tendon stretch and probing their receptive fields than were group IV afferents. In contrast, group III afferents were less responsive to ischemic contraction than were group IV afferents. Equal percentages of group III and IV afferents were stimulated by potassium, lactic acid and arachidonic acid, each of which are metabolic products of contraction. Adenosine, phosphate and lactate, however, had no effect on the discharge of the afferents. Intrathecal injection of antagonists or antibodies to substance P and somatostatin attenuated the pressor response to contraction by about half, a finding that suggests a role for these 2 peptides in the spinal transmission of the reflex.

Effect of metabolic products of muscular contraction on discharge of group III and IV afferents

Static muscular contraction has been firmly established to reflexly increase cardiovascular and ventilatory function. Although group III and IV fibers with endings in muscle have been shown to comprise the afferent arm of this reflex arc, little is known about the nature of the contraction-induced stimulus causing the activation of these fibers. This stimulus has often been suggested to be a metabolic product of muscular contraction. We have therefore recorded the impulse activity of group III and IV afferents with endings in the triceps surae muscles of barbiturate-anesthetized cats while we injected into the femoral artery substances believed to be metabolic products of muscular contraction. We found that lithium and sodium lactate (400 mM; 1 ml) had little or no effect on the discharge of group III and IV afferents. Likewise, monobasic sodium phosphate (20 and 400 mM; 1 ml) and 2-chloroadenosine (50-100 micrograms) had only trivial effects on the discharge of these afferents. By contrast, lactic acid (25 and 400 mM; 1 ml) and arachidonic acid (0.5-2.0 mg) caused significant increases in the activity of group III and IV afferents. Most of the excitatory effect of arachidonic acid on the discharge of the afferents was prevented by indomethacin, a cyclooxygenase inhibitor. We conclude that of the substances tested in our experiments, lactic acid and some cyclooxygenase products, such as prostaglandins and thromboxanes, are the most likely to be responsible for any metabolic stimulation of group III and IV afferents during muscular contraction.

Attenuation of the reflex pressor response to muscular contraction by an antagonist to somatostatin

Although group III and IV fibers are known to compose the afferent pathway of the reflex arc causing the pressor response to static muscular contraction, little is known about the neurotransmitters released by these muscle afferents. Somatostatin might be one of these neurotransmitters because this peptide is found in the terminals of fine afferent fibers ending in the dorsal horn of the lumbar spinal cord. Therefore, in chloralose-anesthetized cats, the reflex pressor response to static contraction was examined before and after subarachnoid injections onto the lumbosacral cord of a peptide antagonist to somatostatin. We found that before giving the antagonist, the pressor response to contraction of the triceps surae muscles in 12 cats averaged 33 +/- 4 mm Hg, while 37 +/- 7 minutes after giving the antagonist, the pressor response averaged only 18 +/- 3 mm Hg (p less than 0.001). In contrast, the antagonist to somatostatin had no effect on either the pressor response to electrical stimulation of the cut central end of the sciatic nerve or the pressor response to stimulation of the posterior diencephalon. Furthermore, subarachnoid injection of a peptide antagonist to luteinizing hormone-releasing hormone had no effect on the reflex pressor response to static contraction. Our findings are consistent with the hypothesis that somatostatin plays a role in the spinal transmission of the contraction-induced pressor reflex arising from hind limb skeletal muscle.

Discharge properties of group III and IV muscle afferents: their responses to mechanical and metabolic stimuli

Static contraction of the hind limb muscles induced by electrical stimulation of the ventral roots has been firmly established to reflexly increase cardiovascular and ventilatory function. Moreover, Group III and IV afferents are known to compose the afferent arm of this reflex arc. The present experiments investigated the discharge properties of Group III and IV afferents whose activation is responsible for the pressor reflex response to static contraction. In general, we found that Group III afferents were more responsive to mechanical stimuli, such as distortion of their receptive fields and tendon stretch, than were Group IV afferents. In contrast, Group IV afferents were more responsive to ischemic contraction than were Group III afferents. In addition, equal percents of Group III and IV afferents were found to be stimulated by increasing interstitial potassium to levels that were similar to those found during muscular contraction. The afferents' response to potassium adapted within seconds, while the interstitial concentration of this ion remained elevated for several minutes. This rapidly adapting response casts doubt on the effectiveness of potassium as the metabolite that signals blood supply and demand in a working muscle are improperly matched.

Stimulation of the caudal ventrolateral medulla decreases total lung resistance in dogs

Although the role played by the caudal ventrolateral medulla in the regulation of the cardiovascular system has been extensively investigated, little is known about the role played by this area in the regulation of airway caliber. Therefore, in alpha-chloralose-anesthetized dogs, we used both electrical and chemical means to stimulate the caudal ventrolateral medulla while we monitored changes in total lung resistance breath by breath. We found that electrical stimulation (25 microA) of 26 sites in this area significantly decreased total lung resistance from 7.1 +/- 0.4 to 5.7 +/- 0.3 cmH2O.1-1.s (P less than 0.001). The bronchodilation evoked by electrical stimulation was unaffected by beta-adrenergic blockade but was abolished by cholinergic blockade. In addition, chemical stimulation of seven sites in the caudal ventrolateral medulla with microinjections of DL-homocysteic acid (0.2 M; 66 nl), which stimulates cell bodies but not fibers of passage, also decreased total lung resistance from 8.3 +/- 1.1 to 6.5 +/- 0.8 cmH2O.l-1.s (P less than 0.01). In contrast, microinjections of DL-homocysteic acid into the nucleus ambiguus (n = 6) increased total lung resistance from 7.5 +/- 0.5 to 9.2 +/- 0.4 cmH2O.l-1.s (P less than 0.05). We conclude that the caudal ventrolateral medulla contains a pool of cell bodies whose excitation causes bronchodilation by withdrawing cholinergic input to airway smooth muscle.

Inhibition of aortic chemoreceptor discharge by pressor response to muscular contraction

We have examined the effect of static contraction of the hindlimb muscles on the discharge of aortic chemoreceptors in chloralose-anesthetized cats. The responses of the chemoreceptors to contraction were dependent on the arterial pressure response to this maneuver. When contraction reflexly evoked a pressor response of at least 20 mmHg, the discharge of 26 chemoreceptors was reduced from control levels by 53% (P less than 0.01). The contraction-induced inhibition of chemoreceptor discharge was prevented by phentolamine, an alpha-adrenergic antagonist that also attenuated the contraction-induced pressor response. In addition, the inhibition evoked by contraction was simulated by injection of phenylephrine and inflation of an aortic balloon, both of which evoked pressor responses. However, when contraction failed to significantly change arterial pressure, the discharge of 20 aortic chemoreceptors was not significantly changed from control levels. We conclude that the reflex pressor response to static contraction inhibits the discharge of aortic chemoreceptors. This inhibition of discharge needs to be considered when interpreting the effects of aortic barodenervation on the cardiovascular responses to exercise.

Acetylstrophanthidin does not enhance the reflex pressor response to static muscular contraction

Cardiac glycosides have been shown to enhance the sensitivity of the reflex cardiovascular responses to stimulation of mechanoreceptors in the heart, carotid sinus and aorta. Little is known, however, about the effect of glycosides on the reflex cardiovascular responses to the contraction-induced stimulation of afferent endings in hindlimb skeletal muscle. We therefore examined the reflex heart rate and arterial pressure responses to static contraction of the hindlimb muscles before and after femoral arterial injection of two doses of acetylstrophanthidin (20 and 80 micrograms/kg). Neither of the two doses enhanced the reflex cardiovascular responses to contraction, although the larger of the two significantly increased femoral venous potassium concentrations from 3.4 +/- 0.2 to 3.8 +/- 0.1 mM. Although injection of the two doses as well as injection of a very large dose of acetylstrophanthidin (400 micrograms/kg) increased baseline mean arterial pressure, these effects were probably caused by the vasoconstrictor action of this agent and not by a chemoreflex, because the increase was not attenuated by denervation of the hindlimb.

Caudal ventrolateral medullary cells responsive to muscular contraction

The pressor reflex evoked by muscular contraction (exercise pressor reflex) is held to be an important mechanism in producing the cardiovascular adjustments to static exercise. Recent experiments using lesioning and metabolic labeling methods have indicated that the caudal ventrolateral medulla may be a key integrative site for the reflex evoked by muscular contraction induced by ventral root stimulation. Therefore, we sought to determine whether cells in this region could be associated with the cardiovascular reflex accompanying muscular contraction through analysis of their discharge characteristics. Eighty cells were characterized as to their response to ventral root stimulus-induced static muscular contraction, intra-arterial capsaicin (selective groups III and IV stimulus), and mechanical probing. The cells' receptive fields were also determined by mechanical probing. The receptive fields were usually large, often including all four limbs and the trunk. Four response patterns were observed to static contractions: a brisk initial discharge followed by a gradual return toward control levels (slowly adapting), a brief onset and cessation response, a brief inhibition followed by a slowly adapting discharge, and inhibition alone. Virtually all cells tested were responsive to capsaicin. Histological analysis verified the position of the recorded cells. It is suggested that the cells most likely to participate in the pressor response to muscular contraction were those cells in the general region of the lateral reticular nucleus which responded with an initial and sustained discharge and the cells that were inhibited in the region of the nucleus ambiguus (possible inhibition of vagal outflow).

Stimulation of groups III and IV phrenic afferents reflexly decreases total lung resistance in dogs

Little is known about the reflex effect on airway caliber evoked by stimulation of phrenic afferents. Therefore, in chloralose-anesthetized, paralyzed dogs, we recorded airflow, airway pressure, arterial pressure, and heart rate while electrically stimulating a phrenic nerve. Total lung resistance was calculated breath by breath. The phrenic nerve was stimulated at 3, 5, 20, 70, 140, and 200 times motor threshold and the compound action potential was recorded. Stimulation of the phrenic nerve at three and five times threshold, which activated groups I, II, and a few group III fibers, had no effect on any of the variables measured. Stimulation at 20 times threshold, which activated many group III fibers and groups I and II fibers, reflexly decreased resistance. Stimulation at 70, 140, and 200 times threshold, which activated groups I-IV fibers, evoked progressively greater decreases in lung resistance. The reflex bronchodilation evoked by phrenic nerve stimulation was unaffected by propranolol or phentolamine but was abolished by atropine. We conclude that activation of groups III and IV phrenic nerve afferents reflexly decreased total lung resistance by withdrawing cholinergic tone to airway smooth muscle.

Immunoneutralization of substance P attenuates the reflex pressor response to muscular contraction

We previously reported that subarachnoid injection of a peptide antagonist to substance P attenuated by half the reflex pressor response to static muscular contraction. Subsequently, some of the peptide antagonists to substance P have been found to possess local anesthetic effects. Therefore, we have repeated our experiments using a substance P antiserum, which was shown to be without local anesthetic effect. We found that intrathecal injection of the antiserum attenuated by more than half the reflex pressor response to static contraction of the triceps surae muscles of cats.

Reflex cardiovascular responses caused by stimulation of pulmonary C-fibers with capsaicin in dogs

The purpose of these studies was to determine quantitatively the reflex cardiovascular responses to stimulation of the pulmonary C-fibers in dogs. We used a preparation in which the airway, pulmonary artery, and the pulmonary veins to the left lung were cannulated in situ. Ventilation and perfusion of the right lung maintained the animal in relatively normal homeostasis. Capsaicin, a decylenic acid amide of vanillylamine that selectively stimulates nerve endings of unmyelinated fibers (C-fibers), was injected into the left pulmonary artery in 5-ml boluses. Maximal reflex responses were obtained with concentrations as low as 0.8-1.6 X micrograms-1 X kg-1. Heart rate, hindlimb resistance, and left ventricular contractility were lowered transiently (the maximal responses showing declines of 40, 13, and 15.2%, respectively). As a result of these changes, combined with vasodilation in other resistance vessels, cardiac output fell 28% and blood pressure fell 35%. Interrupting the afferent neural pathway by severing the ipsilateral cervical vagus nerve eliminated these responses, confirming the distribution of their reflex origin. Although the role of these reflexes in homeostasis has not been decided, the results of this study suggest that the lungs of dogs, if appropriately stimulated, potentially can exert a major inhibitory influence on the neural regulation of cardiovascular function.

Hindlimb muscular contraction reflexly decreases total pulmonary resistance in dogs

We have previously shown that contraction of the gracilis muscles of anesthetized dogs reflexly relaxes tracheal smooth muscle. We have also found that electrical stimulation of these afferents decreases total pulmonary resistance (TPR), a calculation that provides a functional index of airway caliber. Despite these findings, we have yet to show that muscular contraction reflexly decreases TPR. Therefore, in 11 alpha-chloralose-anesthetized dogs, we contracted the hindlimb muscles by electrically stimulating the L6-L7 ventral roots while measuring TPR breath by breath. We found that static contraction decreased TPR from 12.6 +/- 1.1 to 10.4 +/- 0.9 cmH2O X l-1 X s (P less than 0.05). This decrease was reflex in origin because it was prevented by section of the spinal roots innervating the working hindlimb. Repetitive twitch contractions (5 Hz) also reflexly decreased TPR, but the effect was smaller than that evoked by static contraction. The reflex decreases in TPR evoked by contraction were unaffected by propranolol but were abolished by atropine. We conclude that muscular contraction dilates the airways by a reflex mechanism whose efferent arm consists of a withdrawal of cholinergic input to airway smooth muscle.

Effect of PEEP on discharge of pulmonary C-fibers in dogs

Although positive end-expiratory pressure (PEEP) is believed to depress cardiac output and arterial pressure by compressing the vena cava and the heart, it is unclear whether PEEP also depresses these variables by a reflex arising from an inflation-induced stimulation of pulmonary C-fibers. We therefore recorded the impulse activity of 17 pulmonary C-fibers in barbiturate-anesthetized dogs with closed chests, while we placed the expiratory outlet of a ventilator under 5-30 cmH2O. Increasing PEEP in a ramp-like manner stimulated 12 of the 17 pulmonary C-fibers, with activity increasing from 0.0 +/- 0.1 to 0.9 +/- 0.2 imp/s when end-expiratory pressure equaled 15 cmH2O. When PEEP was increased in a stepwise manner to 15-20 cmH2O and maintained at this pressure for 15 min, pulmonary C-fibers increased their firing rates, but the effect was small averaging 0.2-0.3 imp/s after the 1st min of this maneuver. We conclude that pulmonary C-fibers are unlikely to be responsible for causing much of the decreases in cardiac output and arterial pressure evoked by sustained periods of PEEP in both patients and laboratory animals. These C-fibers, however, are likely to be responsible for causing the reflex decreases in these variables evoked by sudden application of PEEP.

Pressor reflex evoked by muscular contraction: contributions by neuraxis levels

The pressor reflex evoked by muscular contraction (exercise pressor reflex) is one important model of cardiovascular adjustments during static exercise. The central nervous system (CNS) structures mediating this reflex have remained largely obscure. Therefore, we examined the contribution of selected levels of the neuraxis in mediating the pressor reflex evoked by muscular contraction from stimulation of ventral roots. Decerebrate cats exhibited larger pressor reflexes than those found in intact alpha-chloralose-anesthetized cats, a difference more apparent at low (5 Hz or repeated twitch) rather than at high (50 Hz or tetanic) stimulus frequencies. Although a depressor response to 5-Hz stimulation was observed in the intact anesthetized cats, it appeared to be primarily due to anesthetic level, since a depressor response was not observed in decerebrate animals (nonanesthetized). Cerebellectomy produced no changes in the reflexes of the decerebrate animal. Further transection of the neuraxis (caudal to the midcollicular level) attenuated the exercise pressor reflex. The spinal cat demonstrated slight evidence of exercise pressor reflex activity. These results provide clarification as to representation of this pressor reflex within the CNS and establish the reflex's characteristics at several levels of neuraxis integration.

Reflex tracheal contraction evoked in dogs by bronchodilator prostaglandins E2 and I2

Bronchodilator prostaglandins E2 and I2 may cause airway irritation and bronchoconstriction in human subjects. These experiments were designed to test the hypothesis that this paradoxical bronchoconstriction is a vagal reflex triggered by stimulation of airway afferents. We recorded smooth muscle tension in an innervated upper tracheal segment in anesthetized dogs and injected prostaglandins into the general circulation or into a bronchial artery or administered them as aerosol to the lungs. Prostaglandins usually caused tracheal contraction, which survived vagal cooling to 5-7 degrees C but was abolished at 0 degrees C. Vagally mediated tracheal contraction was also evoked when prostacyclin was injected into the pulmonary circulation of dogs whose pulmonary and systemic circulations were independently pump perfused. Recordings of afferent vagal impulses indicated that bronchial arterial injection of prostaglandins stimulated bronchial C-fibers; aerosols of prostaglandin stimulated pulmonary and bronchial C-fibers and C-fibers in extrapulmonary airways. We postulate that in susceptible human subjects concentrations of these prostaglandins too low to have direct bronchodilator effects may cause reflex bronchoconstriction by stimulating afferent vagal C-fibers in the lower airways.

Attenuation of the reflex pressor response to muscular contraction by a substance P antagonist

In chloralose-anesthetized cats, we found that D-Pro2-D-Phe7-D-Trp9-substance P (40-100 micrograms), injected intrathecally, reduced the reflex pressor response to static muscular contraction by more than half.

Increasing gracilis muscle interstitial potassium concentrations stimulate group III and IV afferents

Static muscular contraction reflexly increases arterial blood pressure and heart rate. One possible mechanism evoking this reflex is that potassium accumulates in the interstitial space of a working muscle to stimulate group III and IV afferents whose activation in turn evokes a pressor response. The responses of group III and IV muscle afferents to increases in interstitial potassium concentrations within the range evoked by static contraction are unknown. Thus we injected potassium chloride into the gracilis artery of anesthetized dogs while we measured both gracilis muscle interstitial potassium concentrations with potassium-selective electrodes and the impulse activity of afferents in the gracilis nerve. We found that increasing interstitial potassium concentrations to levels similar to those seen during static contraction stimulated 14 of 16 group III and 29 of 31 group IV afferents. The responses of the afferents to potassium were concentration dependent. The typical response to potassium consisted of a burst of impulses, an effect that returned to control firing rates within 26 s, even though interstitial potassium concentrations remained elevated for several minutes. Although our results suggest that potassium may play a role in initiating the reflex cardiovascular responses to static muscular contraction, the accumulation of this ion does not appear to be solely responsible for maintaining the pressor response for the duration of the contraction.

Stimulation of group III and IV muscle afferents reflexly decreases total pulmonary resistance in dogs

Although previous investigations have shown that stimulating group III and IV afferents reflexly decreased transverse tension from the trachealis muscle, these measurements provided no functional information about airway caliber. We therefore electrically stimulated gracilis muscle afferents in paralyzed, chloralose anesthetized dogs while recording total pulmonary resistance breath by breath. In addition, we recorded compound action potentials to determine which afferents were stimulated by current intensities of 3, 5, 20, 70 and 200 times motor threshold. We found that stimulating (20 Hz) the nerves at 3 times threshold, a current intensity which activated only group I and II afferents, had no effect on total pulmonary resistance, whereas stimulating the nerves at 5, 20 and 70 times threshold, current intensities which activated group I, II and III afferents, significantly decreased this variable. Stimulating the nerves at 200 times threshold, a current intensity which activated group IV as well as group I, II and III afferents, decreased total pulmonary resistance significantly more than did stimulating the nerves at 5, 20 or 70 times threshold. In addition stimulating the nerves at 200 times threshold but at frequencies of 2 and 5 Hz significantly decreased total pulmonary resistance. The decrease in total pulmonary resistance evoked by electrically stimulating the nerves at 200 times threshold was unaffected by propranolol but was abolished by atropine methylnitrate. We conclude that stimulating group III and IV gracilis muscle afferents in dogs reflexly decreases total pulmonary resistance, an effect due to the withdrawal of a tonic cholinergic input to the airways.

Activation of visceral thin-fiber afferents increases respiratory output in cats

Respiratory responses to chemical activation of thin-fiber afferents from the stomach and the gallbladder were measured in anesthetized cats. Capsaicin or bradykinin applied to the serosal surface of either the stomach or the gallbladder elicited increases in breathing and phrenic nerve activity. Transection of the cervical vagi or the carotid sinus nerves had no effect on these responses. However, the respiratory responses to visceral stimulation were abolished by bilateral transection of the splanchnic nerves. We conclude that activation of thin-fiber afferents from the stomach and gallbladder causes a reflex increase in respiratory output. The initial afferent limb of this reflex is via the splanchnic nerves.

Effects of static and rhythmic twitch contractions on the discharge of group III and IV muscle afferents

Although both static and rhythmic twitch contractions of the hindlimb muscles of anaesthetised cats have been shown to reflexly evoke pressor responses, the increase in arterial pressure evoked by the former type of contraction has been shown to be substantially larger than that evoked by the latter. We have therefore recorded the impulse activity of single group III and IV muscle afferents, whose activation reflexly increases arterial pressure, while we both statically and rhythmically twitch-contracted the triceps surae muscles of anaesthetised cats. We found that group III afferents (n = 17) discharged significantly more impulses in response to static contraction than in response to rhythmic contraction. By contrast, group IV afferents (n = 18) fired approximately the same number of impulses in response to the two types of contraction. In addition, we found that many of the group III but only a few of the group IV afferents displayed discharge properties suggestive that these afferents were mechanoreceptors. We conclude that the discharge of group III afferents are likely to be responsible for the difference in the magnitudes of the reflex pressor responses evoked by static and rhythmic contraction.

Arterial pressure responses to increasing interstitial potassium in hindlimb muscle of dogs

Static contraction of hindlimb skeletal muscle is known to increase reflexly arterial pressure and heart rate. Potassium is known to be released by the working muscle and is thought to activate the afferents responsible for the reflex cardiovascular responses to muscular contraction. However, it is not known whether potassium, at interstitial concentrations within the range observed during static contraction, is capable of stimulating these afferents. Thus we injected potassium into the gracilis artery of chloralose-anesthetized dogs while we measured interstitial potassium concentrations in the gracilis muscle with potassium-selective electrodes. In 16 dogs, we found that potassium injections, which increased interstitial potassium concentrations by 4.7 +/- 0.3 mM, increased mean arterial pressure by 18 +/- 3 mmHg and heart rate by 12 +/- 8 beats/min; cutting the obturator nerve abolished these increases. These heart rate and blood pressure responses were of short duration (20 +/- 7 s), even though interstitial potassium remained elevated for a period of several minutes. In 5 of the 16 dogs, static contraction of the gracilis muscle for 60 s increased interstitial potassium concentration by 4.3 +/- 0.3 mM. Our data are consistent with the hypothesis that potassium plays a role in causing the reflex cardiovascular responses to static muscular contraction.

Effects of bradykinin and capsaicin on endings of afferent fibers from abdominal visceral organs

Stimulation of sensory endings in abdominal visceral organs with capsaicin or bradykinin reflexly increases heart rate, blood pressure, and myocardial contractility through afferent pathways in splanchnic nerves. To determine the afferent fiber types stimulated, we recorded impulses in the right splanchnic nerve in 12 anesthetized cats after either injecting capsaicin (50-200 micrograms) or bradykinin (6.5-20 micrograms) into the descending thoracic aorta or applying pledgets soaked with these chemicals to a visceral organ. We studied 26 A- and 23 C-fibers, each with one receptive field in the mesentery, stomach, duodenum, jejunum, ileum, pancreas, liver, gallbladder, or porta hepatis. Endings of C-fibers generally were mechanically insensitive, whereas endings of A-fibers were mechanically sensitive. After a latency of 10.7 +/- 3.3 s, capsaicin increased the activity of 10 of 26 A-fibers from 2.0 +/- 0.9 to 9.9 +/- 2.6 impulses/s and 23 of 23 C-fibers from 0.2 +/- 0.1 to 13.0 +/- 1.6 impulses/s after a latency of 3.3 +/- 0.9 s. Bradykinin increased the activity of 15 of 26 A-fibers from 2.6 +/- 0.9 to 7.4 +/- 1.5 impulses/s after a latency of 17.0 +/- 1.7 s and 16 of 22 C-fibers from 0.4 +/- 0.2 to 4.7 +/- 1.2 impulses/s after a latency of 19.0 +/- 1.9 s. Capsaicin stimulated significantly more C- than A-fibers (P less than 0.001) and a significantly greater fraction of C-fibers than did bradykinin (P less than 0.007). We conclude that stimulation of splanchnic C-fiber afferents by capsaicin and both A- and C-fiber afferents by bradykinin is primarily responsible for the reflex cardiovascular responses caused by these chemicals.

Effect of ischemia on responses of group III and IV afferents to contraction

Static contraction of the hindlimb muscles of cats reflexly increases cardiovascular function, an effect that is potentiated by occlusion of the arterial supply to the working muscles. Although group III and IV afferents are known to be stimulated by and to cause the reflex cardiovascular responses to static muscular contraction, little is known about the responses of these afferents to static contraction when the arterial supply to a working muscle is occluded. We therefore recorded the impulse activity of 24 group III afferents and 30 group IV afferents with endings in the triceps surae while we statically contracted this muscle group, both when the abdominal aorta was occluded and when it was patent. A chi 2 analysis revealed that ischemia increased the responses to static contractions of a significantly higher percentage of group IV afferents than group III afferents (46.7% vs. 12.5%, respectively; P less than 0.02). In addition, two patterns of responses to ischemic contraction were observed. The first pattern was displayed by afferents (n = 10) that were stimulated by nonischemic contraction but were stimulated more by ischemic contraction. The second pattern was displayed by afferents (n = 7) that were not stimulated by nonischemic contraction but were stimulated by ischemic contraction. We conclude that afferents displaying both patterns are likely to contribute to the reflex cardiovascular responses to ischemic contraction.

Activation of caudal brainstem cell groups during the exercise pressor reflex in the cat as elucidated by 2-[14C]deoxyglucose

Cell groups of the caudal brainstem were labeled with 2-[14C]deoxyglucose during the pressor response evoked by contraction of hindlimb muscles (exercise pressor reflex). The nuclear groups which were labeled in excess of control levels included: the lateral reticular nucleus, the inferior olive (medial accessory olive), and the lateral tegmental field (adjacent to the lateral reticular nucleus).

Effect on arterial pressure of rhythmically contracting the hindlimb muscles of cats

Although static contraction of the hindlimb muscles of anesthetized cats is known to reflexly increase arterial pressure and heart rate, the cardiovascular effects of rhythmic contractions of these muscles is unclear. To help clarify this issue, we determined, in chloralose-anesthetized cats, the effects on arterial pressure and heart rate of rhythmically contracting the hindlimb muscles at a frequency of 5 Hz. In addition, we determined the effect of rhythmic contractions on the impulse activity of group III and IV muscle afferents whose activation is known to increase cardiovascular function. We found that rhythmic contractions increased arterial pressure (from 108 +/- 8 to 134 +/- 9 mmHg; P less than 0.05) and heart rate (from 192 +/- 13 to 208 +/- 10 beats/min; P less than 0.05) in 10 cats and decreased arterial pressure (from 107 +/- 8 to 93 +/- 9 mmHg; P less than 0.05) but did not change heart rate in 9 other cats. The increases were reflex, because they were prevented by cutting the spinal roots innervating the contracting hindlimb. The decreases, however, were not reflex, because they persisted after spinal root section. The differences in the arterial pressure responses to rhythmic contractions may have been partly due to individual differences in the level of anesthesia, because in three cats the pressor responses to this maneuver were converted to depressor responses after giving the cats additional chloralose. Rhythmic contractions of the triceps surae muscles stimulated 8 of 10 group III afferents and 9 of 16 group IV afferents. We conclude that rhythmic contraction is capable of reflexly increasing cardiovascular function in cats provided that the effect is not depressed by anesthesia.

Chemical activation of group I and II muscle afferents has no cardiorespiratory effects

Although stimulation of group III and IV muscle afferents is known to cause reflex changes in cardiorespiratory function, it has not been resolved whether group I and II afferents contribute to this reflex activation. Therefore, we measured the effects of intra-arterial nonparalyzing doses of succinylcholine (50-100 micrograms/kg) on the firing of muscle afferents from the gastrocnemius muscle in one group of cats, and heart rate, blood pressure, and integrated phrenic nerve activity in a second group of cats. In nonparalyzed cats, succinylcholine injections caused muscular fasciculations and firing of all four groups of muscle afferents. However, succinylcholine stimulated only group I and II afferents after paralysis with gallamine triethiodide. Succinylcholine caused increases in blood pressure, heart rate, and phrenic nerve activity before paralysis. After paralysis, succinylcholine had no effects on any of the cardiorespiratory measures. We conclude that activation of only group I and II afferent fibers from the gastrocnemius muscle has no reflex effects on blood pressure, heart rate, or phrenic nerve activity. These afferents, therefore, are unlikely to play a role in increasing cardiorespiratory function during exercise.

Muscular contraction reflexly relaxes tracheal smooth muscle in dogs

Although contraction of hindlimb skeletal muscle is well known to reflexly increase ventilation, heart rate and arterial pressure, little is known about the reflex effect of this maneuver on airway smooth muscle tone. Therefore, in chloralose-anesthetized dogs, we recorded transverse tension from the trachealis muscle while we contracted both gracilis muscles by electrically stimulating the gracilis nerves at 5 and 40 Hz. In 11 of the 13 dogs studied, static (40 Hz) contraction decreased tracheal tension, whereas in the remaining 2 dogs, static contraction increased tension. In 9 of 11 dogs, rhythmic (5 Hz) contraction decreased tracheal tension, whereas in the remaining 2, this maneuver increased tension. The changes in tracheal tension induced by stimulating the gracilis nerves were abolished by paralyzing the dogs and were restored, for the most part, after paralysis had dissipated. In addition, the contraction-induced changes in tension were not present when the gracilis muscles were contracted by stimulating the cut peripheral ends of the gracilis nerves. We conclude that muscular contraction reflexly relaxes tracheal smooth muscle in most dogs.

Stimulation of splanchnic afferents reflexly relaxes tracheal smooth muscle in dogs

Although chemical stimulation of abdominal visceral afferents has been shown to reflexly increase cardiovascular and ventilatory function, the effect of stimulating these afferents on airway smooth muscle is unknown. Therefore, we recorded transverse smooth muscle tension from an innervated segment of trachea in chloralose-anesthetized dogs while we topically applied capsaicin (200 micrograms/ml) and bradykinin (0.01-10 micrograms/ml) to the serosal surfaces of the stomach, small intestine, and gallbladder. Application of these irritant substances to the stomach and small intestine decreased tracheal tension and increased mean arterial pressure. However, application of capsaicin and bradykinin to the gallbladder had only small effects on both of these variables. Cutting the splanchnic nerves abolished or greatly attenuated the decreases in tension and increases in mean arterial pressure, whereas cutting the vagi had no effect on them. We conclude that stimulation of splanchnic afferent endings in the stomach and small intestine reflexly relaxes tracheal smooth muscle in dogs. This effect may be one component of the constellation of autonomic responses reflexly evoked by abdominal visceral pain and inflammation.

Effects of static muscular contraction on impulse activity of groups III and IV afferents in cats

Static contraction of the hindlimb muscles, induced by electrical stimulation of the ventral roots, reflexly increases arterial blood pressure and heart rate. Although stimulation of groups III and IV muscle afferents is believed to cause these reflex increases, the responses of these afferents to a level of static contraction that increases arterial pressure have not yet been determined. Therefore, in barbiturate-anesthetized cats, afferent impulses arising from endings in the gastrocnemius muscle were recorded from the L7 or S1 dorsal roots, while the cut peripheral end of the L7 ventral root was stimulated. In addition, the effects of capsaicin (100-200 micrograms) and bradykinin (25 micrograms) on the activity of the groups III and IV afferents stimulated by contraction were examined. Contraction of the gastrocnemius muscle to a level equal to or greater than that needed to cause a pressor response stimulated 12 of 19 (63%) group III afferents and 13 of 19 (68%) group IV afferents. However, the discharge patterns of the group III afferents stimulated by contraction were very different from those of the group IV fibers. No relationship was found between those fibers stimulated by contraction and those stimulated by chemicals. Our results suggest that although both groups III and IV muscle afferents contribute to the reflex cardiovascular increases evoked by static exercise, group III fibers were likely to be stimulated by the mechanical effects of muscular contraction, whereas at least some group IV fibers were likely to be stimulated by the metabolic products of muscular contraction.

Atropine prevents the reflex tracheal relaxation arising from the stimulation of intestinal and skeletal muscle afferents in dogs

Using cholinergic and beta-adrenergic antagonists, we characterized the efferent arms of two reflex arcs that relax tracheal smooth muscle in dogs. The reflex arcs investigated were activated by the capsaicin-induced stimulation of afferent endings in the intestine and in the hindlimb. We found that the reflex tracheal relaxations were due to a withdrawal of a tonic cholinergic input. Beta-adrenergic pathways played little role in causing these reflex responses.

Anatomical localization of the cells of origin of efferent fibers in the superior laryngeal and recurrent laryngeal nerves of dogs

Using horseradish peroxidase, we identified the cells of origin of motor fibers in the superior laryngeal and recurrent laryngeal nerves of dogs. Cells giving rise to fibers in the superior laryngeal nerve were found in the dorsal motor nucleus and the nucleus ambiguus, whereas cells giving rise to fibers in the recurrent laryngeal nerve were found in the nucleus ambiguus and nucleus retroambigualis, but usually not in the dorsal motor nucleus.

Responses to inflation of vagal afferents with endings in the lung of dogs

In dogs, inflating the lungs to pressures of 9 cm H2O or less reflexly increases heart rate, whereas inflating the lungs to pressures of 10-30 cm H2O reflexly decreases heart rate. The afferent fibers responsible for the cardioacceleration travel in the vagus nerves and are believed to be pulmonary stretch receptors, whereas the afferent responsible for the deceleration also travel in the vagus nerves, but are believed to be lung C-fibers. To identify the afferents responsible for these effects, we recorded the impulse activity of vagal afferents with endings in the left lung, while we slowly inflated that lung to 30-45 cm H2O. We found that 12 slowly adapting receptors fired at significantly lower inflation pressures than did 10 rapidly adapting receptors (5.8 +/- 1.5 vs. 13.5 +/- 2.2 cm H2O, respectively). We also found that 13 pulmonary C-fibers fired at significantly lower inflation pressures than did 10 bronchial C-fibers (16.4 +/- 1.8 vs 26.5 %/- 2.9 cm H2O, respectively). We conclude that slowly adapting receptors are likely to be responsible for the cardioacceleration evoked by low levels of inflation, and that both pulmonary and bronchial C-fibers are likely to be responsible for the cardiodeceleration evoked by high levels of inflation.

Reflex relaxation of tracheal smooth muscle by thin-fiber muscle afferents in dogs

Although the reflex cardiovascular and ventilatory responses evoked by stimulation of groups III and IV muscle afferents have been extensively investigated, less is known about the effects of stimulation of these afferents on airway caliber. Therefore, in 11 chloralose-anesthetized dogs, we recorded transverse smooth muscle tension from an innervated segment of the trachea, while we stimulated groups III and IV muscle afferents with capsaicin and bradykinin. Injection of both substances into the arterial supply of the skinned hindlimb evoked dose-dependent decreases in tracheal tension, whereas injection into the femoral vein either increased tension or had no effect on it. Injection of capsaicin and bradykinin into the arterial supply of the gracilis muscle also decreased tracheal tension. In addition, cutting the sciatic, gracilis, and femoral nerves abolished the decreases in tracheal tension caused by injection of capsaicin and bradykinin into the arterial supply of the hindlimb. We conclude that chemical stimulation of groups III and IV muscle afferents causes reflux relaxation of tracheal smooth muscle in dogs.

Tracheal contraction and relaxation initiated by lung and somatic afferents in dogs

Capsaicin injected into the right heart of dogs causes reflex bronchoconstriction by stimulating pulmonary C-fibers, but injected into the left heart it is said to have little effect even though it stimulates bronchial C-fibers, which are known to cause contraction of airway smooth muscle. Attempting to resolve this apparent contradiction, we recorded smooth muscle tension in an innervated tracheal segment in anesthetized dogs and examined the reflex effects of injecting capsaicin intravascularly at different sites. Right atrial injection of capsaicin (10 micrograms/kg) caused tracheal contraction, as did bronchial arterial injection (0.15-5.0 micrograms); left atrial injection (10 micrograms/kg), however, caused relaxation or slight contraction, or a combination of the two. Contraction but not relaxation was abolished by cutting or cooling (0 degree C) the cervical vagus nerves. Femoral arterial injection (10-100 micrograms) caused tracheal relaxation, which was abolished by cutting hindlimb nerves. We conclude that both pulmonary and bronchial C-fibers evoke tracheal contraction, but when capsaicin is injected into the left atrium any effects of stimulating bronchial C-fibers are masked by the reflex action of somatic afferents, which cause tracheal relaxation.

Effects of capsaicin and bradykinin on afferent fibers with ending in skeletal muscle

Capsaicin, injected into the arterial supply of the skinned hindlimb of dogs, evokes reflex increases in cardiovascular function. Moreover, the cardiovascular reflexes evoked by capsaicin are very similar to those evoked by static exercise. The afferent fibers initiating these reflex increases have not been identified electrophysiologically, although their endings are believed to be located in skeletal muscle. We have, therefore, attempted to determine which afferent fibers are stimulated by capsaicin. In anesthetized dogs, we recorded impulses from afferent fibers with endings in either the gastrocnemius or gracilis muscles and injected capsaicin (10-30 microgram/kg) into the abdominal aorta. Capsaicin stimulated 24 of 34 group IV (C fiber) endings, but only 5 of 19 group III (A delta fiber) endings. By contrast, bradykinin (0.5-1.5 microgram/kg) stimulated 17 of 33 group IV endings and 9 of 19 group III endings. Impulse activity for the 24 group IV afferents stimulated by capsaicin increased from 0.7 +/- 0.1 to a peak of 9.3 +/- 1.4 imp/sec. Firing started 6 +/- 1 seconds after injection and remained above control levels for 24 +/- 5 seconds. Capsaicin had no significant effect on the firing rate of 30 group I and II muscle afferents. Our results suggest that group IV muscle afferents are primarily responsible for causing the reflex increases in cardiovascular function evoked by injecting capsaicin into the arterial supply of the skinned hindlimb of dogs. Moreover, capsaicin is likely to be a useful pharmacological tool with which to determine the reflex autonomic effects caused by stimulation of group IV muscle afferents.

Reflex tracheal contraction induced by stimulation of bronchial C-fibers in dogs

Bradykinin stimulates the afferent vagal endings of bronchial C-fibers but has little effect on other pulmonary vagal afferents. In anesthetized dogs with open chest, we recorded transverse tension in the posterior wall (trachealis muscle) of an upper cervical tracheal segment and stimulated bronchial C-fibers selectively by injecting bradykinin (19 ng-3 microgram) into a bronchial artery. The recurrent and pararecurrent laryngeal nerves were cut so that the superior laryngeal nerves provided the motor supply to the segment. Bradykinin caused a dose-dependent increase in tracheal muscle tension and often a conspicuous decrease in heart rate, which were abolished by vagotomy or administration of atropine. Injection of bradykinin still evoked tracheal contraction when myelinated lung afferents were blocked by cooling the midcervical vagi to 7 degrees C, but contraction was abolished when unmyelinated lung afferents were blocked by cooling to 0-1 degrees C, the effects of cooling being reversible. Our results indicate that stimulation of bronchial C-fibers, like that of pulmonary C-fibers, evokes reflux contraction of airway smooth muscle and reflex cardiac slowing.

Operational sensitivity and acute resetting of aortic baroreceptors in dogs

Stimulus-response curves of aortic baroreceptors constructed by alternately increasing and decreasing pressure from a normal baseline or set-point differ from curves constructed by varying pressure in one direction only from an abnormally high or low pressure. In anesthetized dogs we recorded impulses from aortic baroreceptors with myelinated fibers, using a pressurized reservoir to control mean aortic blood pressure (MABP). After setting MABP to a baseline of 100 mm Hg (normal MABP in unanesthetized dogs), we constructed baroreceptor response curves by alternately decreasing MABP from 100 to 30 mm Hg, and increasing it from 100 to 180 mm Hg, in each case returning MABP to the baseline to obtain hysteresis loops. All baroreceptors were active at 100 mm Hg, their discharge averaging 15-16 impulses/sec. At all pressures above threshold, baroreceptors fired more when pressure was increasing than when pressure was decreasing. This hysteresis caused the steepest part of the response curve constructed in this manner to span the baseline value, demonstrating that, contrary to previous views, aortic baroreceptors signal decreases in pressure below the normal level, as well as increases above it. We also constructed response curves after holding MABP at a "hypertensive" baseline of 125 mm Hg for 20 minutes. "Hypertensive" curves demonstrated reversible resetting, shifting significantly to the right of "normotensive" curves so that baroreceptor threshold increased on average by 7 mm Hg (P less than 0.01). Both hysteresis and short-term resetting probably result from the viscoelastic behavior of wall elements with which baroreceptors are coupled.

Carotid sinus nerve efferents: properties and physiological significance

The significance of a sympathetic efferent nerve supply, vasoconstrictor to the carotid body and hence facilitatory to carotid chemoreceptors, is well understood. The significance of a second efferent pathway, whose impulses, passing down the sinus nerve, are inhibitory to the chemoreceptors, is less certain. Activity in these sinus nerve efferents is increased by injection of pressor agents, by hypoxia, by hypercapnia, by application of alkaline solutions to the ventral medulla, and by severe hypocapnia. All these stimuli appear to act centrally. Sinus nerve efferents can also be activated reflexly by stimulating ipsilateral carotid chemoreceptors. The mechanism of efferent inhibition is disputed. A purely cholinergic vasodilator role is unlikely because inhibitory effects are abolished by alpha-adrenergic antagonists. Sinus efferents probably cause release of an inhibitory transmitter, dopamine, but convincing evidence for a releasing mechanism has yet to be obtained. Stimulation of nociceptive endings in the heart has reciprocal effects on sinus nerve efferents and sympathetic efferents to the carotid body, inhibiting the former and stimulating the latter. Recent results are cited which indicate that the responses of sinus nerve efferents to changes in blood pressure are more variable than is generally believed, and that the conventional explanation of the relationship between sinus efferent activity and arterial pressure needs to be revised.

Bradykinin stimulates afferent vagal C-fibers in intrapulmonary airways of dogs

Bradykinin is released in the lungs in asthma and pulmonary anaphylaxis. It has negligible direct bronchoconstrictor effects in humans or dogs, but inhaled as aerosol it causes cough and reflex bronchoconstriction in asthmatics and some normal subjects. The afferent nerves responsible for these reflex effects have not been identified. We recorded vagal impulses in anesthetized dogs to determine whether lung afferents were stimulated by bradykinin. C-fiber endings in the intrapulmonary airways accessible from the systemic circulation were stimulated by bradykinin injected into the left atrium (0.5-1.0 micrograms/kg) or bronchial artery (1.5 micrograms), activity increasing 15-fold on average. C-fiber endings accessible from the pulmonary circulation were relatively insensitive to bradykinin. Bradykinin caused a small increase in firing of some rapidly adapting (irritant) receptors, but the effect appeared to be secondary to vascular changes. Bradykinin had variable effects on slowly adapting stretch receptors, but did not stimulate them directly. Thus vagally mediated sensory or reflex effects initiated by bradykinin in the lung are probably due to stimulation of "bronchial" C-fibers.

Temporal relationships of barosensory attenuation in conscious rabbits

Electrical stimulation of anterior or posterior hypothalamus with 10-s trains elicited heart rate and blood pressure decreases. Presentation of anterior hypothalamic stimulation coincident with or 5, 10, or 15 s prior to 5-s train stimulation of aortic nerve (AN) summated with depressor-decelerator responses to AN stimulation. The summating effect was more pronounced for heart rate than for blood pressure. Simultaneous onset of AN and posterior hypothalamic stimulation did not influence AN responses. In contrast, when AN stimulation was delayed until 5, 10, or 15 s after onset of posterior hypothalamic stimulation, small, moderate, and full attenuation of AN responses occurred, respectively. Since AN and posterior hypothalamic stimulation each led to depressor-decelerator responses, attenuation of AN responses cannot be attributed to simple summation of cardiovascular responses elicited by intracranial and aortic nerve stimulation.