Differential sympathetic neural control of oxygenation in resting and exercising human skeletal muscle.

Metabolic products of skeletal muscle contraction activate metaboreceptor muscle afferents that reflexively increase sympathetic nerve activity (SNA) targeted to both resting and exercising skeletal muscle. To determine effects of the increased sympathetic vasoconstrictor drive on muscle oxygenation, we measured changes in tissue oxygen stores and mitochondrial cytochrome a,a3 redox state in rhythmically contracting human forearm muscles with near infrared spectroscopy while simultaneously measuring muscle SNA with microelectrodes. The major new finding is that the ability of reflex-sympathetic activation to decrease muscle oxygenation is abolished when the muscle is exercised at an intensity > 10% of maximal voluntary contraction (MVC). During high intensity handgrip, (45% MVC), contraction-induced decreases in muscle oxygenation remained stable despite progressive metaboreceptor-mediated reflex increases in SNA. During mild to moderate handgrips (20-33% MVC) that do not evoke reflex-sympathetic activation, experimentally induced increases in muscle SNA had no effect on oxygenation in exercising muscles but produced robust decreases in oxygenation in resting muscles. The latter decreases were evident even during maximal metabolic vasodilation accompanying reactive hyperemia. We conclude that in humans sympathetic neural control of skeletal muscle oxygenation is sensitive to modulation by metabolic events in the contracting muscles. These events are different from those involved in either metaboreceptor muscle afferent activation or reactive hyperemia.     

Arterial baroreflex buffering of sympathetic activation during exercise-induced elevations in arterial pressure.

Static muscle contraction activates metabolically sensitive muscle afferents that reflexively increase sympathetic nerve activity and arterial pressure. To determine if this contraction-induced reflex is modulated by the sinoaortic baroreflex, we performed microelectrode recordings of sympathetic nerve activity to resting leg muscle during static handgrip in humans while attempting to clamp the level of baroreflex stimulation by controlling the exercise-induced rise in blood pressure with pharmacologic agents. The principal new finding is that partial pharmacologic suppression of the rise in blood pressure during static handgrip (nitroprusside infusion) augmented the exercise-induced increases in heart rate and sympathetic activity by greater than 300%. Pharmacologic accentuation of the exercise-induced rise in blood pressure (phenylephrine infusion) attenuated these reflex increases by greater than 50%. In contrast, these pharmacologic manipulations in arterial pressure had little or no effect on: (a) forearm muscle cell pH, an index of the metabolic stimulus to skeletal muscle afferents; or (b) central venous pressure, an index of the mechanical stimulus to cardiopulmonary afferents. We conclude that in humans the sinoaortic baroreflex is much more effective than previously thought in buffering the reflex sympathetic activation caused by static muscle contraction.     

Impairment of sympathetic activation during static exercise in patients with muscle phosphorylase deficiency (McArdle''s disease).

Static exercise in normal humans causes reflex increases in muscle sympathetic nerve activity (MSNA) that are closely coupled to the contraction-induced decrease in muscle cell pH, an index of glycogen degradation and glycolytic flux. To determine if sympathetic activation is attenuated when muscle glycogenolysis is blocked due to myophosphorylase deficiency (McArdle's disease), an inborn enzymatic defect localized to skeletal muscle, we now have performed microelectrode recordings of MSNA in four patients with McArdle's disease during static handgrip contraction. A level of static handgrip that more than doubled MSNA in normal humans had no effect on MSNA and caused an attenuated rise in blood pressure in the patients with myophosphorylase deficiency. In contrast, two nonexercise sympathetic stimuli, Valsalva's maneuver and cold pressor stimulation, evoked comparably large increases in MSNA in patients and normals. The principal new conclusion is that defective glycogen degradation in human skeletal muscle is associated with a specific reflex impairment in sympathetic activation during static exercise.     

Intracellular ATP can regulate afferent arteriolar tone via ATP-sensitive K+ channels in the rabbit.

Studies were performed to assess whether ATP-sensitive K+ (KATP) channels on rabbit preglomerular vessels can influence afferent arteriolar (AA) tone. K+ channels with a slope conductance of 258 +/- 13 (n = 7) pS and pronounced voltage dependence were demonstrated in excised patches from vascular smooth muscle cells of microdissected preglomerular segments. Channel activity was markedly reduced by 1 mM ATP and in a dose-dependent fashion by glibenclamide (10(-9) M to 10(-6) M), a specific antagonist of KATP channels. 10(-5) M diazoxide, a K+ channel opener, activated these channels in the presence of ATP, and this effect was also blocked by glibenclamide. To determine the role of these KATP channels in the control of vascular tone, diazoxide was tested on isolated perfused AA. After preconstriction from a control diameter of 13.1 +/- 1.1 to 3.5 +/- 2.1 microns with phenylephrine (PE), addition of 10(-5) M diazoxide dilated vessels to 11.2 +/- 0.7 microns, which was not different from control. Further addition of 10(-5) M glibenclamide reconstricted the vessels to 5.8 +/- 1.5 microns (n = 5; P less than 0.03). In support of its specificity for KATP channels, glibenclamide did not reverse verapamil induced dilation in a separate series of experiments. To determine whether intracellular ATP levels can effect AA tone, studies were conducted to test the effect of the glycolytic inhibitor 2-deoxy-D-glucose. After preconstriction from 13.4 +/- 3.2 to 7.7 +/- 1.3 microns with PE, bath glucose was replaced with 6 mM 2-deoxy-D-glucose. Within 10 min, the arteriole dilated to a mean value of 11.8 +/- 1.4 microns (n = 6; NS compared to control). Subsequent addition of 10(-5) M glibenclamide significantly reconstricted the vessels to a diameter of 8.6 +/- 0.5 micron (P less than 0.04). These data demonstrate that KATP channels are present on the preglomerular vasculature and that changes in intracellular ATP can directly influence afferent arteriolar tone via these channels.     

Sympathetic nerve discharge is coupled to muscle cell pH during exercise in humans.

We used phosphorus nuclear magnetic resonance spectroscopy (31P-NMR) to probe the cellular events in contracting muscle that initiate the reflex stimulation of sympathetic outflow during exercise. In conscious humans, we performed 31P-NMR on exercising forearm muscle and simultaneously recorded muscle sympathetic nerve activity (MSNA) with microelectrodes in the peroneal nerve to determine if the activation of MSNA is coupled to muscle pH, an index of glycolysis, or to the concentrations (II) of inorganic phosphate (Pi) and adenosine diphosphate (ADP) which are modulators of mitochondrial respiration. During both static and rhythmic handgrip, the onset of sympathetic activation in resting muscle coincided with the development of cellular acidification in active muscle. Furthermore, increases in MSNA were correlated closely with decreases in intracellular pH but dissociated from changes in phosphocreatine [( PCr]), [Pi], and [ADP]. The principal new conclusion is that activation of muscle sympathetic outflow during exercise in humans is coupled to the cellular accumulation of protons in contracting muscle.     

ATP-dependent K+ channels modulate vasoconstrictor responses to severe hypoxia in isolated ferret lungs.

In normo- and hypoglycemic ferret lungs, the pulmonary vascular response to severe hypoxia (PiO2 less than or equal to 10 mmHg) is characterized by an initial intense vasoconstriction followed by marked vasodilation, whereas in hyperglycemic lungs, vasodilation is minimal, causing vasoconstriction to be sustained. In contrast, the response to moderate hypoxia is characterized by a slowly developing sustained vasoconstriction which is unaffected by glucose concentration. To determine the role of ATP-dependent K+ (KATP) channels in these responses, we examined the effects of cromakalim, which opens KATP channels, and glibenclamide, which closes them. During steady-state vasoconstriction induced in isolated ferret lungs by moderate hypoxia, cromakalim caused dose-dependent vasodilation (EC50 = 7 x 10(-7) M) which was reversed by glibenclamide (IC50 = 8 x 10(-7) M), indicating that KATP channels were present and capable of modulating vascular tone. During severe hypoxia in hypoglycemic lungs [( glucose] less than 1 mM), glibenclamide markedly inhibited the secondary vasodilation. Raising perfusate glucose concentration to 14 +/- 0.4 mM had the same effect. As a result, initial vasoconstrictor responses were well sustained. However, neither glibenclamide nor hyperglycemia affected vasoconstrictor responses to moderate hypoxia or KCl, indicating that effects during severe hypoxia were not due to nonspecific potentiation of vasoconstriction. These findings suggest that in the ferret lung (a) severe hypoxia decreased ATP concentration and thereby opened KATP channels, resulting in increased K+ efflux, hyperpolarization, vasodilation, and reversal of the initial vasoconstrictor response; and (b) hyperglycemia prevented this sequence of events.     

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

Summary. 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 μ/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 μg/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.     

Electrophysiological analysis of adrenergic neurotransmission and its modulation by chronic denervation in canine saphenous veins

The present experiments were undertaken to investigate the electrophysiological responses of the canine saphenous vein evoked by perivascular nerve stimulation, norepinephrine or selective alpha adrenergic agonists before and after chronic sympathetic denervation. Unilateral sympathectomy was performed from T12 to L9 in adult female dogs. After 3 to 5 weeks, the denervated saphenous veins were removed. Innervated saphenous veins were obtained from unoperated dogs. In innervated but not in denervated veins, electrical stimulation generated excitatory junction potentials and a slow depolarization. The slow depolarization was inhibited by rauwolscine or phentolamine, but not by prazosin, whereas excitatory junction potentials were not inhibited by alpha adrenergic blockers. Exogenously applied norepinephrine caused a depolarization of the membrane that was inhibited by rauwolscine but not by prazosin. The selective alpha-1 adrenergic agonist, phenylephrine, and the selective alpha-2 adrenergic agonist, UK 14,304, caused depolarization. In denervated veins, the threshold concentrations of norepinephrine or UK 14,304 required to depolarize the smooth muscle cell membrane were reduced. Responses to phenylephrine were not affected by denervation. These results indicate that in the canine saphenous vein norepinephrine, whether added exogenously or released from sympathetic nerves, causes predominant depolarization by activating alpha-2 adrenergic receptors. Denervation augments selectively the electrical response to alpha-2 adrenergic stimulation.     

Adenosine receptors mediate synergistic stimulation of glucose uptake and transport by insulin and by contractions in rat skeletal muscle.

The role of adenosine receptors in the regulation of muscle glucose uptake by insulin and contractions was studied in isolated rat hindquarters that were perfused with a standard medium containing no insulin or a submaximal concentration of 100 microU/ml. Adenosine receptor antagonism was induced by caffeine or 8-cyclopentyl-1,3-dipropylxantine (CPDPX). Glucose uptake and transport were measured before and during 30 min of electrically induced muscle contractions. Caffeine nor CPDPX affected glucose uptake in resting hindquarters. In contrast, the contraction-induced increase in muscle glucose uptake was inhibited by 30-50% by caffeine, as well as by CPDPX, resulting in a 20-25% decrease in the absolute rate of glucose uptake during contractions, compared with control values. This inhibition was independent of the rate of perfusate flow and only occurred in hindquarters perfused with insulin added to the medium. Thus, adenosine receptor antagonism inhibited glucose uptake during simultaneous exposure to insulin and contractions only. Accordingly, caffeine inhibited 3-O-methylglucose uptake during contractions only in oxidative muscle fibers that are characterized by a high sensitivity to insulin. In conclusion, the present data demonstrate A1 receptors to regulate insulin-mediated glucose transport in contracting skeletal muscle. The findings provide evidence that stimulation of sarcolemmic adenosine receptors during contractions is involved in the synergistic stimulation of muscle glucose transport by insulin and by contractions.     

Effects of pH upon the inhibition by sulphonylurea drugs of ATP-sensitive K+ channels in cardiac muscle.

The effect of pH was tested upon the inhibition of ATP-sensitive K+ (KATP) channels caused by the sulphonylurea drugs tolbutamide and glibenclamide. KATP channels and currents (I-KATP) were activated with SR 44866 in ventricular myocytes isolated from guinea pig hearts. Modification of either external or internal pH had little effect upon the background K+ current (IK1). External pH had no consistent effects upon I-KATP. The application of NH4Cl inhibited I-KATP and its withdrawal caused a slight rebound activation. Compared with the results obtained at pHo 7.4, inhibition of I-KATP by the sulphonylurea drugs was enhanced at pHo 6.5 and reduced at pHo 8.4. The kinetics of the recovery of I-KATP was independent of pHo. Neither internal pH 6.5 nor NH4Cl had any effect upon sulphonylurea-induced inhibition of I-KATP. The dose-response curves for inhibition of I-KATP at different pHo's were found to coincide when plotted for the unionized concentrations of the drugs. It is concluded that it is the unionized forms of the sulphonylurea drugs which are responsible for closure of KATP channels in cardiac muscle. In consequence, extracellular acidification during ischemia will increase the effective concentration of glibenclamide and may be responsible for the cardiovascular disorders associated with this treatment in noninsulin-dependent diabetics.     

运动与ATP-敏感型钾离子通道

背景：在运动生理状态下，KATP 在调节冠状动脉张力、运动诱导心肌保护效应和延缓骨骼肌疲劳等多个方面具有重要作用。目的：对KATP在运动中的作用进行了综述和探讨，以期为深入了解运动调节机体代谢提供理论参考。方法：检索1991年1月至2014年6月 PubMed数据库及维普中文科技数据库文献。英文检索词为“KATP Channels；Adenosine Triphosphate；Sports；Myocardium；Ion Channels”，中文检索词为“KATP通道；三磷酸腺苷；运动；心肌；离子通道”。选择与KATP分子结构、生物学功能及调控相关，以及KATP与冠状动脉、心肌、骨骼肌疲劳及运动能力相关的文献42篇文献进行探讨。结果与结论：ATP敏感性钾离子通道可以偶联细胞内能量代谢和细胞膜兴奋性，在应对各种生理和病理应激时是保护心肌的效应器之一。长期的耐力训练则会增加骨骼肌和心肌KATP的表达，可能是心肌和骨骼肌对运动应激产生的一种适应性表现。KATP 可能参与冠状动脉血流量的调节。在运动诱导的减轻心肌缺血再灌注损伤的保护效应中，心肌KATP具有重要作用。当骨骼肌疲劳发生时，KATP的激活有利于防止ATP的过度消耗而造成肌纤维损伤和细胞死亡，有利于疲劳的快速恢复。关于KATP与运动能力的关系仍需进一步的研究。     

Functional sympatholysis during exercise in patients with type 2 diabetes with intact response to acetylcholine

OBJECTIVE

Sympathetic vasoconstriction is blunted in contracting human skeletal muscles (functional sympatholysis). In young subjects, infusion of adenosine and ATP increases blood flow, and the latter compound also attenuates α-adrenergic vasoconstriction. In patients with type 2 diabetes and age-matched healthy subjects, we tested 1) the sympatholytic capacity during one-legged exercise, 2) the vasodilatory capacity of adenosine and ATP, and 3) the ability to blunt α-adrenergic vasoconstriction during ATP infusion.

RESEARCH DESIGN AND METHODS

In 10 control subjects and 10 patients with diabetes and normal endothelial function, determined by leg blood flow (LBF) response to acetylcholine infusion, we measured LBF and venous NA, with and without tyramine-induced sympathetic vasoconstriction, during adenosine-, ATP-, and exercise-induced hyperemia.

RESULTS

LBF during acetylcholine did not differ significantly. LBF increased ninefold during exercise and during adenosine- and ATP-induced hyperemia. Infusion of tyramine during exercise did not reduce LBF in either the control or the patient group. During combined ATP and tyramine infusions, LBF decreased by 30% in both groups. Adenosine had no sympatholytic effect.

CONCLUSIONS

In patients with type 2 diabetes and normal endothelial function, functional sympatholysis was intact during moderate exercise. The vasodilatory response for adenosine and ATP did not differ between the patients with diabetes and the control subjects; however, the vasodilatory effect of adenosine and ATP and the sympatholytic effect of ATP seem to decline with age.In healthy people, blood flow regulation during exercise is well matched to metabolic demands; vasodilation occurs in active muscles, brought about by a complex interaction of various factors regulating the vascular tone in the microcirculation. One such factor is to overcome the sympathetically mediated vasoconstriction. Direct recordings of muscle sympathetic nerve activity (MSNA) show that exercise-induced increase in sympathetic discharge is targeted to both inactive and active skeletal muscles (1). In the latter, this vasoconstrictor activity is opposed by an inhibition termed “functional sympatholysis” (2).Prostaglandins do not seem to be mandatory for functional sympatholysis, and exogenous nitric oxide cannot oppose sympathetic vasoconstriction (3). Combined inhibition of nitric oxide and prostaglandins augments sympathetic α-adrenergic vasoconstriction, yet the vasoconstrictor responses were substantially blunted compared with resting conditions, indicating that other signals compensate to maintain blood flow to the contracting muscle (4).ATP and adenosine are present in both the systemic circulation and the microcirculation and may be part of cardiovascular regulation because of a direct vasodilatory effect on purinergic endothelial receptors (5). Circulating ATP, but not adenosine, was demonstrated to cause a concomitant vasodilation and inhibition of sympathetic vasoconstriction, indicating an involvement of ATP in functional sympatholysis (6). These versatile actions of ATP on vascular tone may therefore have clinical implications for the pathogenesis of hypertension and atherosclerosis and in the reduced exercise capacity observed in patients with diabetes (7), in whom the ability to increase leg blood flow (LBF) during exercise may be attenuated (8) and the vasoconstrictor responsiveness, as reflected in MSNA, is increased (9).We have recently demonstrated that the vasodilatory effect of the purinergic system is attenuated in patients with type 2 diabetes (10). The current study focused on the capacity of functional sympatholysis in skeletal muscles during moderate exercise in patients with type 2 diabetes. The patients were selected to have a preserved endothelial function, based on their response to infusions with acetylcholine. Moreover, we evaluated the capacity of ATP as a sympatholytic agent and the vasodilatory potency of infusions of ATP and adenosine.     

Alpha adrenoceptor-mediated vasoconstriction in rat hindlimb: innervated alpha-2 adrenoceptors in the saphenous arterial bed

The alpha adrenoceptor subtypes mediating vasoconstriction to exogenous agonists and to spinal sympathetic nerve stimulation have been characterized in the autoperfused (constant flow) femoral (predominantly skeletal musculature) and saphenous (predominantly cutaneous) vascular beds of the pithed rat. Intra-arterial infusion of the alpha-1 adrenoceptor agonist, methoxamine, increased perfusion pressure in both vascular beds over the same range of infusion rates, and the maximum responses were similar. The selective alpha-2 adrenoceptor agonist, B-HT 933, also increased perfusion pressure in both beds, although the maximum response to B-HT 933 in the saphenous bed was approximately twice that observed in the femoral bed. Responses to methoxamine were blocked by the alpha-1 adrenoceptor antagonist, prazosin (0.1 mg/kg), but not the alpha-2 adrenoceptor antagonist, rauwolscine (1 mg/kg), or by the selective postjunctional alpha-2 adrenoceptor antagonist, SK&F 104078 (1 mg/kg). Conversely, responses to B-HT 933 were blocked by rauwolscine and by SK&F 104078, but not by prazosin. Vasopressor responses to B-HT 933 in both vascular beds of the rat hindlimb also were reduced markedly by the calcium channel blocker, nifedipine (1 mg/kg), whereas responses to methoxamine were relatively resistant to inhibition by nifedipine. In the femoral bed, as in the systemic arterial circulation, responses to sympathetic nerve stimulation were strongly inhibited by prazosin, were potentiated by rauwolscine and were unaffected by SK&F 104078. In contrast, in the saphenous arterial bed, the responses to sympathetic nerve stimulation were inhibited by all three antagonists.(ABSTRACT TRUNCATED AT 250 WORDS)     

Differential effects of diazoxide, cromakalim and pinacidil on adrenergic neurotransmission and 86Rb+ efflux in rat brain cortical slices.

The effects of diazoxide, cromakalim and pinacidil on depolarization-evoked tritium overflow from the rat brain cortical slices preloaded with [3H]noradrenaline were studied. Diazoxide inhibited both transmural nerve stimulation (TNS)- and 25 mM K(+)-evoked tritium overflows more potently than cromakalim. Diazoxide effects were only partially antagonized and cromakalim ones were totally reversed by 1 microM glibenclamide. Diazoxide, but not cromakalim, reduced the 45 mM K(+)-evoked tritium overflow, which was not antagonized by glibenclamide. Both diazoxide and cromakalim stimulated 86Rb+ efflux to a similar extent, the effects being completely abolished by glibenclamide. Glibenclamide (> or = 3 microM) by itself enhanced the TNS-evoked tritium overflow. Pinacidil increased both TNS- and K+ (25 and 45 mM)-evoked tritium overflows with little effect on 86Rb+ efflux. Pinacidil-induced increase in the TNS-evoked tritium overflow was still observed in the presence of cocaine or hydrocortisone. Pinacidil failed to affect the inhibitory action of xylazine on the TNS-evoked tritium overflow, whereas phentolamine attenuated it. These results indicate that ATP-sensitive K+ channels are present in the adrenergic nerve endings of rat brain. These channels seem to be pharmacologically different from those reported for vascular smooth muscles and pancreatic beta-cells.     

Differential effects of hyperinsulinemia and carbohydrate metabolism on sympathetic nerve activity and muscle blood flow in humans.

Euglycemic hyperinsulinemia evokes both sympathetic activation and vasodilation in skeletal muscle, but the mechanism remains unknown. To determine whether insulin per se or insulin-induced stimulation of carbohydrate metabolism is the main excitatory stimulus, we performed, in six healthy lean subjects, simultaneous microneurographic recordings of muscle sympathetic nerve activity, plethysmographic measurements of calf blood flow, and calorimetric determinations of carbohydrate oxidation rate. Measurements were made during 2 h of: (a) insulin/glucose infusion (hyperinsulinemic [6 pmol/kg per min] euglycemic clamp), (b) exogenous glucose infusion at a rate matched to that attained during protocol a, and (c) exogenous fructose infusion at the same rate as for glucose infusion in protocol b. For a comparable rise in carbohydrate oxidation, insulin/glucose infusion that resulted in twofold greater increases in plasma insulin concentrations than did glucose infusion alone, evoked twofold greater increases in both muscle sympathetic nerve activity and calf blood flow. Fructose infusion, which increased carbohydrate oxidation comparably, but had only a minor effect on insulinemia, did not stimulate either muscle sympathetic nerve activity or calf blood flow. These observations suggest that in humans hyperinsulinemia per se, rather than insulin-induced stimulation of carbohydrate metabolism, is the main mechanism that triggers both sympathetic activation and vasodilation in skeletal muscle.     

Inhibitory effect of calcitonin gene-related peptide on excitation and contraction of smooth muscles of the rat vas deferens

Calcitonin gene-related peptide (CGRP) inhibits the twitch response of the rat vas deferens induced by nerve stimulation. Inasmuch as CGRP-like immunoreactive nerves were demonstrated to be present in the rat vas deferens, the effect of CGRP on the contractile activity of the tissue was pharmacologically and electrophysiologically analyzed in vitro. The twitch response of the vas deferens induced by transmural nerve stimulation was inhibited by rat CGRP, porcine CGRP and human CGRP (hCGRP). Both ED50 values and the extent of the maximum inhibition of the twitch response were the same for these CGRP groups. hCGRP (10(-8) to 10(-7) M) hyperpolarized the resting membrane potential of smooth muscle cells but did not affect the amplitude of excitatory junction potentials induced by nerve stimulation. Neither the frequency of occurrence nor the amplitude of spontaneous junction potentials were affected by hCGRP. The threshold potentials for the generation of action potentials were less negative in the presence of hCGRP. hCGRP reduced slightly the contraction of the tissue induced by norepinephrine and by adenosine 5'-triphosphate. hCGRP reduced markedly the contractions induced by direct electrical stimulation of both denervated and normal tissues in the presence of tetrodotoxin. These results indicate that CGRP does not affect the release of a sympathetic neurotransmitter. CGRP appears to attenuate the contraction of the rat vas deferens through suppression of both the excitability and excitation-contraction coupling of the smooth muscle.     

Alpha1-adrenergic receptors augment P2X3 receptor-mediated nociceptive responses in the uninjured state.

In the present study, the adrenergic receptor (AR) subtype mediating adrenergic augmentation of P2X(3) receptor-mediated nociceptive responses on sensory nerve endings was examined by using selective AR receptor agonists and antagonists in Sprague Dawley rats in the uninjured state. Local administration of alphabeta-methyleneATP (ligand for P2X3/P2X2/3 receptors) into the plantar hind paw produced few pain behaviors when given alone in this strain of rats; combination with adrenaline (alpha1- and alpha2-AR agonist) and phenylephrine (alpha1-AR agonist) but not clonidine or UK 14,304 (alpha2-AR agonists) increased flinching behaviors. Flinching produced by noradrenaline (NA)/alphabeta-methyleneATP was suppressed by low doses of prazosin (alpha1-AR antagonist), and this reduction was selective compared with yohimbine (alpha2-AR antagonist). Prazosin also reduced flinching produced by phenylephrine/alphabeta-methyleneATP. Using thermal threshold determinations, adrenaline and phenylephrine but not clonidine or UK 14,304, mimicked the action of NA in augmenting reductions in thermal thresholds produced by alphabeta-methyleneATP. Terazosin (another alpha1-AR antagonist) inhibited hyperalgesia produced by NA/alphabeta-methyleneATP. These results provide evidence for alpha1-AR involvement in adrenergic augmentation of P2X3/P2X2/3 receptor-mediated responses on sensory nerve endings in the uninjured state in Sprague Dawley rats. PERSPECTIVE: This study indicates the alpha1-adrenergic receptor subtype mediates adrenergic augmentation of the activation of sensory nerves by purinergic P2X3 receptors (respond to ATP) in the periphery. Observations are potentially relevant to chronic pain conditions in which sympathetic nerves influence sensory nerves.     

Effects of inhibition of ATP-sensitive potassium channels on metabolic vasodilation in the human forearm

Experimental data suggest that vascular ATP-sensitive potassium (K(ATP)) channels may be an important determinant of functional hyperaemia, but the contribution of K(ATP) channels to exercise-induced hyperaemia in humans is unknown. Forearm blood flow was assessed in 39 healthy subjects (23 males/16 females; age 22+/-4 years) using the technique of venous occlusion plethysmography. Resting forearm blood flow and functional hyperaemic blood flow (FHBF) were measured before and after brachial artery infusion of the K(ATP) channel inhibitors glibenclamide (at two different doses: 15 and 100 microg/min) and gliclazide (at 300 microg/min). FHBF was induced by 2 min of non-ischaemic wrist flexion-extension exercise at 45 cycles/min. Compared with vehicle (isotonic saline), glibenclamide at either 15 microg/min or 100 microg/min did not significantly alter resting forearm blood flow or peak FHBF. The blood volume repaid at 1 and 5 min after exercise was not diminished by glibenclamide. Serum glucose was unchanged after glibenclamide, but plasma insulin rose by 36% (from 7.2+/-0.8 to 9.8+/-1.3 m-units/l; P =0.02) and 150% (from 9.1+/-1.3 to 22.9+/-3.5 m-units/l; P =0.002) after the 15 and 100 microg/min infusions respectively. Gliclazide also did not affect resting forearm blood flow, peak FHBF, or the blood volume repaid at 1 and 5 min after exercise, compared with vehicle (isotonic glucose). Gliclazide induced a 12% fall in serum glucose (P =0.009) and a 38% increase in plasma insulin (P =0.001). Thus inhibition of vascular K(ATP) channels with glibenclamide or gliclazide does not appear to affect resting forearm blood flow or FHBF in healthy humans. These findings suggest that vascular K(ATP) channels may not play an important role in regulating basal vascular tone or skeletal muscle metabolic vasodilation in the forearm of healthy human subjects.     

Effect of hypoxemia on responses to norepinephrine and angiotensin in coronary and muscular vessels.

The purpose of this study was to determine the relative effects of acute hypoxemia on constrictor responses to norepinephrine and angiotensin in two vascular beds, the coronary and skeletal muscle. The left circumflex coronary and gracilis muscle arteries of anesthetized dogs were perfused at constant flow. Practolol or propranolol was administered to block indirect myocardial effects of norepinephrine on coronary resistance. When Po2 of arterial blood perfusing the coronary and muscle beds was reduced from 101 to 44 mm while systemic Pco2 remained normal, constrictor responses to both norepinephrine and angiotensin were inhibited in coronary vessels but not in muscle vessels. When local Po2 was reduced to 27 mm Hg, inhibition of responses was again observed in the coronary circulation with both drugs; in the muscle, responses to angiotensin but not to norepinephrine were depressed significantly. Since intracoronary infusion of adenosine increased, rather than inhibited, vasoconstrictor responses to angiotensin, it is unlikely that release of adenosine during hypoxemia accounts for inhibition of vasoconstriction in the coronary circulation. Indomethacin did not alter the inhibition of coronary vasoconstrictor responses to angiotensin during hypoxemia, which suggests that releease of prostglandins during htpoxemia is not the primary mechanism for inhibition of coronary vascular responses. When contractions in the gracilis muscle were produced by electrical stimulation, vasconstrictor responses to norepinnephrine were inhibited during hypoxemia. We conclude that depression of constrictor responses by hypoxemia is more pronounced in the coronay circulation than in resting muscle, but when muscle is contracting, vasoconstrictor responses are impaired during hypoxemia.