Ischemically sensitive abdominal visceral afferents: response to cyclooxygenase blockade

Ischemically sensitive abdominal visceral afferents are known to reflexly stimulate the cardiovascular system. These nerve endings respond to severe hypoxia as well as to exogenously administered bradykinin and prostaglandins such as PGI2, PGE, and PGF2 alpha. We have shown previously that these prostaglandins can sensitize some previously unresponsive afferents to respond to ischemia. To determine if endogenously produced prostaglandins contribute to the observed increase in activity during ischemia, we recorded activity of 6 A delta- and 23 C-fiber sympathetic afferents in anesthetized cats during 5 min of ischemia before and 15-30 min after intravenous administration of either indomethacin (5 mg/kg) or aspirin (50 mg/kg). Before cyclooxygenase inhibition, we noted repeatable increases of 1.44 +/- 0.22 and 1.44 +/- 0.36 impulses/s in the A delta- and C-fibers, respectively, in response to ischemia. After indomethacin or aspirin, these increases were significantly reduced (P less than 0.05) in both thinly myelinated and unmyelinated afferents (0.69 +/- 0.36 and 0.46 +/- 0.21 impulses/s, respectively). In a second protocol, we observed that the activity of six A delta- and seven C-fibers was significantly reduced by aspirin or indomethacin when a single period of ischemia preceded cyclooxygenase blockade. These data, in conjunction with our previous observations, indicate that prostaglandins significantly contribute to the increased afferent discharge activity associated with ischemia of the abdominal visceral region.

Hemodynamic responses to 6 degree head-down rest in dogs: effect of aerobic conditioning

The -6 degree head-down position is used in humans to produce fluid shifts that resemble those occurring in microgravity. Alternative animal models of microgravity may be helpful for extensive exploration of this unique condition. The dog may be a viable candidate. Sixteen dogs were assigned to one of three conditions: anesthetized open chest, anesthetized closed chest, and awake. Dogs in groups 1 (N = 6) and 2 (N = 6) were divided into an exercise or a sedentary treatment, and dogs in group 3 (N = 4) served as their own controls. Following instrumentation the dogs were put in the head-down position for 1 h. Measurements included right atrial pressure, heart rate, and mean arterial pressure for all groups, left ventricular pressure and LV dp/dt for group 1, and cardiac output and iliac flow for group 2. Right atrial pressure increased for all groups. Heart rate demonstrated non-significant changes over time or group. Significant differences were noted for mean arterial pressure, left ventricular pressure and LV dp/dt for exercise condition in response to HDR. It appears that -6 degrees of head-down rest produces similar cardiovascular responses in dogs as those observed in humans and that exercise has a minor effect on those responses.

Cyclooxygenase blockade attenuates responses of group IV muscle afferents to static contraction

Cyclooxygenase products of arachidonic acid might be some of the substances that accumulate in contracting muscle to cause the reflex increases in arterial pressure and ventilation that are evoked by exercise. Recently, cyclooxygenase blockade has been shown to attenuate the reflex cardiovascular responses to static muscular contraction in anesthetized cats. Group IV afferents are believed to comprise part of the afferent arm of the reflex arc, the activation by which static muscular contraction causes these cardiovascular effects. We therefore examined the effects of indomethacin and aspirin, two cyclooxygenase-blocking agents, on the responses to static contraction of group IV afferents with endings in the triceps surae muscles of anesthetized cats. We found that indomethacin (5 mg/kg iv) decreased the responses to contraction of each of eight group IV afferents tested. Likewise, aspirin (50 mg/kg iv) decreased the responses to contraction of each of four group IV afferents tested. On the other hand, we found that arachidonic acid (2 mg) injected into the femoral artery did not increase the responses to contraction of four group IV afferents that were stimulated by this maneuver. In addition, arachidonic acid injection did not cause any of seven group IV afferents not stimulated by static contraction to become responsive to this maneuver. Nevertheless, arachidonic acid injection with the muscle at rest stimulated five of seven contraction-insensitive and two of four contraction-sensitive group IV afferents. Our data suggest that cyclooxygenase metabolites of arachidonic acid are needed for the full expression of the responses of group IV muscle afferents to static contraction.(ABSTRACT TRUNCATED AT 250 WORDS)

Sensitization of group III muscle afferents to static contraction by arachidonic acid

The afferent arm of the reflex are responsible for the pressor response to static contraction is comprised of group III and IV fibers. The nature of the contraction-induced stimulus activating these fibers remains unclear. Evidence suggests that most group III afferents are sensitive to mechanical stimuli, whereas most group IV afferents are sensitive to metabolic stimuli. Recently, in anesthetized cats, stimulation of group III mechanoreceptors has been shown to have a role in the reflex pressor response to static contraction. In skin, the sensitivity of thin fiber mechanoreceptors to distortion of their receptive fields has been shown to be increased by both cyclooxygenase and lipoxygenase products of arachidonic acid metabolism. Therefore, in barbiturate-anesthetized cats we recorded the responses of group III muscle afferents to static contraction before and after arachidonic acid (1-2 mg ia) and/or indomethacin (5 mg/kg iv). Arachidonic acid increased the responses of group III afferents (n = 11) to contraction by 265% (from 0.17 +/- 0.07 to 0.62 +/- 0.24 impulses/s; P less than 0.025). Indomethacin decreased the responses of group III afferents (n = 9) to contraction by 61% (from 1.00 +/- 0.37 to 0.39 +/- 0.16 impulses/s; P less than 0.025). Arachidonic acid given after indomethacin increased the responses of two of four group III afferents to contraction. We conclude that both cyclooxygenase and lipoxygenase products of arachidonic acid metabolism sensitize group III muscle afferents to static contraction.

Reflex cardiovascular and ventilatory responses to increasing H+ activity in cat hindlimb muscle

Static exercise increases arterial pressure, heart rate, and ventilation, effects which are believed in part to arise reflexly from a metabolic stimulus in the working muscle. In anesthetized cats, we tested the hypothesis that intra-arterial injections of lactic and hydrochloric acid, which created levels of these substances in muscle similar to those seen during contraction, reflexly increased cardiovascular and ventilatory function. Hydrochloric acid (32 and 57 mM; 1 ml) injected into the arterial supply of the triceps surae decreased intramuscular pH from 7.26 +/- 0.05 to 7.17 +/- 0.05 (P less than 0.01) and reflexly increased arterial pressure (23 +/- 7 mmHg; P less than 0.01), heart rate (11 +/- 2 beats/min; P less than 0.001), and ventilation (187 +/- 72 ml/min; P less than 0.05). Static contraction of the triceps surae decreased intramuscular pH from 7.28 +/- 0.06 to 7.13 +/- 0.06 (P less than 0.01). Lactic acid was more potent in causing reflexes than was equimolar HCl. For example, lactic acid containing 4 mM lactate and 0.87 mM H+ reflexly increased arterial pressure, heart rate, and ventilation, whereas 0.87 mM HCl did not. Intra-arterial sodium lactate (13 and 33 mM) at a neutral pH had no effect on these variables. We conclude that contraction-induced accumulation of H+, especially that arising from lactic acid, might provide a metabolic stimulus to evoke reflex autonomic effects.

Static contraction increases arachidonic acid levels in gastrocnemius muscles of cats

Static contraction of hind-limb muscles is well known to increase reflexly cardiovascular function. Recently, blockade of cyclooxygenase activity has been reported to attenuate the reflex pressor response to contraction, a finding which suggests that working skeletal muscle releases arachidonic acid metabolites. Therefore, we measured the effects of static contraction and ischemia on arachidonic acid levels in the gastrocnemius muscles of barbiturate-anesthetized cats treated with indomethacin. Unesterified arachidonic acid levels were measured by high-pressure liquid chromatography. We found that static contraction of freely perfused gastrocnemius muscles increased arachidonic acid levels from 4.4 +/- 1.0 to 10.3 +/- 2.2 nmol/g wet wt (n = 12; P less than 0.005). Likewise, static contraction of gastrocnemius muscles made ischemic for 2 min before the onset of the contraction period increased arachidonic acid levels from 12.6 +/- 2.3 to 21.0 +/- 2.0 nmol/g wet wt (n = 12; P less than 0.01). Lastly, 2 min of ischemia with the gastrocnemius muscles at rest increased arachidonic acid levels from 5.9 +/- 1.1 to 10.5 +/- 3.0 nmol/g wet wt (n = 18; P less than 0.02). We conclude that both static contraction and ischemia increase arachidonic acid levels in working hindlimb muscle.

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.

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.

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.