Vasodilatory mechanisms in contracting skeletal muscle.

Skeletal muscle blood flow is closely coupled to metabolic demand, and its regulation is believed to be mainly the result of the interplay of neural vasoconstrictor activity and locally derived vasoactive substances. Muscle blood flow is increased within the first second after a single contraction and stabilizes within approximately 30 s during dynamic exercise under normal conditions. Vasodilator substances may be released from contracting skeletal muscle, vascular endothelium, or red blood cells. The importance of specific vasodilators is likely to vary over the time course of flow, from the initial rapid rise to the sustained elevation during steady-state exercise. Exercise hyperemia is therefore thought to be the result of an integrated response of more than one vasodilator mechanism. To date, the identity of vasoactive substances involved in the regulation of exercise hyperemia remains uncertain. Numerous vasodilators such as adenosine, ATP, potassium, hypoxia, hydrogen ion, nitric oxide, prostanoids, and endothelium-derived hyperpolarizing factor have been proposed to be of importance; however, there is little support for any single vasodilator being essential for exercise hyperemia. Because elevated blood flow cannot be explained by the failure of any single vasodilator, a consensus is beginning to emerge for redundancy among vasodilators, where one vasoactive compound may take over when the formation of another is compromised. Conducted vasodilation or flow-mediated vasodilation may explain dilation in vessels (i.e., feed arteries) not directly exposed to vasodilator substances in the interstitium. Future investigations should focus on identifying novel vasodilators and the interaction between vasodilators by simultaneous inhibition of multiple vasodilator pathways.     

Elevation in resting blood flow attenuates exercise hyperemia.

These experiments tested the hypothesis that elevating muscle blood flow before exercise would wash out vasoactive substances produced by muscle contraction and reduce the magnitude of exercise hyperemia and/or delay the response. In chronically instrumented dogs (n = 7), hindlimb blood flow was measured with chronically implanted flow probes during mild treadmill exercise. In an anesthetized preparation (n = 8), arterial and venous blood flows of a single hindlimb were obtained during 1-s tetanic contractions evoked by electrical stimulation of the cut sciatic nerve. Elevation of blood flow by intra-arterial infusion of adenosine attenuated the increase in flow during exercise and tetanic contraction by 48 and 47%, respectively. No delay was observed in the latency to peak flow. The attenuated hyperemic response to exercise or contraction is best explained by washout of vasoactive substance(s) produced by contracting muscle, but the residual response suggests that a metabolic mediator may not be the sole explanation for exercise hyperemia.     

Hyperosmolality dilates rat skeletal muscle arterioles: role of endothelial K(ATP) channels and daily exercise.

The purpose of this study was to investigate the mechanism underlying arteriolar responses to hyperosmolality and to determine the effects of daily exercise on this response. Dilator responses were measured in isolated, cannulated, and pressurized skeletal muscle arterioles. Osmolality was increased from approximately 290 to 330 mosmol/kgH(2)O by adding glucose, sucrose, or mannitol to the superfusion solution. All three compounds elicited similar changes in vessel diameter, suggesting that this response was due to changes in osmolality. Responses to glucose were abolished by endothelium removal but were not altered in endothelium-intact vessels by superfusion with the nitric oxide synthase inhibitor N(omega)-nitro-L-arginine or the cyclooxygenase inhibitor indomethacin. In endothelium-intact arterioles, responses to glucose superfusion with the ATP-sensitive potassium (K(ATP)) channel inhibitor glibenclamide; however, intraluminal perfusion with glibenclamide nearly abolished the responses to glucose and mannitol. Intraluminal administration of glucose elicited a significantly greater dilation than extraluminal glucose. The response to intraluminal glucose was also inhibited by intraluminal glibenclamide. Four weeks of daily exercise did not significantly alter the responses to hyperosmolality in gracilis or soleus muscle arterioles. These data demonstrate that physiological increases in intraluminal osmolality dilate rat skeletal muscle arterioles via activation of endothelial K(ATP) channels; however, this endothelium-dependent response is not augmented by daily exercise.     

Impaired skeletal muscle perfusion in obese Zucker rats

Skeletal muscle arterioles from obese Zucker rats (OZR) exhibit oxidant stress-based alterations in reactivity, enhanced alpha-adrenergic constriction, and reduced distensibility vs. microvessels of lean Zucker rats (LZR). The present study determined the impact of these alterations for perfusion and performance of in situ skeletal muscle during periods of elevated metabolic demand. During bouts of isometric tetanic contractions, fatigue of in situ gastrocnemius muscle of OZR was increased vs. LZR; this was associated with impaired active hyperemia. In OZR, vasoactive responses of skeletal muscle arterioles from the contralateral gracilis muscle were impaired, due in part to elevated oxidant tone; reactivity was improved after treatment with polyethylene glycol-superoxide dismutase (PEGSOD). Arterioles of OZR also exhibited increased alpha-adrenergic sensitivity, which was abolished by treatment with phentolamine (10-5 M). Intravenous infusion of phentolamine (10 mg/kg) or PEG-SOD (2,000 U/kg) in OZR altered neither fatigue rates nor active hyperemia from untreated levels; however, combined infusion improved performance and hyperemia, although not to levels in LZR. Microvessel density in the contralateral gastrocnemius muscle, determined via histological analyses, was reduced by approximately 25% in OZR vs. LZR, while individual arterioles from the contralateral gracilis muscle demonstrated reduced distensibility. These data suggest that altered arteriolar reactivity contributes to reduced muscle performance and active hyperemia in OZR. Further, despite pharmacological improvements in arteriolar reactivity, reduced skeletal muscle microvessel density and arteriolar distensibility also contribute substantially to reduced active hyperemia and potentially to impaired muscle performance.     

Metabolic factors in peripheral circulatory regulation.

The old and recent literature bearing on the role of metabolic factors in exercise hyperemia has been reviewed. Two general conclusions have gradually emerged over the years. First, no one factor is by itself a sufficient explanation for the hyperemia. Second, the contributions of the various factors appear to change with time of exercise. While additional temporal studies are needed to firmly establish more specific conclusions, those now available suggest that factors related to skeletal muscle cell depolarization initiate the hyperemia while factors related to oxygen consumption in excess of oxygen delivery contribute more to the maintenance of the hyperemia. For example, the potassium that leaves the skeletal muscle cell on depolarization appears to contribute more to the initiation of the hyperemia than to its maintenance. Hydrogen, on the other hand, appears to have little to do with initiation but may contribute to maintenance, at least with grades of exercise that reduce cellular oxygen tension. The picture that emerges from the review seems to be one of multiple factors acting in concert with a changing temporal pattern.     

Microvascular remodeling and accelerated hyperemia blood flow restoration in arterially occluded skeletal muscle exposed to ultrasonic microbubble destruction

We showed previously that microbubble destruction with pulsed 1-MHz ultrasound creates a bioeffect that stimulates arteriogenesis and a chronic increase in hyperemia blood flow in normal rat muscle. Here we tested whether ultrasonic microbubble destruction can be used to create a microvascular remodeling response that restores hyperemia blood flow to rat skeletal muscle affected by arterial occlusion. Pulsed ultrasound (1 MHz) was applied to gracilis muscles in which the lateral feed artery was occluded but the medial feed artery was left intact. Control muscles were similarly occluded but did not receive ultrasound, microbubbles, or both. Hyperemia blood flow and number of smooth muscle (SM) alpha-actin-positive vessels, >30-mum arterioles, and capillaries per fiber were determined 7, 14, and 28 days after treatment. In ultrasound-microbubble-treated muscles, lateral region hyperemia blood flow was increased at all time points and restored to normal at day 28. The number of SM alpha-actin vessels per fiber was increased over control in this region at days 7 and 14 but decreased by day 28, when larger-diameter arterioles became more prevalent in the medial region. The number of capillaries per fiber was increased over control only at day 7 in the lateral region and only at days 7 and 14 in the medial region, indicating that the angiogenesis response was transient and likely did not contribute significantly to flow restoration at day 28. We conclude that ultrasonic microbubble destruction can be tailored to stimulate an arteriogenesis response that restores hyperemia blood flow to skeletal muscle in a rat model of arterial occlusion.     

Bradykinin facilitates noradrenaline spillover during contraction in the canine gracilis muscle.

Noradrenaline spillover from skeletal muscle vascular areas increases during exercise but the underlying mechanisms are not well understood. Muscle contraction itself causes changes in many factors that could affect noradrenaline spillover. For instance, it has been reported that bradykinin is synthesized in skeletal muscle areas during contraction. Because the B2 bradykinin receptor facilitates noradrenaline spillover, it may be involved in the increase associated with contraction. In this experiment, we studied the effect of bradykinin on noradrenaline spillover in the in situ canine gracilis muscle, using the specific B2 antagonist HOE 140. The drug did not modify noradrenaline spillover at rest, but did cause a significant decrease during muscle contraction, from 558 to 181 pg min(-1). As reported previously in the literature, fractional extraction of noradrenaline decreased during muscle contraction. This effect was independent of HOE 140 treatment. In light of our results, it seems that bradykinin formation during muscle contraction may play an important part in the observed increase in noradrenaline spillover but does not affect fractional extraction.     

Mechanisms involving the endothelium in reaction of reactive hyperemia

The experiments on anesthetized dogs and on test-preparations of isolated vascular rings of femoral artery used for detection of appearance of vasoactive substances in venous blood demonstrated that the response of reactive hyperemia is accompanied by the appearance of vasodilation substances in the blood, the concentration of which taking into account the reaction of relaxation of vascular preparation, increases with the occlusion duration. Chemical inhibition of endothelium of a studied bed by saponin essentially decreases the reactive hyperemia and relaxation of test-preparation. The rise of pressure in an overlapped part of a bed and the decrease in the deformation of endothelium with the help of dimerized glutaraldehyde treatment affected the hyperemia and vascular preparation reaction in the similar way. We concluded that the reaction of reactive hyperemia is the result of the vasoactive substances secretion by endothelium in response to a decrease in intravascular pressure.     

Rapid vasodilation in response to a brief tetanic muscle contraction.

To test the hypothesis that vasodilation occurs because of the release of a vasoactive substance after a brief muscle contraction and to determine whether acetylcholine spillover from the motor nerve is involved in contraction-induced hyperemia, tetanic muscle contractions were produced by sciatic nerve stimulation in anesthetized dogs (n = 16), instrumented with flow probes on both external iliac arteries. A 1-s stimulation of the sciatic nerve at 1. 5, 3, and 10 times motor threshold increased blood flow above baseline (P < 0.01) for 20, 25, and 30 s, respectively. Blood flow was significantly greater 1 s after the contraction ended for 3 and 10 x motor threshold (P < 0.01) and did not peak until 6-7 s after the contraction. The elevations in blood flow to a 1-s stimulation of the sciatic nerve and a 30-s train of stimulations were abolished by neuromuscular blockade (vecuronium). The delayed peak blood flow response and the prolonged hyperemia suggest that a vasoactive substance is rapidly released from the contracting skeletal muscle and can affect blood flow with removal of the mechanical constraint imposed by the contraction. In addition, acetylcholine spillover from the motor nerve is not responsible for the increase in blood flow in response to muscle contraction.     

Muscle blood flow patterns during exercise in partially curarized rats

We studied the distribution of blood flow within and among muscles of partially curarized (40-100 micrograms/kg body wt) rats during preexercise and at 1 min of low-speed treadmill exercise (15 m/min). Glycogen loss in the deep red muscles and parts of muscles was significantly reduced in the curarized animals during exercise, indicating the fibers in these muscles were recruited to a lesser extent and/or had lower metabolisms than fibers in the same muscles of control rats. However, elevations in blood flow in the red muscles of the curarized rats were as great or greater than those in the control rats. Thus reduced recruitment and/or metabolism of the deep red muscle fibers of the curarized animals was not accompanied by reduced blood flow. These findings suggest a dissociation between red fiber metabolism and blood flow in the curarized rats during the 1st min of slow treadmill exercise and indicate that release of vasodilator substances or local physical factors associated with muscle fiber activity are not solely responsible for the initial hyperemia during exercise.     

Functional adaptations of rat skeletal muscle arterioles to aerobic exercise training.

This study tested the hypothesis that both structural and functional adaptations of arterioles occur within the skeletal muscle of rats aerobically trained for 8-10 wk with treadmill exercise. The training regimen used has been shown to elicit a 37% increase in plantaris citrate synthase activity but did not result in an elevation in citrate synthase activity in the spinotrapezius or gracilis muscles of rats used in this study. In the in vivo resting spinotrapezius muscle, arteriole diameters were similar in sedentary (SED) and trained (TR) rats. However, large- (1A) and intermediate- (2A) sized arterioles dilated proportionately more in TR than in SED rats during 1- to 8-Hz muscle contractions, even though the passive mechanical properties (circumference-passive wall tension relationships) were similar between groups. Vascular casts demonstrated a trend for an increase in the number of small (3A) arterioles and an approximately 20% increase in the passive diameter of 1A and 2A arterioles in the spinotrapezius muscle of TR rats. In contrast, in the gracilis muscle, arteriole diameters and density were identical in SED and TR rats, but the capillary-to-muscle fiber ratio was approximately 15% higher in TR rats. The results suggest that aerobic exercise training can greatly increase functional vasodilation and induce a slight increase in vascular density in skeletal muscle tissues, even if the oxidative capacity of these tissues is not increased by the training regimen.     

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.     

Exercise training and responsiveness of isolated coronary arteries.

Exercise is associated with release of catecholamines and vasoactive intestinal polypeptides. Recurrent exposure to catecholamines modifies the sensitivity of adrenoceptors. To test the hypothesis that exercise training may affect the sensitivity of the epicardial coronary arteries, we performed studies on isolated coronary arteries from male dogs capable of running on a treadmill. The animals were separated randomly into two groups: sedentary and exercise training. After 11 wk, rings of left circumflex and left anterior descending coronary arteries were studied in vitro. Contractions to alpha 1-adrenergic agonists (norepinephrine and phenylephrine) were not affected by exercise training. During contractions with prostaglandin F2 alpha, endothelium-dependent relaxations to alpha 2-adrenergic agonists (norepinephrine and UK 14304) were not reduced significantly by exercise training. The concentration-relaxation curves to beta-adrenergic agonists (norepinephrine, isoproterenol, and epinephrine) were shifted to the right after training. The concentration-response curves to vasoactive intestinal polypeptide, but not that to substance P, were shifted to the right in rings with endothelium from exercise-trained animals. These findings demonstrate a decrease in responsiveness of canine vascular smooth muscle to beta-adrenergic agonists and to vasoactive intestinal polypeptide after exercise training.     

Innervation of interstitial cells of Cajal by vasoactive intestinal polypeptide containing nerves in canine colon.

The hypothesis was tested, through structural and functional studies, that interstitial cells of Cajal receive and can respond to direct innervation from nerves containing the vasoactive intestinal polypeptide neuromediator. The submucosal network of interstitial cells of Cajal has been postulated to provide pacemaking activity for the circular muscle and to be involved in neurotransmission from nonadrenergic, noncholinergic nerves for which vasoactive intestinal polypeptide is a putative mediator. The distribution of vasoactive intestinal polypeptide and substance P immunoreactive material in nerve profiles of the enteric nervous system of the canine colon was examined. In addition, electrophysiological studies were done on the interstitial cells bordering the submucosal side of the circular muscle layer after they were electrically isolated using heptanol. The vasoactive intestinal polypeptide immunoreactivity, located exclusively in nerve large granular vesicles, was found throughout the enteric nervous system (myenteric plexus, submucous plexus, and circular muscle--submucosa interface). The highest proportion (38% compared with 22-24%) of profiles of large granular vesicles with vasoactive intestinal polypeptide immunoreactivity was found in nerve profiles of the circular muscle--submucosa interface. In contrast, substance P immunoreactivity was found in nerve profiles of myenteric plexus (33% of large granular vesicles were positive) but not associated with submucosal interstitial cell nerve network. The vasoactive intestinal polypeptide hyperpolarized interstitial cells by 9 mV when electrically isolated by 1 mM heptanol and markedly reduced (about 50%) their input membrane resistance. We conclude that the distribution of vasoactive intestinal polypeptide immunoreactivity and its action are consistent with a postulated role of the interstitial cells as a major site of neurally mediated inhibition of colonic pacemaker activity.     

Exercise selectively increases G4 AChe activity in fast-twitch muscle

Acetylcholinesterase (AChe) molecular forms were studied in hindlimb skeletal muscles from adult male Fischer 344 rats subjected to treadmill exercise for periods ranging between 1 and 30 days. Groups of three animals were exercised for 1 h/day at a treadmill speed of 8.5 m/min, with 1-min sprints at 15 m/min every 10 min. This exercise protocol led to a significant increase in the activity of G4 AChe in fast-twitch (gracilis and tibialis) but not in slow-twitch (soleus) muscles. Other AChe forms and muscle protein content remained unaltered. Such a selective enzymatic change was detected after a single exercise session, became more apparent after three daily sessions, and persisted for at least 30 days of exercise. A larger increment in G4 AChe activity was observed in gracilis muscle end-plate vs. non-end-plate regions. These findings show a specific adaptive reaction of fast-twitch muscles to enhanced motor activity, suggest that individual AChe forms in motor end plates are regulated through separate mechanisms, and support the hypothesis that membrane-bound G4 AChe plays an essential role in neuro-muscular transmission.     

Immediate exercise hyperemia: contributions of the muscle pump vs. rapid vasodilation.

A striking characteristic of the blood flow adaptation at exercise onset is the immediate and substantial increase in the first few (0-5 s) seconds of exercise. The purpose of this mini-review is to put into context the present evidence regarding mechanisms responsible for this phase of exercise hyperemia. One potential mechanism that has received much attention is the mechanical effect of muscle contraction (the muscle pump). The rapid vasodilatory mechanism(s) is another possible mechanism that has recently been shown to exist. This review will provide the reader with 1) an understanding of the basic physics of blood flow and the theories of muscle pump function, 2) a critical examination of evidence both for and against the contribution of the muscle pump or rapid vasodilatory mechanisms, and 3) an awareness of the limitations and impact of experimental models and exercise modes on the contribution of each of these mechanisms to the immediate exercise hyperemia. The inability to measure microvenular pressure continues to limit investigators to indirect assessments of the muscle pump vs. vasodilatory mechanism contributions to immediate exercise hyperemia in vivo. Future research directions should include examination of muscle-contraction-induced resistance vessel distortion as a trigger for rapid smooth muscle relaxation and further investigation into the exercise mode dependency of muscle pump vs. rapid vasodilatory contributions to immediate exercise hyperemia.     

Expression of functional neurotransmitter receptors in an uninnervated tissue: avian amnion

Summary The smooth muscle of the avian amnion is unusual because it is normally never innervated. However, as assessed by contractile responses, this tissue expressed at least 11 different types of receptor for neurotransmitter substances including acetylcholine, norepinephrine, histamine, 5-hydroxytryptamine, vasoactive intestinal peptide, urotensin II, neurotensin, and somatostatin-28. Three neurotransmitters, histamine, 5-hydroxytryptamine, and norepinephrine, each acted via 2 separate and antagonistic types of receptors. The amnion also responded to prostaglandin E₂. On the other hand, the tissue did not respond to substance P or bradykinin, 2 peptides that are known to affect smooth muscle contractility in a variety of other systems. Studies with organ-cultured amnion demonstrated that the smooth muscle can be cultured early in development and will differentiate in vitro. Some, but not all, of the amniotic responses developed in a defined medium. The results indicate that this novel smooth muscle preparation will be useful for identifying epigenetic factors that control the expression of functional receptors.     

Effects of combined inhibition of ATP-sensitive potassium channels, nitric oxide, and prostaglandins on hyperemia during moderate exercise.

ATP-sensitive potassium (KATP) channels have been suggested to contribute to coronary and skeletal muscle vasodilation during exercise, either alone or interacting in a parallel or redundant process with nitric oxide (NO), prostaglandins (PGs), and adenosine. We tested the hypothesis that KATP channels, alone or in combination with NO and PGs, regulate exercise hyperemia in forearm muscle. Eighteen healthy young adults performed 20 min of moderate dynamic forearm exercise, with forearm blood flow (FBF) measured via Doppler ultrasound. After steady-state FBF was achieved for 5 min (saline control), the KATP inhibitor glibenclamide (Glib) was infused into the brachial artery for 5 min (10 microg.dl(-1).min(-1)), followed by saline infusion during the final 10 min of exercise (n = 9). Exercise increased FBF from 71 +/- 11 to 239 +/- 24 ml/min, and FBF was not altered by 5 min of Glib. Systemic plasma Glib levels were above the therapeutic range, and Glib increased insulin levels by approximately 50%, whereas blood glucose was unchanged (88 +/- 2 vs. 90 +/- 2 mg/dl). In nine additional subjects, Glib was followed by combined infusion of NG-nitro-L-arginine methyl ester (L-NAME) plus ketorolac (to inhibit NO and PGs, respectively). As above, Glib had no effect on FBF but addition of L-NAME + ketorolac (i.e., triple blockade) reduced FBF by approximately 15% below steady-state exercise levels in seven of nine subjects. Interestingly, triple blockade in two subjects caused FBF to transiently and dramatically decrease. This was followed by an acute recovery of flow above steady-state exercise values. We conclude 1) opening of KATP channels is not obligatory for forearm exercise hyperemia, and 2) triple blockade of NO, PGs, and KATP channels does not reduce hyperemia more than the inhibition of NO and PGs in most subjects. However, some subjects are sensitive to triple blockade, but they are able to restore FBF acutely during exercise. Future studies are required to determine the nature of these compensatory mechanisms in the affected individuals.     

Muscle blood flow during isometric activity and its relation to muscle fatigue

The effect of isometric exercise on blood flow, blood pressure, intramuscular pressure as well as lactate and potassium efflux from exercising muscle was examined. The contractions performed were continuous or intermittent (5 s on, 5 s off) and varied between 5% and 50% maximal voluntary contraction (MVC). A knee-extensor and a hand-grip protocol were used. Evidence is presented that blood flow through the muscle is sufficient during low-level sustained contractions (less than 10% MVC). Despite this muscle fatigue occurs during prolonged contractions. One mechanism for this fatigue may be the disturbance of the potassium homeostasis. Such changes may also play a role in the development of fatigue during intermittent isometric contractions and even more so in the recovery from such exercise. In addition the role of impaired transport of substances within the muscle, due to long-lasting daily oedema formation, is discussed in relation to fatigue in highly repetitive, monotonous jobs.     

Nitric oxide may be the final mediator of nonadrenergic, noncholinergic inhibitory junction potentials in the gut.

This study tested the hypothesis that the final mediator of nonadrenergic, noncholinergic (NANC) inhibitory junction potentials (ijps) and associated relaxation responses was nitric oxide (NO) or a related substance and not vasoactive intestinal polypeptide (VIP). We used opossum esophagus body circular muscle and canine intestine circular muscle. In both these tissues, ijps had reversal potentials near the potassium equilibrium potential, (EK); in esophagus the ijps were apamin insensitive, but in the intestine they were partially apamin sensitive. N omega-Nitro-L-arginine methyl ester (NAME) (10(-5) to 5 x 10(-4) M) abolished ijps in both tissues, an effect overcome by 10(-3) M L-arginine but not D-arginine. NAME increased input resistance of esophagus tissues in the double sucrose gap but caused no significant depolarization in the sucrose gap or in studies with microelectrodes. Contractions and basal tension were increased in both tissues by NAME. The apamin sensitive and insensitive ijp components in canine muscle were both abolished by NAME, but the time course of this abolition was different for the two components. Methylene blue (10-50 microM) with variable rapidity and extent inhibited ijps in both tissues, but L-arginine could not overcome this effect. Methylene blue, like NAME, did not depolarize detectably but enhanced the contractile activity. VIP (10(-6) M) had very small effects in both tissues, little or no hyperpolarization and increased input resistance in esophagus, these effects were not changed by NAME, and VIP did not affect ijps. We conclude that NO may be the final mediator of NANC-initiated inhibitory junction potentials in gastrointestinal circular smooth muscle.