Central hemodynamic effects of adrenaline with special reference to β2-adrenergic influence on heart rate and cardiac afterload in anesthetized cats

Central hemodynamic responses evoked by i. v.infusions of adrenaline and noradrenaline were studied in normovolemic anesthetized cats with intact adrenoceptors, after selective β₂-blockade (ICI 118,551), and after nonselective β-blockade (propranolol).The results demonstrated the presence of an important β₂-adrenergic component in the integrated response to ‘physiological’ doses of adrenaline contributing to increased cardiac output, decreased total peripheral resistance and virtually unchanged mean arterial blood pressure. Corresponding β₂-adrenergic effects of noradrenaline were small. The β₂-adrenergic effects of adrenaline on the heart seemed to be both direct and indirect. A moderate direct chronotropic response mediated by β₂-adrenoceptors apparently was present but there was no evidence of a direct β₂-adrenergic inotropic effect. An indirect, quite marked effect on the heart was accomplished by a β₂-adrenergic vasodilator interaction with the α-adrenergic vasoconstrictor influence on the systemic resistance vessels. This caused a net decrease in total peripheral resistance, thereby preventing an undue increase in cardiac afterload (arterial pressure) which seemed to be essential for evoking ‘optimal’ increases in cardiac output. It is suggested that such adrenaline evoked indirect, β₂-adrenergic improvement of cardiac performance is of functional importance in reflex sympatho-adrenal circulatory control.     

Decrease in survival time in β2-adrenoceptor blocked cats exposed to bleeding

Our previous investigations have indicated that β₂-adrenergic regulatory mechanisms contribute to important compensatory hemodynamic adjustments in hemorrhage. In the present study an attempt was made to examine, by comparative observations after standardized fatal hemorrhage on cats with intact and ‘selectively’ blocked β₂-adrenoceptors (ICI 118,551), whether such compensatory effects are crucial for survival. On the average, the survival time after bleeding was 686 min in cats with intact and 427 min in cats with blocked β₂-adrenoceptors (p < 0.05), the difference thus approaching 4.5 h. It is suggested that the reduced survival time after β₂-blockade, at least partly, can be ascribed to interference with the circulatory β₂-adrenergic control in hemorrhage aimed at improving tissue perfusion.     

β2-adrenergic control of plasma volume in hemorrhage

Hemorrhage is associated with absorption of extravascular fluid from skeletal muscle to blood in order to compensate for the loss of intravascular volume. Our previous studies have shown that this fluid gain is mainly linked to β-adrenergic microvascular adjustments leading to decrease in capillary hydrostatic pressure and to precapillary ‘sphincter’ mediated increase in the capillary surface area available for fluid exchange. In the present study the importance of β-adrenergic control of plasma volume in bleeding was confirmed by measurement of changes in plasma volume after graded hemorrhage in animals with intact and blocked vascular β₂-adrenoceptors (i. v. administration of the ‘selective’β₂-blocking agent ICI 118, 551). With intact β₂-adrenoceptors plasma volume was gradually restored after bleeding so that about 50% of the shed plasma volume (about 35% of the shed blood volume) had been compensated for at two hours after exsanguination of 20% as well as 40% of the blood volume. The corresponding figures in animals with blocked β₂-adrenoceptors were only 14% of the shed plasma volume and 8% of the shed blood volume at both degrees of hemorrhage.     

Influences on central hemodynamics in hemorrhage of β2-adrenergic vascular control mechanisms

Central hemodynamic responses evoked by standardized hemorrhage (exsanguination of 20 ml×kg bwt^-1) were followed during 2 h in cats with intact and blocked vascular β₂-adrenoceptors using the ‘selective’β₂-blocker, ICI 118, 551. In the first 10 min after bleeding blood pressure and cardiac output (CO) decreased and total peripheral resistance (TPR) increased by the same amount in the ‘intact’ and β₂-blocked animals. Whereas blood pressure later on reached approximately the same hypotension level in both groups, other hemodynamic variables were distinctly different. In the ‘intact’ animals there was a gradual, partial recovery of stroke volume (SV) and CO in the face of a restoration to control of TPR. In the β₂-blocked animals TPR continued to increase in the face of a maintained low CO and declining SV. The lower SV in the latter group was ascribed to abolition of β₂-adrenergic restoration of plasma volume via absorption of tissue fluid into the circulation. The gradual decline of TPR in the ‘intact’ animals was attributed to β₂-adrenergic dilator interaction with constrictor influences on the resistance vessels. It is concluded that β-adrenergic vascular control mechanisms help to improve nutritional tissue blood flow during hemorrhage by increasing plasma volume, and hence venous return and CO, and by decreasing TPR. These reflex, β₂-adrenergic circulatory events are similar to those aimed at in current shock therapy by transfusion and vasodilator treatment.     

Classification of β-adrenoceptors in the microcirculation of skeletal muscle

Nervous and humoral β-adrenergic, postjunctional effects on microvascular resistance, on precapillary sphincter tone, and on transcapillary fluid exchange in cat skeletal muscle (Lundvall & Järhult 1974, 1976 a, Lundvall & Hillman 1978 a, b) were evaluated with regard to the β₁-or β₂,-specificity of the adrenoceptors. Marked β₂-dilator responses but no significant β₁-effects were observed. The conclusion was therefore reached that neurogenic as well as humoral β-adrenergic control of the microcirculation in skeletal muscle is exerted via activation of β₂-adrenoceptors.     

Effects of subacute treatment with toluene on cerebrocortical α- and β-adrenergic receptors in the rat. Evidence for an increased number and a reduced affinity of β-adrenergic receptors

Subacute treatment with toluene (80–1500 p.p.m.) produces a dose-dependent reduction of affinity and increase in density of the β-adrenergic antagonist [³H]dihydroalprenolol binding sites in the frontoparietal cortex of the male rat, while the binding characteristics of a,-adrenergic ([³H]WB 4101) and α₂^-adrenergic ([³H]p-aminoclonidine) binding sites in the same region is unaffected by this treatment as evaluated in vitro. Therefore, it is suggested that the cortical β-adrenergic receptors are particularly vulnerable to the action of toluene in vivo. It is speculated that as a result cortical β-adrenergic neurotransmission may be altered following exposure to low concentrations of toluene, possibly related to the physico-chemical properties of toluene, leading to changes in membrane fluidity.     

Sympathetic influence on cardiovascular responses to sustained head-up tilt in humans

Sympathetic β-adrenergic influences on cardiovascular responses to 50d? head-up tilt were evaluated with metoprolol (β₁-blockade; 0.29 mg kg^-1) and propranolol (β₁ and β-₂-blockade; 0.28 mg kg^-1) in eight males. A normotensive-tachycardic phase was followed by a hypotensive-bradycardic episode associated with presyncopal symptoms after 23pL3 min (control, mean pLSE). Head-up tilt made thoracic electrical impedance (3.0pL10Ω), mean arterial pressure (MAP, 86pL4-93pL4 mmHg), heart rate (HR, 63pL3-99pL10 beats min^-1) and total peripheral resistance (TPR, 15pL1-28pL4 mmHg min L^-1) increase, while central venous oxygen saturation (74pL2-58pL4%), cardiac output (5.7pL0.1–3.1pL0.3 L min^-1), stroke volume (95pL6-41pL5 mL) and pulse pressure (55pL4-49pL4 mmHg) decreased (P < 0.05). Central venous pressure decreased during head-up tilt (7pL2-0pL1 mmHg), but it remained stable during the sustained tilt. At the appearance of preswyncopal symptoms MAP (49pL3 mmHg), HR (66pL4 beats min^-1) and TPR (15pL3 mmHg min L^-1) decreased (P < 0.05). Neither metoprolol or propranolo changed tilt tolerance or cardiovascular variables, except for HR that remained at 57pL2 (metoprolol) and 55pL3 beats min^-1 (propranolol), and MAP that remained at 87pL5 mmHg during the first phase with metoprolol. In conclusion, sympathetic activation was crucial for the heart rate elevation during normotensive head-up tilt, but not for tilt tolerance or for the associated hypotension and bradycardia.     

Influence of angiotensin II, α- and β-adrenoceptors on peripheral noradrenergic neurotransmission in canine gracilis muscle in vivo

Interactions between angiotensin II and adrenoceptor-mediated effects on peripheral sympathetic neurotransmission were investigated in constant flow blood-perfused canine gracilis muscle in situ, without and with pretreatment by non-competitive α- adrenoceptor blockade. Angiotensin converting enzyme (ACE)-inhibition by benazeprilat increased nerve stimulation (2 Hz, 4 min)-evoked noradrenaline (NA) overflow (+21 ± 5 yo) with α- adrenoceptors intact, but reduced NA overflow (– 18 ± 6%) when α-adrenoceptors were blocked. Vasoconstrictor responses were slightly reduced by benazeprilat. Subsequent infusion of angiotensin II (Ang 11, 20 and 500 ng kg_-1 min_-1 i.v., raising arterial concentrations from 0.6 ± 0.2 PM to 1390 ± 240 and 25 110 ± 3980 PM, respectively) failed to increase NA overflow or to enhance stimulation-evoked vasoconstriction. Adrenaline (0.4 nmol kg_-1 min_-1 i.v.) did not change evoked NA overflow before or after benazeprilat, either with or without α-adrenoceptor blockade, despite high concentrations (± 10 nM) in arterial plasma. Following benazeprilat, propranolol reduced NA overflow (–24 ± 3 yo) only if the α-adrenoceptors were blocked. In conclusion, benazeprilat reduced evoked NA overflow in the presence of α- adrenoceptor blockade to a similar degree as previously shown in the presence of neuronal uptake inhibition in this model. However, contrasting to our previous findings, benazeprilat enhanced NA overflow and reduced the post-junctional response to nerve stimulation in the absence of α-adrenoceptor blockade. This could be related to bradykinin accumulation during ACE-inhibition, in addition to the reduction of Ang II generation. Our data are not compatible with facilitation of NA release by circulating Ang II even at pharmacological dose levels. Although activation of prejunctional β-adrenoceptors may facilitate evoked NA overflow in this model, circulating adrenaline is ineffective under physiological conditions even after α-adrenoceptor blockade. Also, β-adrenoceptor-mediated prejunctional effects do not seem to involve Ang II in canine skeletal muscle in vivo.     

Acute blockade of β1-receptors in the asphyxiated sheep fetus

Acute blockade of β₁-receptors in the asphyxiated sheep fetus. Acta Physiol Scand 130 , 381–385. Received 5 November 1986, accepted 9 February 1987. ISSN 0001–6772. Department of Paediatrics, Landspitalinn, University Hospital, Reykjavik, Iceland and Department of Physiology and Department of Paediatrics I, University of Goteborg, Sweden. The effects of acute β₁-blockade on fetal cardiovascular reactions during asphyxia were evaluated in 11 exteriorized sheep fetuses. Gestational age was 110–142 days. Asphyxia was induced either by ventilating the mother with low oxygen gas mixture or by mechanical reduction of placental blood flow. During asphyxia all fetuses reacted to metoprolol injection with a decrease in heart rate, myocardial contractility, cardiac output and arterial blood pressure. Five experiments resulted in irreversible fetal cardiovascular collapse. Isoprenaline was given to the fetuses during hypoxia to test the ability to further increase heart rate and activate myocardial β-adrenoceptors. In those experiments with fetal cardiovascular demise after metoprolol, the isoprenaline injection did not result in a significant tachycardia. The surviving fetuses could increase their heart rate as a sign of a capacity to further increase the sympatho-adrenergic drive.     

Modulation of oxotremorine-induced tremor by central β-adrenoceptors

The muscarinic agonist oxotremorine was used to induce tremor in rats pretreated with methylatropine. An objective assessment of tremor intensity was accomplished by means of an accelerometer-based recording system. The non-selective, lipophilic β-adrenoceptor antagonist propranolol dose-dependently suppressed tremor intensity, whereas the r -isomer of propranolol was without effect, verifying β-adrenoceptor involvement. Since the hydrophilic, non-selective β-antagonist nadolol was ineffective, the effect appears to be located inside the blood-brain barrier. The β₂-selective antagonist ICI 118, 551 dose-dependently reduced tremor intensity, whereas selective blockade of β₁-adrenoceptors with metoprolol had no effect, indicating the participation of a β₂-adrenoceptor. On the other hand, the lipophilic β₂-agonist clenbuterol dose-dependently enhanced tremor induced by oxotremorine. Determination of circulating plasma catecholamine concentrations revealed that the effect of β-antagonists on tremor was not secondary to an effect on the oxotremorine-induced rise in catecholamine levels. Thus, the results suggest that β₂-adrenocpetors located inside the blood-brain barrier are able to modulate oxotremorine-induced tremor in rats.     

Prejunctional β2-adrenoreceptor blockade reduces nerve stimulation evoked release of endogenous noradrenaline in skeletal muscle in situ

Prejunctional β-adrenoceptor-mediated modulation of endogenous noradrenaline (NA) overflow elicited by sympathetic nerve stimulation was studied in blood-perfused canine gracilis muscle in situ. An attempt was made to subclassify these β-adrenoceptors by comparing the effects of β₁-selective (metoprolol) and non-selective (propranolol) β-adrenoceptor blockade. Animals were pre-treated with desipramine and phenoxybenzamine in order to counteract possible influences of neuronal uptake and stimulation-evoked changes in vascular resistance on the diffusion of NA into the blood stream. Metoprolol did not decrease stimulation-evoked NA overflow, as compared with control experiments (?10 and ?8 %, respectively). However, propranolol reduced stimulation-evoked NA overflow by 30% in metoprolol pre-treated animals (P < 0.05 vs. control experiments). Both antagonists elevated basal perfusion pressure, suggesting that vascular post-junctional β₁-as well as β₂-adrenoceptors are present. Propranolol increased stimulation-evoked vasoconstriction in metoprolol pre-treated animals, indicating that neuronally released NA may activate postjunctional β₂-adrenoceptors under these experimental conditions. In conclusion, our findings suggest that NA release can be enhanced by activation of prejunctional β₂-adrenoceptors in vivo.     

β1-and β2-adrenoceptor-mediated secretion of amylase from incubated rat parotid gland

The present in vitro investigation was undertaken in an attempt to obtain further information on β-adrenoceptor specificity and action in the rat parotid gland, with regard to amylase secretion. The β₁-selective agonist prenalterol was roughly 800 times more potent than the β₂-agonist terbutaline, and about 5 times more effective than noradrenaline in evoking amylase release. Propranolol was the most effective inhibitor of amylase release in all experiments. The β₁-selective antagonist metoprolol and H104/08 were also effective blockers of maximal noradrenaline-and prenalterol-induced release. The inhibition curves displayed biphasic shapes when amylase secretion was induced by noradrenaline, but not when prenalterol was the secretagogue. The β₂-antagonist H35/25 was without effect on maximal noradrenaline-and prenalterol-stimulated secretion. The amylase release evoked by submaximal concentration of terbutaline was inhibited by the two antagonists H35/25 and IPS 339. In another series of experiments propranolol and metoprolol clearly shifted the noradrenaline concentration-response curve to the right, whereas H35/25 was without effect. The results further demonstrate the major importance of the β₁-adrenoceptor (noradrenaline-activated) in eliciting amylase release from the rat parotid gland. However, it is also suggested that the β₂-adrenoceptors (terbutaline-activated) may to some extent serve the same function.     

Density and functioning of human lymphocytic β-adrenergic receptors during prolonged physical exercise

In order to study the regulation of β-adrenergic receptor number and function in response to prolonged physical effort, lymphocytic β-adrenoceptor density (determined by (-)[¹²⁵I]iodocyanopindolol binding), lymphocytic basal and isoproterenol-stimulated cyclic AMP (cAMP) production and concentrations of plasma catecholamines were measured before and during 3 h running exercise in eight healthy volunteers. A significant (P < 0.01) increase of the lymphocytic β-adrenoceptor density from 45±4 to 81 ± 9 fmol mg^-1 protein (mean ± SEM) took place during the first hour of exercise. As the exercise was continued for up to 2.1–3 h, the receptor densities did not change significantly any more and remained elevated (72 ± 9 fmol mg^-1 protein) in comparison to the resting levels (P < 0.02). The isoproterenol-stimulated cAMP production of the lymphocytes increased during the first hour of running from 190 ± 36 to 269 ± 56 pmol mg^-1 protein (P < 0.01) and returned to the resting level at the end of the exercise (182 ± 38 pmol mg^-1 protein). The mean levels of plasma catecholamines increased ? sixfold during the first hour of exercise and remained elevated until the end of the running. This study demonstrates that the β-adrenergic receptor system is activated in lymphocytes during prolonged aerobic physical exercise. This activated state becomes, however, attenuated within 2–3 h of exercise as indicated by a diminishing ability of β-adrenoceptors to mediate catecholamine-induced cAMP production.     

Beta2-adrenergic attenuation of capillary pressure autoregulation during hemorrhagic hypo tension,a mechanism promoting transcapillary fluid absorption in skeletal muscle

The aim of this study was to evaluate a possible humoral β₂-adrenergic effect on the capillary pressure autoregulation capacity in cat skeletal muscle during bleeding. For this purpose capillary pressure autoregulation in response to graded decrease in arterial pressure was studied in sympathectomized muscle in the control state, and during haemorrhagic hypovolaemia in the presence and absence of selective β₂-adrenoceptor blockade (ICI 118,551). The study was performed with a technique that permits continuous recordings of average capillary pressure in absolute terms and of the regional pre- and postcapillary vascular resistance, from which the pre- to post capillary resistance ratio could be determined. In the pre-haemorrhagic control state, an experimental decrease in arterial pressure from 100 to 50 mmHg caused a fall of capillary pressure from 17.6 by only 1.7 mmHg (ΔP_A/ΔP_c= 29), demonstrating an efficient capillary pressure autoregulation. This autoregulation was accomplished by a decrease in pre- to post capillary resistance ratio in turn being a result of active precapillary dilatation and a passive increase in post capillary vascular resistance. Haemorrhage per se, via a humoral α-adrenergic preferentially precapillary vaso-constriction, caused a decrease in capillary pressure to 16.8 mmHg at arterial pressure 100 mmHg. A superimposed decrease in arterial pressure to 50 mmHg resulted in a capillary pressure fall by 3.7 mmHg (ΔP_A/ΔP_e= 14), indicating impaired autoregulation capacity. This attenuation to a great extent could be ascribed to adrenaline-induced B₂-adrenoceptor stimulation, since β₂-blockade restored the Δ arterial pressure/capillary pressure ratio to 20. Low-dose isoprenaline infusion in the control state similarly caused marked impairment of capillary pressure autoregulation. The β₂-adrenergic attenuation of capillary pressure autoregulation appears to be a beneficial effect in haemorrhagic hypotension, since it lowers capillary pressure passively in relation to the arterial pressure fall, thereby reinforcing the a-adrenergic active capillary pressure decrease, leading to more effective transcapillary fluid absorption and, hence, improved replenishment of plasma volume.     

Autoradiographic location of β-adrenoceptor subtypes in cat colon smooth muscle

In order to localize β-adrenoceptors ¹²⁵I-(—)pindolol (IPIN) was used in binding to sections from cat colon. The binding characteristics for IPIN to β-adrenoceptors on colon sections were estimated by demonstrating reversible binding in the presence of isoprenaline and by steroselective binding to the isomers of propranolol. The binding of IPIN to both β₁-and β₂-adrenoceptors was shown by biphasic displacement curves in the presence of the selective β-adrenoceptor compounds betaxolol, ICI 118.551 and procaterol. The colon sections were found to contain proportions of β₁-adrenoceptors (30–50%) and β₂-adrenoceptors (50–70%). In the autoradiographic studies, 100% of the developed grains after exposure of IPIN to the photographic emulsion were displaced by 50 μm of isoprenaline. By microscopic counting at autoradiographic grains, 30–40% of the grains were found in the circular smooth muscle, while 60–70% of the grains were found in the longitudinal smooth muscle. A concentration of 2 nm ICI 118.551 completely displaced all grains in the circular smooth muscle and partly displaced those found in the longitudinal smooth muscle. A high concentration of ICI 118.551 (1 μm ) displaced all grains above background from the smooth muscle. It is concluded that the circular smooth muscle only contains β₂-adrenoceptors, while longitudinal smooth muscle may contain a proportion of β₁-adrenoceptors. Whether such a location of β-adrenoceptors can be related to the β₁-adrenoceptor-mediated inhibition of colon motility can not be clarified from these studies. However, it seems that β₁-adrenoceptors are located to the longitudinal smooth muscle instead of to the myenteric plexus of the colon.     

α 2 –Adrenoceptor activation may trigger the increased production of endothelium–derived nitric oxide in skeletal muscle during acute haemorrhage

Our previous studies indicated that acute haemorrhage leads to a pronounced increase in the release of endothelium-derived nitric oxide (EDNO) graded in relation to the magnitude of the blood loss. The EDNO-induced vasodilatation, confined selectively to the arterial `feeder' vessels, attenuates the concomitant reflex adrenergic constriction and thereby prevents deleterious reduction of blood flow. The present study aimed at investigating whether the reflex release of blood-borne catecholamines might trigger this EDNO release via activation of endothelial α₂-adrenoceptors. The study was performed on the sympathectomized vascular bed of cat skeletal muscle with a technique permitting quantitative recordings of resistance (tone) in consecutive vascular sections. Selective α₂-adrenoceptor blockade with idazoxan applied at steady state vasoconstriction after a 35% blood loss evoked an initial generalized dilator response (attributable to inhibition of post-synaptic smooth muscle α₂-adrenoceptors), followed by a constrictor response selectively in the arterial feeder vessels, the latter compatible with the hypothesis of reduced EDNO release by α₂-adrenoceptor blockade. More direct evidence for the hypothesis was obtained from studies of the vascular response to EDNO blockade ( L -NAME) after haemorrhage in the presence and absence of α₂-adrenoceptor blockade. The constrictor response to EDNO blockade, which is a measure of the pre-existing EDNO dilator influence (EDNO production), was significantly smaller (P < 0.01) in the presence than absence of α₂-adrenoceptor blockade. The results indicate that blood-borne catecholamines, via activation of endothelial α₂-adrenoceptors, trigger the increase in the EDNO release in acute haemorrhage, implying a functionally important negative feedback in the integrated control of vascular tone in bleeding.     

Identification of deletion and triple α-globin gene haplotypes in the montreal β-thalassemia screening program: Implications for genetic medicine

We obtained blood samples in a screening program designed to detect β-thalassemia heterozygotes in Montreal; additional samples were obtained from referred persons. We analyzed DNA for variant numbers of α-globin genes, notably the α-thalassemia₂ (- α/), α-thalassemia₁, (– –/), and triplicated ζ-globin gene (ααα/) haplotypes using restriction enzymes and probes for α-globin and α-globin gene sequences. We estimated the numbers of Montreal residents of Italian and Greek ethnic origin with –α/αα genotype. Thus, 4.3% of Italians and 1.5% of Greeks, or about 7,500 persons, are estimated to be α-thalassemia₂, trait (silent carriers), largely (80%) in the –α^3.7/type I form. The triplicated α-globin gene haplotype was also found. The risk of a severe (α-thalassemia₁) phenotype associated with inheritance of – –;/αα or –α/ –α genotypes was low and was found predominantly in this study, in persons of Asian ethnic origin. The sample of Asians was too small to estimate carrier frequencies; however, based on results from the β-thalassemia screening program, we estimated that about 4% of Asians (about 1,300 persons) in Montreal are α-thalassemia carriers. We identified persons heterozygous for both β-thalassemia and α-thalassemia mutations. In these double heterozygotes, the effect of the triplicated α-globin gene was to make the erythrocyte parameters used for screening (MCV and %HbA₂) more deviant from normal whereas deletion of 2 α-globin genes tended to normalize the erythrocyte values. These findings have implications for the screening program and reproductive counseling.     

Functional β1 - and β2-adrenoceptors in the human myocardium

Functional β-adrenoceptor populations in the human heart were studied in vitro in electrically-paced strips of the right auricular and ventricular myocardium. The relative potency of selected agonists in producing inotropic responses (T_max, T′_max) in the presence of blockers for neuronal and extraneuronal uptakes was found to be as follows: isoprenaline > noradrenaline = adrenaline = salbutamol > dobutamine. Prenalterol had a negative inotropic effect in these preparations. The selective β₁ -(practoloI) and β₂-(H 35/25) blockers reduced inotropic responses to adrenaline (T_max, T′_max) and noradrenaline (T′_max) in the auricular strips. These results indicate the participation of β₂-adrenoceptors in inotropic responses in the human auricular and ventricular myocardium. For comparison, inotropic responses of electrically-paced rat myocardium to β-adrenergic agonists in the presence of blockers for neuronal and extraneuronal uptakes were likewise studied. The relative potencies for T_max were: noradrenaline = adrenaline > prenalterol > dobutamine = salbutamol. Given the high relative potency of salbutamol in the human myocardial strips (analogous to that previous shown in the β₂-dominated atria of the frog and trout) and the low relative potency of salbutamol in the rat tissue, these findings indicate a greater population of functionally active β₂-adrenoceptors in the human than in the rat myocardium.     

Beta Adrenergic Dilator Component of the Sympathetic Vascular Response in Skeletal Muscle Influence on the micro-circulation and on transcapillary exchange

A neurogenic β-adrenergic vasodilatation in skeletal muscle has been indicated by some recent investigations. The present study describes the extent to which this neurogenic β-dilator mechanism contributes to the integrated vascular response in consecutive sections of the muscle vascular bed during sympathetic nerve activation. This was done by studying the vascular reactions to graded sympathetic stimulation (1–16 Hz) before and after β-adrenoceptor blockade, β-blockade did not influence significantly the sympathetically induced changes of total muscle vascular resistance or capacitance. Vascular tone in the “micro-vessels” during stimulation was, however, clearly more pronounced in the β-blocked than in the non-blocked region, as revealed by segmental resistance analysis and by determination of precapillary sphincter tone (CFC). In addition, β-blockade markedly reduced the net transcapillary absorption of extravascular fluid evoked by nerve activation. This effect could be ascribed to the mentioned influence on the precapillary sphincters, leading to a decrease of the number of capillaries available for transcapillary exchange, and to a limitation of the nerve induced fall of capillary hydrostatic pressure. The described effects of β-blockade were observed at all rates of sympathetic stimulation. — The conclusion was reached that the β-adrenergic dilator component of the sympathetic vascular response in skeletal muscle significantly modifies the α-adrenergic constriction in the micro-vessels. It is suggested that, in the intact organism, this neurogenic β-dilator mechanism is primarily aimed at improving the transcapillary exchange.     

Increased β1-adrenoceptor density after 6-hydroxydopamine pretreatment in rat colon and lung

Estimation of β-adrenoceptor-binding sites with ¹²⁵I-(-)-pindolol in rat colon show a proportion of 30%β₁,-adrenoceptors and 70%β₂-adrenoceptors. Studies on the isolated colon strip have revealed a neuronal β-adrenoceptor involved in the inhibitory response of colon motility to β-adrenoceptor stimulation. In order to further characterize the β-adrenoceptors in the colon, acute and chronic treatments with 6-hydroxydopamine were made. Both acute pretreatment of rats with 6-hydroxydopamine for 8 and 24 h (one intravenous injection) and chronic treatment for 3 days (implanted osmotic mini-pumps), reduced the noradrenaline tissue content by 90%, and successively increased the β-adrenoceptor-binding sites from 14.3 to 21.7 fmol mg^_1 P^_1 in colon and from 158 to 240 fmol mg^-1 P^_1 in lung membranes. Displacement of the radiolabelled ligand by the selective β-adrenoceptor antagonists, pafenolol and ICI 118.551 showed that the density of β₁,-adrenoceptor binding sites was more than doubled, whereas the density of β₂-adrenoceptor-binding sites was only marginally increased by chronic treatment with 6-hydroxydopamine. Thus sympathetic denervation by 6-hydroxydopamine treatment produced a selective increase in β₁-adrenoceptors in the rat colon. These results may indicate that stimulation of β₁-adrenoceptors in both colon and lung have a neuronal linkage.