Contractile effects of various vasoactive agents in small rat portal veins and hepatic arteries and the influence of sympathetic denervation on the noradrenaline response

Contractile responses were studied in isolated tubal segments of branches of the rat portal vein (luminal diameter approximately 300 microns) and hepatic artery (luminal diameter approximately 200 microns). Portal veins were approximately three times more sensitive to noradrenaline (NA) than hepatic arteries. 5-hydroxytryptamine contracted hepatic arteries concentration-dependently, whereas it produced only weak and inconsistent contractions in portal veins. Vasopressin effectively contracted hepatic arteries, whereas it had no effect on portal veins. Both vessel types responded to prostaglandin F2 alpha with contractions, although the drug potency was relatively low (EC50 greater than 10(-5) mol l-1). Histamine and carbachol failed to induce (hepatic arteries) or caused only weak (portal veins) contractions. Microsurgical hepatic hilar denervation reduced the catecholamine content of the parenchyma to less than or equal to 25% of controls. In both portal veins and hepatic arteries, the denervation procedure increased the NA sensitivity by factors of 3.1 and 2.0, respectively. In non-denervated livers, cocaine produced a similar increase of the NA sensitivity, whereas the drug had no significant effect in vessels from denervated animals. Thus, there was a marked difference between rat portal veins and hepatic arteries in their responsiveness to several contractile agents. Furthermore, the results of the present study indicate that the adrenergic nerves in both vessel types can be adequately removed by the microsurgical denervation procedure used.     

Mechanisms underlying pre- and postjunctional effects of neuropeptide Y in sympathetic vascular control

The effects of porcine neuropeptide Y (NPY) regarding sympathetic vascular control were studied in vitro on isolated rat blood vessels. The 10(-9)M NPY enhanced (about two-fold) the contractile responses to transmural nerve stimulation (TNS), noradrenaline (NA) and adrenaline (about two-fold) in the femoral artery. Higher concentrations of NPY (greater than 10(-8)M) caused an adrenoceptor-resistant contraction per se. The TNS-evoked [3H]NA efflux was significantly reduced by NPY in a concentration-dependent manner (threshold 10(-9)M). The calcium antagonist, nifedipine, abolished the contractile effects of NPY and the NPY-induced enhancement of NA contractions but did not influence the prejunctional inhibition of [3H]NA release. Receptor-binding studies showed that the ratio of alpha 1-to alpha 2-adrenoceptors in the femoral artery was 30:1. The NPY did not cause any detectable change in the number of alpha 1-or alpha 2-adrenoceptor binding sites or in the affinity of alpha 2-binding sites, as revealed by prazosin- and clonidine-binding, respectively. The NPY also inhibited the TNS-evoked [3H]NA release (by 42-86%) in the superior mesenteric and basilar arteries and in femoral and portal veins. The NPY still depressed TNS-evoked [3H]NA secretion from the portal vein in the presence of phentolamine. The NPY caused a clear-cut contraction in the basilar artery, increased the contractile force of spontaneous contractions in the portal vein, while only weak responses were observed in the superior mesenteric artery and femoral vein. The NA-induced contraction was markedly enhanced by NPY in the superior mesenteric artery, only slightly enhanced in the portal vein and uninfluenced in the femoral vein. In conclusion, in all blood vessels tested, NPY depresses the TNS-evoked [3H]NA secretion via a nifedipine-resistant action. Furthermore, NPY exerts a variable, Ca2+-dependent vasoconstrictor effect and enhancement of NA and TNS contractions.     

Effects of nifedipine on potassium-induced contraction and noradrenaline release in cerebral and extracranial arteries from rabbit

The present study was designed to evaluate the effects of the calcium antagonist nifedipine on potassium-evoked contractions and release of noradrenaline from sympathetic nerves in rabbit basilar and facial arteries. Contractions were measured isometrically in a small volume organ bath. While noradrenaline (NA) produced strong contractions in facial arteries, the majority of the basilar arteries responded only to the highest concentrations of NA employed (greater than 10 microM) with weak contraction. Prazosin (1 microM) and phentolamine (1-10 microM) effectively antagonized the responses to NA in both types of vessel. In contrast, contractions evoked by potassium (K+, 124 mM) were only slightly reduced by the alpha-adrenoceptor blocking agents, indicating that the participation of endogenous NA in maintaining the contractile response to K+ is either small or negligible in the vessel types studied. Nifedipine concentration-dependently inhibited K+-induced contractions in basilar and facial arteries, the former being significantly more affected as evidenced by the maximum inhibitions (approximately 80% compared to approximately 60%) and IC50 values (approximately 10 nM vs. approximately 30 nM). A combination of nifedipine (0.3 microM) and prazosin (1 microM) or phentolamine (1 microM) further suppressed the K+-evoked contractile response in facial arteries, but failed to do so in basilar arteries, when compared with the effect of nifedipine alone. The depressant effect of the alpha-adrenoceptor blockers was, however, still obtainable after reserpine treatment of the facial artery in vitro. Fluorescence histochemical demonstration of noradrenaline revealed a dense network of adrenergic nerve fibres in the walls of the basilar and facial artery. The vessels were also shown to accumulate 3H-NA and release it upon depolarization with K+. The uptake and subsequent release of 3H-NA were significantly reduced by desipramine (10 microM). Nifedipine (0.3-3.0 microM) failed to alter the K+-evoked 3H-NA efflux from sympathetic nerves in neither of the two vessel types. It may be concluded that nifedipine effectively inhibits K+-evoked contractions in isolated basilar and facial arteries from rabbit without interfering with nerve-mediated NA release. Possible explanations for this selective effect of nifedipine on muscle contraction are discussed.     

Effects of prostanoids on isolated feline cerebral arteries. II. Roles of extra- and intracellular calcium for the prostaglandin F2 alpha-induced contraction

The roles of extra- and intracellular calcium for the contractile effects of PGF2 alpha in the feline basilar artery (BA) were investigated. Comparisons were made with contractions induced by K+ and noradrenaline (NA). Addition of nifedipine to PGF2 alpha- or K+ (124 mM)-contracted arteries resulted in an incomplete relaxation, whereas NA-contracted vessels were completely relaxed. Incubation of the preparations in a calcium-free medium containing 10(-5) M EGTA for 5-10 min almost abolished contractions induced by K+ and NA. In contrast, 63% of the response to PGF2 alpha remained after pretreatment of the arteries in a calcium-free solution for 40 min; PGF2 alpha produced a biphasic contraction in 17 out of 20 preparations consisting of a rapidly developing initial phase followed by a second increase in tension after 1-6 min. The second phase was absent if the EGTA-concentration was increased to 10(-4) M, or if the arteries were pre-treated with nifedipine. After incubation of the arteries in a calcium-free medium for 40-120 min and K+-depolarization, re-addition of calcium elicited contractions at lower concentrations in the presence of PGF2 alpha than in controls. The results suggest that PGF2 alpha-induced contractions in the feline BA are considerably less dependent on extracellular calcium than contractions evoked by K+ or NA. PGF2 alpha appears to be able to release calcium from two cellular stores, and may also promote calcium influx through the cell membrane.     

Differentiation of fast and slow muscles in the rat after neonatal denervation: A physiological study

Summary Whether an intact innervation is essential for postnatal muscle differentiation was examined in the rat by recording physiological contraction parameters. Muscles in one leg were denervated neonatally (within 24 h of birth) and, between 3–28 days after the operation, their contractions were compared with those of the contralateral control muscles. Experiments were performed on the extensor digitorum longus (edl, a fast muscle) and the soleus (a slow muscle) muscles and contractions were recordedin vitro, at 35 C and with direct stimulation. When compared with the control muscles, 3–4-day-old neonatally denervated fast and slow muscles had longer twitch contractions, higher twitch/tetanus ratios and certain other specific differences in their contraction parameters. These denervation-induced changes in neonatal muscles were essentially similar to those produced 3–7 days after denervation in the differentiated (4-week-old) fast muscle. Despite differences in their absolute values, the contraction parameters of neonatally denervated and control edl muscles changed similarly during development, indicating that postnatal differentiation of fast muscle fibres is independent of a neuronal influence. In the case of the neonatally denervated soleus muscle, the developmental changes in contraction parameters, i.e. shortening of the twitch duration, increase of rate of rise and rate of relaxation in the tetanus and increase of the maximum shortening velocity, were more pronounced than in the control slow muscle; also, there were similarities with the pattern of fast muscle differentiation. Thus, muscle fibre differentiation in soleus becomes altered towards that of a fast muscle after neonatal denervation.     

Comparative effects of some calcium-channel blockers on human peripheral arteries and veins

We investigated the effects of five different calcium-channel blockers (CCBs), verapamil, nifedipine, diltiazem, flunarizine and lidoflazine, on contractions evoked in vitro by noradrenaline (NA) in small human arteries and veins from the epigastric region. Vessels were obtained from patients without obvious vascular diseases undergoing surgery because of inguinal hernias. The human superficial epigastric artery has previously been shown to contain mainly alpha 1-adrenoceptors, whereas in the vein alpha 2-adrenoceptors predominate. In experiments where NA (10(-5) M) was added non-cumulatively, it was found that nifedipine was the most potent relaxant agent in both arteries and veins, but that this drug showed no preference for any type of vessel. In contrast verapamil (10(-6) M) and (10(-5) M) diltiazem, flunarizine and lidoflazine inhibited the NA-induced contractions to a significantly greater extent in the arteries than in the veins. Comparison between diltiazem and nifedipine on contractions induced by cumulative addition to NA showed that both drugs had significantly more depressive effects on arteries than on veins if the vessels were contracted by relatively high concentrations of NA (10(-6) and 10(-5) M). The results thus confirm the clinical finding that CCBs have more pronounced effects on the arterial than on the venous side of the circulation. They do not support the view that CCBs are more effective inhibitors of alpha 2- than alpha 1-adrenoceptor mediated contraction in isolated human blood vessels.     

Influence of extracellular calcium and nifedipine on alpha 1- and alpha 2-adrenoceptor-mediated contractile responses in isolated rat and cat cerebral and mesenteric arteries

The influence of extracellular Ca2+ and nifedipine on contractile responses to 10 microM noradrenaline (NA) was investigated in isolated rat and cat middle cerebral (RCA, CCA) and mesenteric (RMA, CMA) arteries. In the CCA (containing predominantly alpha 2-adrenoceptors), the NA-induced contractions developed considerably more slowly than in the RCA, RMA (containing mainly alpha 1-adrenoceptors) and CMA (sensitive to both alpha 1- and alpha 2-adrenoceptor selective antagonists). The tonic component of the NA-induced contraction in the four types of artery was substantially suppressed after only short periods in Ca2+-free solution. In each type of artery, excluding the CCA, the contractile response to 124 mM K+ was more sensitive to Ca2+ deprivation than that to NA. This suggests that NA, besides mobilizing extracellular Ca2+, can also release Ca2+ from an intracellular pool in the RCA, RMA and CMA, but not in the CCA. Thus, alpha 1-adrenoceptor-mediated contractions in the RCA and RMA seem to depend on both Ca2+ influx and intracellular Ca2+ release, whereas alpha 2-adrenoceptor-mediated contractile responses in the CCA appear to rely almost entirely on Ca2+ influx. Both the maximum response and the tonic component of the NA-induced contraction were significantly more sensitive to nifedipine in the CCA than in the RCA. In comparison with the NA-induced contractions in these arteries, those in the RMA and CMA were relatively resistant to nifedipine. In the CCA exposed to NA in Ca2+-free medium, nifedipine almost abolished the contraction induced by re-addition of Ca2+, whereas in the other types of artery, Ca2+ re-application evoked a significant contraction also in the presence of the drug. The differential effects of nifedipine presumably reflect differences between the arteries, not only in the relative contribution of Ca2+ influx and intracellular Ca2+ release to the contractile activation, but also in the nifedipine sensitivity of the Ca2+ entry pathways utilized by NA. It is concluded that the mechanisms through which NA induces contraction seem to be related both to the subtype of alpha-adrenoceptor stimulated by NA and to the type of vessel studied.     

Time-dependent effects of ischaemia on neuropeptide Y mechanisms in pig renal vascular control in vivo

We have investigated the effects of ischaemia on neuropeptide Y (NPY) mechanisms involved in sympathetic vascular control of the pig kidney in vivo. Reperfusion after 2 h of renal ischaemia was associated with local overflow of noradrenaline (NA) but not of NPY-like immunoreactivity (-LI). Renal sympathetic nerve stimulation 10 min into reperfusion evoked markedly reduced vasoconstrictor effects and significantly less overflow of NA (reduced by 70% from the pre-ischaemic conditions), whereas NPY-LI overflow was unaltered. Renal vasoconstrictor responses to exogenous peptide YY (PYY), phenylephrine and angiotensin II were strongly attenuated after this ischaemic period, while vasoconstriction to α,β-methylene ATP was maintained to a larger extent. The renal vascular responses and NA overflow had become partially normalized within a 2 h recovery period. In contrast, the renal vasoconstrictor response and the overflow of NPY-LI upon sympathetic nerve stimulation were enhanced after 15 min of renal ischaemia. In parallel, the PYY-evoked renal vasoconstriction was selectively and markedly prolonged after the 15 min of ischaemia. In the presence of the NPY Y₁ receptor antagonist BIBP 3226, the augmented vascular response to nerve stimulation was significantly attenuated. We conclude that reperfusion after 2 h of renal ischaemia is associated with local overflow of NA, whereas the sympathetic nerve-evoked release of NA and the reactivity of the renal vasculature to vasoconstrictor stimuli are reversibly reduced. Furthermore, possibly due to an impaired local degradation, the role of neurogenically released NPY in renal sympathetic vasoconstriction is enhanced after short-term (15 min) ischaemia compared with control conditions.     

Release and vasoconstrictor effects of neuropeptide Y in relation to non-adrenergic sympathetic control of renal blood flow in the pig

The possible involvement of neuropeptide Y (NPY) in sympathetic control of renal blood flow was investigated in the pig in vivo. Exogenous NPY caused renal vasoconstriction with a threshold effect at an arterial plasma concentration of 164 pmol 6(-1). Stimulation of the renal nerves (0.59, 2 and 10 Hz) in control animals evoked rapid and frequency-dependent reduction in renal blood flow and overflow of NPY-like immunoreactivity (NPY-LI) and noradrenaline (NA) from the kidney, suggesting co-release from sympathetic nerves. Following the administration of the alpha- and beta-adrenoceptor antagonists phenoxybenzamine and propranolol, the vasoconstrictor response to exogenous NA was reduced by 98%, whereas that of NPY was unaltered. The response to nerve stimulation with 0.59 Hz was abolished, whereas relatively slowly developing reductions in renal blood flow by 7 and 28% were obtained upon stimulation with 2 and 10 Hz respectively. The nerve stimulation-evoked overflow of NA at 0.59 and 2 Hz, but not at 10 Hz and not that of NPY-LI, was enhanced after adrenoceptor blockade. Twenty-four hours after reserpine treatment (1 mg kg-1 i.v.) the contents of NPY-LI and NA in the renal cortex were reduced by 80 and 98% respectively. Sectioning of the renal nerves largely prevented the reserpine-induced depletion of NPY-LI, but not that of NA. Nerve stimulation of the denervated kidney with 2 and 10 Hz 24 h after reserpine treatment evoked slowly developing and long-lasting reductions in renal blood flow by 6 and 52% respectively. These responses were associated with overflow of NPY-LI, which was similar to and threefold higher than that observed in controls at 2 and 10 Hz respectively, while no detectable overflow of NA occurred. Repeated stimulation with 10 Hz resulted in a progressive fatigue of the vasoconstrictor response and the associated overflow of NPY-LI, giving a high correlation (r = 0.86, P less than 0.001) between the two parameters. It is concluded that NPY is a potent constrictor of the renal vascular bed. Furthermore, although NA is the likely transmitter mediating most of the responses to low to moderate nerve activation under control conditions, the data suggest that NPY may mediate the non-adrenergic reductions in renal blood flow evoked by high-frequency sympathetic nerve stimulation after reserpine treatment.     

Hemodynamic and functional changes during renal venous stasis in dog kidneys

The effect of renal venous pressure (RVP) elevation on renal hemodynamics and tubular function was studied in neurolept anaesthetized dogs. Renal blood flow (RBF) was measured electromagnetically. Clearance of 51Cr-EDTA was used as a measure of the rate of glomerular filtration (GFR). GFR, urinary excretion rates of sodium and water, and lithium clearance (CLi) were used for assessing the absolute and fractional reabsorption rates of sodium and water in the proximal as well as in more distal segments of the nephron. The vasoconstrictor response to RVP elevation was partly abolished by acute surgical denervation or by local application of lidocain on the renal capsule, suggesting that RVP elevation activates an adrenergic vasoconstrictor reflex comprising the spinal cord, and elicited from stretch receptors located in the renal capsule. Further studies in alpha-adrenoceptor blocked or chronic denervated kidneys and in decapsulated kidneys favour the view, that neurogenic and myogenic mechanisms significantly influence the vasoconstrictor response to RVP elevation: The neurogenic contribution to the vasoconstrictor response comprising intrarenal and extrarenal vasoconstrictor mechanisms evoked reflexly by RVP elevation; the myogenic contribution to the vasoconstrictor response comprising opposing vasodilator mechanisms due to increase in renal interstitial tissue pressure during RVP elevation. Studies carried out in intact kidneys, acutely surgically or chronically denervated kidneys or alpha-adrenoceptor blocked kidneys indicate that the increase in proximal reabsorption rates during moderate RVP elevation is due mainly to local intrarenal alpha-adrenergic reflex mechanisms, since the decrease in CLi (during constant filtered load) induced by RVP elevation was unaffected by acute surgical denervation, but completely abolished by chronic denervation of the kidney, or by local alpha-adrenoceptor blockade of the kidney.     

Analysis of the effects of graded levels of hypoxia on noradrenaline-evoked contraction in the rat iliac artery in vitro

In rings of rat iliac artery, contractions were evoked by noradrenaline (NA), the selective alpha(1) adrenoceptor agonist phenylephrine (PE), and K(+), which causes depolarisation-induced contraction. There was no evidence of alpha(2) adrenoceptor-evoked contraction. Hypoxia, induced by reducing P(O(2)) in the bath from 100 mmHg to 70, 55 or 40 mmHg, had similar effects on rings with (E+) and without (E-) endothelium. In E- rings, the NA concentration-response curve was biphasic, whereas that for PE was monophasic. Hypoxia reduced maximum contractions in response to NA and PE (NA(max) and PE(max), respectively) without affecting the concentrations that evoked 50 % of maximum contraction (EC(50)). At P(O(2)) of 70 mmHg, NA(max) of the high affinity alpha(1) receptor for NA (NA(maxh)) and PE(max) were reduced by approximately 15 %, but at P(O(2)) of 55 and 40 mmHg, NA(maxh) was severely attenuated while PE(max) fell by 45 and 75 %, respectively. Similarly, the Ca(2+) channel blocker nicardipine depressed NA(maxh) and PE(max), but P(O(2)) of 55 mmHg further reduced NA(max) and PE(max). Hypoxia also reduced contractions evoked by NA, PE or K(+) at the concentrations required to produce 80 % of the maximum contraction (EC(80)), receptor-mediated contractions being more affected. Ca(2+)-free conditions reduced the contractions evoked by NA and PE, at the EC(80), to approximately 10 % of control. The K(+) channel inhibitors glibenclamide and tetraethylammonium did not prevent hypoxia-induced depression of PE-evoked contraction. Thus, contractions evoked in iliac artery by the high affinity subtype of alpha(1) adrenoceptor for NA, which may respond to circulating levels of NA, and by the single alpha(1) adrenoceptor subtype for PE, are especially vulnerable to P(O(2)) levels less-than-or-equal 55 mmHg. We propose that this reflects hypoxia-induced inhibition of Ca(2+) influx through L-type and receptor-operated Ca(2+) channels; K(+) channel opening makes little contribution.     

Effects of pH on vascular tone in rabbit basilar arteries

Effects of pH on vascular tone and L-type Ca2+ channels were investigated using Mulvany myograph and voltage-clamp technique in rabbit basilar arteries. In rabbit basilar arteries, high K+ produced tonic contractions by 11+/-0.6 mN (mean+/-S.E.,n=19). When extracellular pH (pHo) was changed from control 7.4 to 7.9 ([alkalosis]o), K+-induced contraction was increased to 128+/-2.1% of the control (n=13). However, K+-induced contraction was decreased to 73+/-1.3% of the control at pHo 6.8 ([acidosis] o, n=4). Histamine (10 microM) also produced tonic contraction by 11+/-0.6 mN (n=17), which was blocked by post-application of nicardipine (1 microM). [alkalosis]o and [acidosis]o increased or decreased histamine-induced contraction to 134+/-5.7% and 27+/-7.6% of the control (n=4, 6). Since high K+- and histamine-induced tonic contractions were affected by nicardipine and pHo, the effect of pHo on voltage-dependent L-type Ca2+ channel (VDCCL) was studied. VDCCL was modulated by pHo: the peak value of Ca2+ channel current (IBa) at a holding of 0 mV decreased in [acidosis]o by 41+/-8.8%, whereas that increased in [alkalosis]o by 35+/-2.1% (n=3). These results suggested that the external pH regulates vascular tone partly via the modulation of VDCC in rabbit basilar arteries.     

Characterization of two different calcium entry pathways in small mesenteric arteries from rat

The effects of Ca2+ removal, nifedipine, and La3+ on contractions induced by 124 mM K+ and 10 microM noradrenaline (NA) were investigated in small mesenteric arteries from rat. Ring segments of the arteries were suspended between two steel wires in a 2.5 ml muscle bath, and the mechanical activity recorded "isometrically". The tonic components of the contractile responses to both K+ and NA were critically dependent on the presence of Ca2+ in the bath solution. Nifedipine effectively relaxed K+-contracted arteries, whereas those activated by NA were considerably less affected by the drug. Application of NA to arteries depolarized by K+ in the presence of nifedipine induced a sustained tonic contraction, which was only approximately 20% smaller than that elicited by NA in "standard" Krebs solution, implicating pharmacomechanical coupling. Unlike nifedipine, La3+ inhibited K+- and NA-induced contractions to approximately the same extent. Re-application of Ca2+ to "Ca2+-depleted" preparations exposed to K+ and/or NA induced concentration-dependent contractions. The experimental results suggested that the effects of K+ and NA on the membrane permeability to Ca2+ were additive. The Ca2+-induced contractions were more inhibited by nifedipine in K+-depolarized than in NA-exposed arteries. It is concluded that K+ and NA utilize partly different Ca2+ entry pathways to increase the myoplasmic Ca2+ concentration in rat mesenteric arteries. Whereas K+ seems to promote the influx Ca2+ by activation of CA2+ channels sensitive to the membrane potential, the nature of the receptor-operated Ca2+ entry pathway remains to be established.     

Characterization of the prostanoid receptors and of the contractile effects of prostaglandin F2 alpha in human pial arteries

The contractile and relaxant effects of various prostanoids were studied on isolated human pial arteries. Contractions were elicited with the following order of potency: U46619 approximately equal to U44069 greater than PGB2 greater than PGF2 alpha greater than PGE2 approximately equal to PGD2 approximately equal to PGF1 alpha greater than or equal to TXB2, indicating that prostanoid-induced contractions probably are mediated by a thromboxane-sensitive receptor. Relaxation of PGF2 alpha-contracted arteries was induced with the order of potency: PGE2 greater than PGE1 greater than PGD2 approximately equal to PGD1. Vessels contrated by K+ were relaxed only by PGE1. Since PGI2 was previously found to be more potent than all the prostanoids tested in the present study, relaxant responses are probably mediated via a PGI2-sensitive receptor. The role of free extracellular and cellularly bound calcium for the contractile effects of PGF2 alpha and K+ were estimated by incubating the arteries for various times in calcium-free medium containing 10(-5) M EGTA. Incubation for 5-10 min abolished K+-induced contractions, whereas after 40 min of incubation PGF2 alpha still induced contractions that reached 70% of control. The PGF2 alpha-induced contraction was biphasic in 8 out of 10 preparations. The second phase could be eliminated by increasing the EGTA-concentration to 10(-4) M, as well as by nifedipine pretreatment. In calcium-free, high K+ medium calcium-induced contractions were elicited at lower concentrations in the presence of PGF2 alpha. The results suggest that PGF2 alpha-induced contractions in human pial arteries are relatively independent of free extracellular calcium. PGF2 alpha may promote trans-membrane influx of calcium, as well as release calcium from seemingly superficially located cellular stores.     

Effect of Chronic Sympathetic Denervation upon Local Regulation of Blood Flow in Human Subcutaneous Tissue

The effect of chronic sympathetic denervation upon the vasoconstrictor response to an increase of vascular transmural pressure in human subcutaneous adipose tissue was investigated in 6 patients suffering from manual hyperhidrosis. Changes in transmural pressure were obtained either by postural changes of a forearm or by venous stasis of 30 mmHg. Blood flow was measured in the distal part of the forearm or crus by means of the local ¹³³Xenon washout technique. 2 patients were studied before and after sympathectomy. When the area under study was lowered about 40 cm below the jugular notch, blood flow decreased about 50 per cent preoperatively, about 30 per cent 24 h after the operation, but remained constant 4 days after or later. Similar results were obtained during venous stasis. Hence about 4 days after sympathectomy, the vasoconstrictor response to an increase in vascular transmural pressure was abolished. In 3 chronically sympathectomized patients blood flow remained constant in the denervated limb, but decreased significantly in the control limb. In another patient studied 580 days after surgery blood flow remained constant during lowering of the denervated forearm as well as during venous stasis. These findings might indicate that the vasoconstrictor response to an increase in vascular transmural pressure in human subcutaneous adipose tissue is due to a local nervous mechanism involving symphathetic adrenergic nerves, but a myogenic mechanism cannot be definitively excluded.     

Effects of prostanoids on isolated feline cerebral arteries

The roles of extra-and intracellular calcium for the contractile effects of PGF_2α in the feline basilar artery (BA) were investigated. Comparisons were made with contractions induced by K⁺ and noradrenaline (NA). Addition of nifedipine to PGF_2α-or K⁺ (124 mM)-contracted arteries resulted in an incomplete relaxation, whereas NA-contracted vessels were completely relaxed. Incubation of the preparations in a calcium-free medium containing 10^-5 M EGTA for 5–10 min almost abolished contractions induced by K⁺ and NA. In contrast, 63 % of the response to PGF_2α remained after pretreatment of the arteries in a calcium-free solution for 40 min; PGF_2α produced a biphasic contraction in 17 out of 20 preparations consisting of a rapidly developing initial phase followed by a second increase in tension after 1–6 min. The second phase was absent if the EGTA-concentration was increased to 10^-4 M, or if the arteries were pre-treated with nifedipine. After incubation of the arteries in a calcium-free medium for 40–120 min and K⁺-depolarization, re-addition of calcium elicited contractions at lower concentrations in the presence of PGF_2α than in controls. The results suggest that PGF_2α-induced contractions in the feline BA are considerably less dependent on extracellular calcium than contractions evoked by K⁺ or NA. PGF_2α appears to be able to release calcium from two cellular stores, and may also promote calcium influx through the cell membrane.     

Differences in contractile activation between human myometrium and intramyometrial arteries

Small intramyometrial arteries and pieces of adjacent myometrial tissue were obtained from 25 non-pregnant women undergoing hysterectomy. Vascular and myometrial preparations were dissected, mounted in organ baths and isometric tension was recorded. Myometrial strips, but no vascular preparation, developed spontaneous contractile activity. Noradrenaline (NA) and vasopressin (VP) contracted both vessels and myometrium. Prostaglandin F_2α (PGF_2α) contracted the myometrial tissue, but had only a minor effect on the vessels. Removal of extracellular calcium almost abolished the myometrial responses to high K⁺ (124 mm)-solution, PGF_2α, NA and VP. The vascular responses remaining after this treatment were 18% (K⁺), 34% (NA) and 25% (VP) of control contractions induced by high K⁺ (124 mm). Nifedipine potently depressed myometrial contractions induced by NA and VP, but was less active against the vascular responses to these agents. In preparations exposed to calcium-free medium, nifedipine (10^-7 m) almost abolished myometrial contractions induced by calcium in the presence of K⁺ (124 mm), NA or VP. It also effectively depressed vascular responses to calcium in the presence of K⁺, but was less active if NA and VP were present. It is suggested that PGF_2α has almost no contractant effect on intramyometrial arteries, and that the activation process in these vessels is much less dependent on extracellular calcium than that of the myometrium.     

Effects of noradrenaline and KCl on peripheral vessels in doxorubicin induced model of heart failure

The purpose of the work presented here was to investigate the responses mediated by alpha-adrenoceptors and also contractility of vascular smooth muscle in large peripheral vessels following doxorubicin (DXR)-induced heart failure. Cardiac failure was induced by DXR injection. Thirty saline-treated (normal group) and 30 DXR-treated rabbits (1 mg/kg administered intravenously twice weekly for 8 weeks) were studied. Chronic heart failure was confirmed by echocardiography and later also by histopathology. The DXR-treated hearts were subdivided by ejection fraction >40 or <40 into non-failing (control) and failing (test) groups. Animals were sacrificed by overdose with pentobarbitone sodium (i.v. injection). Arteries and veins were carefully removed with as little connective tissue as possible and placed in cold physiological salt solution. The arterial and venous rings were mounted in 10 ml isolated organ baths, maintained at 37 °C and gassed with 95% O₂ plus 5% CO₂. The rings were then placed under different resting tensions. After initial application of tension tissues were left to equilibrate for a 60-min period. Then all preparations were contracted with KCl (Krebs solution, Na free and high KCl, 125 mM) and allowed to contract for 5–10 min. Following complete washout with normal Krebs, an additional 30 min equilibration period was allowed. Then cumulative concentration–response curves to noradrenaline (NA) obtained by increasing the concentration of the agonist in half-log increments. In contraction responses to NA the renal artery and aorta were the most sensitive preparations (pD₂ values: 5.75 and 5.36, respectively). Compared with control, in DXR-treated rabbits, maximum response (E_max) of NA was not modified in the aorta; renal and saphenous arteries, renal and saphenous veins, whereas it was significantly lower in the vena cava. Compared with control rabbits, in DXR-treated rabbits the pD₂ of NA was significantly increased in the thoracic aorta whereas there was no significant difference between groups in the other studied vessels. Contraction to KCl showed no significant difference between two groups. These results suggest that the sympathetic regulation of vascular contraction is impaired by DXR-induced heart failure through reduction in the alpha-adrenoceptors.     

Response of the granulation tissue to acetylcholine and noradrenaline during denervation

Granulation tissue from the wounds of back of both paws was studied in rats on 7th day of healing following crushing of right sciatic nerve and after repeated applications of 0.2 g/l of acetylcholine (Ach) and noradrenaline (NA). In control group (rats with intact nerves) applications of Ach intensified inflammatory reaction and negatively affected the state of regenerating skin tissues: the effect of NA consists in promoting fibroblastic and leukocytic reactions. Simultaneous crushing of right sciatic nerve and infliction of the wound amplified the pathologic reaction in the wounds of denervated rats as compared to that in animals who did not undergo denervation, leading to rapid ulceration. NA administration caused negative consequences in wounds both in right and left sides. Crushing of the nerve was performed 7 days prior to wound infliction and on day 7 of the study of neurodystrophic processes has shown that Ach influence on denervated and non denervated wounds was positive, while NA influence was negative. After reinnervation adreno- and cholinoreactivity of granulation tissue was partially normalized both on the right and left sides.