Angiotensin II infusion during β-adrenergic stimulation by isoproterenol. Effects on hepatic,splenic and cardiac blood volumes and on the magnitude and distribution of cardiac output in the dog

The cardiac and peripheral vascular adjustments to angiotensin II (0.1–0.2 μg kg^-1 min^-1 i.v.) during high β-adrenergic activity by a continuous isoproterenol infusion (0.2–0.3 μg kg^-1 min^-1 i.v.) were examined in anaesthetized, atropinized dogs. Hepatic, splenic and left ventricular (LV) volume changes were estimated by an ultrasonic-technique, and the blood flow distribution was measured by injecting radioactive microspheres and by electromagnetic flowmetry on the caval veins, the hepatic artery and the portal vein. During isoproterenol infusion, angiotensin II increased the systolic LV pressure by 45 ± 3 mmHg and the stroke volume by 17 ± 6 %. Concomitantly, the hepatic and splenic blood volumes declined by 29 ± 4 and 14 ± 6 ml, respectively, and the LV end-diastolic segment length increased by 3 ± 1 %. The flow through the inferior caval vein increased by 39 ± 9%, whereas the superior vena caval flow remained unchanged. The hepatic arterial flow more than doubled. Thus, at high inotropy by isoproterenol infusion, angiotensin II relocates blood from the liver and the spleen towards the heart. By activating the Frank-Starling mechanism, cardiac output is increased and conducted through the lower body, especially through the hepatic artery, because of the poor autoregulation of flow through this vessel.,     

Effect of Substance P on Various Vascular Beds in the Dog

Using the electromagnetic flowmeter technique, the blood flow in the aorta, carotid, hepatic, superior mesenteric, renal and femoral arteries and portal vein was recorded during continuous i.v. infusion of synthetic Substance P (SP) in 8 dogs. Systemic and portal blood pressures were recorded. A significant decrease in mean arterial blood pressure was recorded at infusion of SP in the femoral vein at a rate of 2.5 ng × min^-1× kg b.w.^-1 or higher. Portal venous blood pressure increased. A rapid increase in the carotid, hepatic, mesenteric and portal blood flow was obtained at infusion rates of 1.2 ng × min^-1× kg b.w.^-1 or higher. The femoral artery responded with a late, transient increase in flow, with a return to the base level while the infusion was still in progress. The renal artery blood flow decreased slightly at low infusion rates and increased at higher. At SP infusions in the portal vein the infusion rate had to be increased to 20 ng × min^-1× kg b.w.^-1 or higher before any general vascular reactions were recorded, indicating that the liver has a high capacity for inactivating SP.     

Blood flow in the rabbit tenuissimus muscle Influence of preparative procedures for intravital microscopic observation

LINDBOM, L., TUMA, R. F. & ARFORS, K.-E.: Blood flow in the rabbit tenuissimus muscle: Influence of preparative procedures for intravital microscopic observation. Acta Physiol Scand 1982, 114 :121–127. Received 21 April 1981. ISSN 0001–6772. Department of Experimental Medicine, Pharmacia AB, Uppsala, Sweden. The tenuissimus muscle in the rabbit and the cat is a suitable tissue for intravital microscopic investigation of skeletal muscle blood flow. In this study the influence of surgical procedures necessary for direct microscopic observation on the physiological state of the rabbit tenuissimus muscle was assessed by means of blood flow measurements. Mean resting blood flow was 2.8±0.8 (mean ± S.D.) ml. min^-1. 100 g^-1 in the left tenuissimus muscle when prepared for microscopic observation as determined by the radioactive microsphere method. This value was not significantly different from that in the intact unexposed muscle in the contralateral leg, 3.3 ±1.1 ml. min^-1. 100 g^-1. Exposure of the muscle to atmospheric oxygen tension resulted in a reduction of blood flow to 0.7±0.4 ml. min^-l. 100g^-l, suggesting that local metabolic control mechanisms were active. The normal range of vascular control seemed to be maintained, as demonstrated by an increase in blood flow to 64.2± 18.8 ml. min-¹. 100 g^-l during “maximal” vasodilation induced by topical application of PGE₁. The tenuissimus muscle showed a marked sensitivity to mechanical stimulation. Slight stretching of the muscle, similar to what may occur during surgical preparation, resulted in an increase in blood flow to 17.5±5.7 ml. min^-1. 100 g^-1. Flow values calculated from data obtained by direct microscopic measurements in the tenuissimus muscle agreed well with those obtained by the microsphere method.     

Anaerobic and aerobic power of top athletes

Summary In this study the alactic anaerobic and aerobic power of top level sprinters, long-distance runners, and untrained students were compared. Maximal oxygen uptake was measured during a progressive test on a treadmill. The anaerobic power was estimated according to a newly developed bicycle ergometer technique. As reported elsewhere, the maximal oxygen uptake is very high in twelfe long-distance runners (77.6±2.7 ml/kg·min⁻¹) whereas the maximal oxygen uptake of six sprinters amounts to 60.1±5.9 ml/kg·min⁻¹. The average alactic anaerobic power of a control group of 32 students was 710 W or 10.1±1.2 W/kg. Significantly lower results were obtained by long-distance runners (551 W or 8.93 W/kg) whereas significantly higher results were obtained by sprinters (1,021 W or 14.16 W/kg). In top level athletes, but not in the control group, a negative relationship was found between aerobic power and anaerobic power.     

Effect of Physical Training on Hemodynamic Response during Submaximal and Maximal Exercise in 11–13-Year Old Boys

Nine healthy boys, mean age 11.7 years (11.0–13.0), height 150.4 cm and weight 45.1 kg, were examined with determinations of maximal oxygen uptake (1.85 1×min^-1), heart volume (499 ml) and total hemoglobin (391 g). Cardiac output was determined at rest and during exercise, including maximal exercise, using the dye-dilution technique and i.a. pressures were recorded. Cardiac output was approximately 2 1×min^-1 lower and the systemic a-v oxygen difference (AVD) was correspondingly higher than for young adult men at the same sub-maximal oxygen uptake. At maximal exercise cardiac output was 12.5 1×min^-1, stroke volume 67 ml, AVD 14.2 ml × 100 ml^-1, systolic, diastolic and mean blood pressure 160, 71 and 105 mm Hg respectively and total peripheral resistance 8.6 mm Hg×1–¹×min. After a training period of 4 months a normal increase in height was found in all boys, but body weight was unchanged. Maximal oxygen uptake increased to 2.21 1×min^-1 (p < 0.01), almost entirely due to increased stroke volume (80 ml), resulting in a maximal cardiac output of 14.6 1×min^-1. No significant increase in AVD was found. Mean blood pressure at maximal exercise increased significantly, total peripheral resistance was unchanged. Both heart volume and total hemoglobin showed minor increases, but the changes found were not significantly larger than expected from body growth. The hemoglobin concentration was normal (13 g%) for the age and unaffected by training.     

Effects of indomethacin on regional blood flow in conscious rabbits—a microsphere study

In an attempt to reveal the importance of prostaglandins in the control of regional blood flow 20 mg/kg b.wt. indomethacin was given i.v. in conscious resting rabbits. Regional blood flow determinations were made before and 20 min after the injection using the labelled microsphere technique. The blood flow in the stomach wall was reduced by 0.75 ± 0.17 g·min^-1·g^-1 from a level of 1.64 ± 0.24 g·min^-1·g^-1. In jejunum the corresponding figures were 0.44 ± 0.12 and 1.26 ± 0.17 and in the brain 0.29 ± 0.10 and 1.24 ± 0.10. The blood flow in the liver via the hepatic artery increased by 0.20 ± 0.02 g·min^-1·g^-1 from a level of 0.13 ± 0.02 g·min^-1·g^-1. In the retina there was a reduction in blood flow by 2.75 ± 1.03 mg·min^-1 from a starting level of 15.1 ± 2.3 mg·min^-1. In a number of other tissues investigated there were no significant effects of the drug. The results suggest that under resting conditions prostaglandins play a role in the control of blood flow in the gastrointestinal tract, the brain and the retina—tissues which are likely to be rather active under such conditions.     

Cardiovascular responses during one- and two-legged exercise in middle-aged men

Eight healthy and regularly physically active men, 44–69 years old, performed one- and two-legged dynamic knee extension exercise at increasing work intensities, including one leading to exhaustion. Leg blood flow increased linearly in relation to work rate, reaching a peak value of 5.1 ±0.4 1 min^-1. With a mean weight of quadriceps femoris of 2.2 ±0.1 kg, a peak perfusion of 2.3 ±0.11 kg^-1 min^-1 was attained. The maximal leg oxygen uptake was 0.72 ±0.071 min^-1 (0.33 ±0.03 1 kg^-1 min^-1). At submaximal work the elevation in limb oxygen uptake accounted for between 70 and 100% of the rise in pulmonary oxygen uptake. Comparing two- with one-legged knee extension the cardiac output was 1.5 1 min^-1 higher at each work level, reaching 13.7±0.7 and 12.3 ± 1.0, respectively at exhaustion, leaving 3.5 and 7.2 1 min^-1 of blood flow to the remaining body (cardiac output –leg blood flow). The mean arterial pressure was 119 ±5 mmHg at rest and increased to 155 mmHg for both test modes at the maximal work rate. The femoral arterial and venous plasma concentrations of lactate, ammonia and noradrenaline were significantly higher for two-legged as compared with one-legged exercise at the maximal load performed. However, the rate of release per leg, for both lactate and ammonia, did not differ between the two test conditions. It is concluded that physically active middle-aged men, with a well-retained muscle mass, can maintain a high skeletal muscle perfusion, similar to that of young males. However, the blood flow is achieved with a higher mean arterial pressure and an elevated sympathetic activity, as reflected by noradrenaline in plasma and spillover from the exercising limb.     

Role of adenosine in exercise‐induced human skeletal muscle vasodilatation

The role of adenosine in exercise‐induced human skeletal muscle vasodilatation remains unknown. We therefore evaluated the effect of theophylline‐induced adenosine receptor blockade in six subjects and the vasodilator potency of adenosine infused in the femoral artery of seven subjects. During one‐legged, knee‐extensor exercise at ～48% of peak power output, intravenous (i.v.) theophylline decreased (P < 0.003) femoral artery blood flow (F_aBF) by ～20%, i.e. from 3.6 ± 0.5 to 2.9 ± 0.5 L min^?1, and leg vascular conductance (VC) from 33.4 ± 9.1 to 27.7 ± 8.5 mL min^?1 mmHg^?1, whereas heart rate (HR), mean arterial pressure (MAP), leg oxygen uptake and lactate release remained unaltered (P = n.s.). Bolus injections of adenosine (2.5 mg) at rest rapidly increased (P < 0.05) F_aBF from 0.3 ± 0.03 L min^?1 to a 15‐fold peak elevation (P < 0.05) at 4.1 ± 0.5 L min^?1. Continuous infusion of adenosine at rest and during one‐legged exercise at ～62% of peak power output increased (P < 0.05) F_aBF dose‐dependently to level off (P = ns) at 8.3 ± 1.0 and 8.2 ± 1.4 L min^?1, respectively. One‐legged exercise alone increased (P < 0.05) F_aBF to 4.7 ± 1.7 L min^?1. Leg oxygen uptake was unaltered (P = n.s.) with adenosine infusion during both rest and exercise. The present findings demonstrate that endogenous adenosine controls at least ～20% of the hyperaemic response to submaximal exercise in skeletal muscle of humans. The results also clearly show that arterial infusion of exogenous adenosine has the potential to evoke a vasodilator response that mimics the increase in blood flow observed in response to exercise.     

Cardiovascular and ventilatory responses to electrically induced cycling with complete epidural anaesthesia in humans

Cardiovascular and ventilatory responses to electrically induced dynamic exercise were investigated in eight healthy young males with afferent neural influence from the legs blocked by epidural anaesthesia (25 ml 2% lidocaine) at L3-L4. This caused cutaneous sensory anaesthesia below T8-T9 and complete paralysis of the legs. Cycling was performed for 22.7 ± 2.7 min (mean, SE) (fatigue) and oxygen uptake (Vo₂) increased to 1.90 ± 0.13 1 min^-1. Compared with voluntary exercise at the same Vo₂, increases in heart rate (HR) (135 ± 7 vs. 130 ± 9 beats min^-1) and cardiac output (16.9 ± 1.1 vs. 17.3 ± 0.9 1 min^-1) were similar, and ventilation (54 ± 5 vs. 45 ± 4 1 min^-1) was higher (P < 0.05). In contrast, the rise in mean arterial blood pressure during voluntary exercise (93 ± 4 (rest) to 119 ± 4 mmHg (exercise)) was not manifest during electrically induced exercise with epidural anaesthesia [93 ± 3 (rest) to 95 ± 5 mmHg (exercise)]. As there is ample evidence for similar cardiovascular and ventilatory responses to electrically induced and voluntary exercise (Strange et al. 1993), the present results support the fact that the neural input from working muscle is crucial for the normal blood pressure response to exercise. Other haemodynamic and/or humoral mechanisms must operate in a decisive manner in the control of HR, CO and VE during dynamic exercise with large muscle groups.     

Intravenous bilirubin infusion causes vacuolization of the cytoplasm of hepatocytes and canalicular cholestasis

To examine whether intravenous bilirubin infusion causes cholestasis and impairs liver metabolism, bile secretion and ethanol clearance were measured in 34 anaesthetized pigs before and after intravenous infusion of 0.5 μmol kg^-1 min^-1 bilirubin for 4.5 hours. Bilirubin infusion increased plasma bilirubin to 556±76 μmol l^-1 and hepatic tissue bilirubin to 3.5 ± 1.3 mmol kg tissue weight^-1. Bilirubin infusion depressed bilirubin secretion and net hepatic uptake of cholate and taurocholate, and caused a 86±6% reduction of cholate-induced bile secretion. Bilirubin caused formation of large cytoplasmic vacuoles in hepatocytes and dilatation of bile canaliculi. Ethanol clearance and secretin-dependent ductular bile secretion were unaffected by bilirubin. We conclude that intravenous infusion of unconjugated bilirubin causes accumulation of bilirubin in the liver, vacuolization of the hepatocyte cytoplasm and canalicular but not ductular cholestasis. The canalicular cholestasis is not due to impaired hepatic mitochondrial energy metabolism, but may be due to inhibition of a common pathway for lipid, bilirubin and bile salt secretion from hepatocytes.     

前列地尔Lipo-PGE1干预肝脏血流灌注的实验研究

目的： 探讨前列地尔脂微球(liposome prostaglandin E₁,Lipo-PGE₁) 不同用药时间和途径对肝脏血流灌注的作用机制。方法: 选取健康成年犬12只，经左小隐静脉注射Lipo-PGE₁₁ μg/kg，速度均为0.05 μg·kg^-1·min^-1。分别于0 min、5 min、15 min、30 min后行肝脏CT灌注成像（computed tomography perfusion imaging，CTPI）扫描，计算肝动脉灌注量(hepatic arterial perfusion,HAP)、门静脉灌注量 (portal vein perfusion,PVP)、总肝灌注量（total liver perfusion,TLP），对照分析不同时间Lipo-PGE1对肝脏血流灌注的影响。选取健康成年犬24只，随机平均分成4组：对照组、外周静脉用药组、肝动脉组、肠系膜上动脉组。Lipo-PGE₁的用药量均为1 μg/kg、用药速度均为0.05 μg·kg^-1·min^-1，0.9%生理盐水用量为20 mL。各组用药5 min后行肝脏CTPI，比较分析不同途径给予Lipo-PGE₁对肝脏血流灌注的影响。结果: 经外周静脉注射Lipo-PGE10 min、5 min、15 min、30 min后CTPI测量的HAP(mL·min^-1·mL^-1)分别为：0.22 ±0.65、0.24±0.65、0.22±0.69、0.22±0.06；PVP (mL·min^-1·mL^-1)：1.22±0.40、1.88±0.59、1.55±0.55、1.29 ±0.57；TLP (mL·min^-1·mL^-1)分别为：1.44±0.42、2.12±0.61、1.77±0.56、1.51±0.58。方差分析显示HAP组间比较无显著差异（F=0.249，P>0.05），而PVP、TLP组间比较有显著差异（F=3.812，P<0.05）、（F=3.805，P<0.05）。5 min组PVP、TLP增加最为显著，15 min、30 min时两者仍处于高值水平。对照组和外周静脉组、肝动脉组、肠系膜上动脉组的HAP (mL·min^-1·mL^-1)分别为：0.22±0.06、0.24±0.06、0.31±0.07、0.26±0.05；PVP (mL·min^-1·mL^-1)分别为1.28±0.38、2.33±0.41、2.37±0.55、2.83±0.94；TLP (mL·min^-1·mL^-1)分别为：1.50±0.40、2.57±0.42、2.67±0.58、3.09±0.94。方差分析显示HAP组间比较无显著差异（F=2.248，P>0.05），而PVP、TLP组间比较有显著差异（F=6.892，P<0.01）、（F=7.802，P<0.01）。经肠系膜上动脉给药较其它途径给药PVP、TLP增加趋势更为显著。结论: Lipo-PGE₁能显著增强肝脏血流灌注，且主要影响门静脉灌注分量，介入技术可为快速改善肝血流灌注提供有效途径。     

Inhibitory effect of endothelin on renin release in dog kidneys

To investigate the effect of endothelin on renin release, experiments were performed in barbiturate-anaesthetized dogs with denervated kidneys. Intrarenal infusion of endothelin (1 ng min^-1kg^-1body wt) reduced renal blood flow (RBF) from 145 ± 10 ml min^-1to 98 ± 9 ml min^-1without altering renin release (1 ± 1 μg angiotensin I (AI) min^-1). Renin release was then increased either by renal arterial constriction or ureteral occlusion. When renal arterial pressure was reduced to 50 mmHg, renin release averaged 79 ± 20 μg AI min^-1in six dogs and fell significantly to 24 ± 6 μg AI min^-1during endothelin infusion. During ureteral occlusion the inhibitory effect of endothelin on renin release either during inhibition of β-adrenergic activity with propranolol or after inhibiting prostaglandin synthesis by indomethacin during intrarenal infusion of isoproterenol was examined. After propranolol administration ureteral occlusion increased renin release from 5 ± 2 μg AI min^-1to 38 ± 12 μg AI min^-1in six dogs. Subsequent intrarenal endothelin infusion (1 ng min^-1kg^-1body wt) during maintained ureteral occlusion reduced renin release to 10 ± 3 μg AI min^-1. In six other dogs prostaglandin synthesis was inhibited by indomethacin. Subsequent infusion of isoproterenol (0.2 μg min^-1kg^-1body wt) to stimulate β-adrenoceptor activity increased renin release from 13 ± 4 μg AI min^-1to 68 ± 8 μg AI min^-1during ureteral occlusion. Intrarenal endothelin infusion (1 ng min^-1kg^-1body wt) reduced renin release to 22 ± 3 μg AI min^-1during continuous isoproterenol infusion and ureteral occlusion. Hence endothelin inhibits renin release induced by renal arterial constriction or ureteral occlusion. Similar inhibitory effects whether renin release was raised by increasing prostaglandin synthesis or by stimulating β-adrenergic activity suggest a direct effect of endothelin on the juxtaglomerular cells.     

High afterload during 10 min of regional ischaemia affects diastolic creep but not systolic function in reperfused (stunned) myocardium

The effect of afterload during regional ischaemia on myocardial stunning was studied in 15 pentobarbital anaesthetized cats. 10 min occlusion of the left anterior descending artery (LAD) was followed by 60 min of reperfusion. Afterload was decreased by intravenous infusion of nitroglycerine 3–8 μg kg^-1 min^-1 in group I (n=8); left ventricular peak systolic pressure (LVSP) 84±4 mmHg (mean±SEM) during coronary artery occlusion. In group II (n=7) LVSP was increased to 188±10 mmHg by inflating an intraaortic balloon during coronary artery occlusion. Regional function in the LAD perfused region was evaluated by cross-oriented sonomicrometry. Myocardial tissue blood flow was evaluated by radio-labelled microspheres. Afterload alterations did not affect regional systolic shortening (10.8±2.0% vs. 11.0±1.5% in group I and II, respectively, after 60 min of reperfusion). However, increased end-diastolic dimensions (diastolic creep) in both the circumferential and longitudinal segments were markedly more pronounced in the high afterload group (group II). Also important, the markedly increased myocardial tissue blood flow during reperfusion in group II as compared with group I (2.30±0.18 vs.  1.34±0.08 mL min^-1 g^-1 and 2.58±0.23 vs. 1.49±0.07 mL min^-1 g^-1 in subepicardial and subendocardial layers in the LAD perfused region) suggests that increased diastolic creep increased metabolic demands. This study indicates that passive stretching of the ischaemic area during coronary artery occlusion is an important mechanism behind diastolic creep.     

Maximal oxygen uptake in Danish adolescents 16–19 years of age

Summary A random sample of schoolchildren, 119 boys and 153 girls, was tested in the fall of 1983. The data presented here are anthropometric data (height, weight, fat % and vital capacity) and oxygen uptake directly measured on a bicycle ergometer. The mean height and weight for boys were 179.1 cm and 67.7 kg, and those for girls were 168.0 cm and 59.6 kg. The mean fat content was 9.1% for boys and 19.1% for girls, and their mean vital capacities were 4.91 and 3.61 respectively. The boys had a high maximal oxygen uptake (51.7 ml · kg^–1 · min^–1) showing no reduction over the age span studied. The girls' maximal oxygen uptake was lower (overall mean 40.0 ml · kg^–1 · min^–1) with a small reduction from 16 to 19 years of age. When comparing maximal oxygen uptake per kg lean body mass in the two sexes, the boys had 18.4% higher values than the girls, indicating that girls of this age have the lower fitness level. The results of maximal aerobic power measurement in the boys compare well with findings from other investigations using direct measurements, indicating that the fitness of teenage boys is kept at a high level. Comparable data from various countries for girls show different pictures, but it appears that in general they have a low fitness level.     

Long-lasting coronary vasoconstrictor effects and myocardial uptake of endothelin-1 in humans

The effect of intravenous administration of the endothelium-derived vasoconstrictor peptide endothelin-1 (ET-1 0.2, 1 and 8 pmol kg^?1 min^?1) on coronary blood flow in relation to plasma ET-1 as well as blood lactate and glucose levels were investigated in six healthy volunteers. Coronary sinus blood flow was measured by thermodilution. Administration of ET-1 elevated arterial plasma ET 35-fold, dose-dependently increased mean arterial blood pressure from 95±5 mmHg to 110±6 mmHg (P<0.01) and reduced heart rate from 64±4 beats min^?1 to 58±4 beats min^?1 (P<0.05) at 8 pmol kg^?1 min^?1. Coronary sinus blood flow was reduced maximally by 23±4% (P<0.01) and coronary vascular resistance increased by 48±11% (P<0.01). Coronary sinus oxygen saturation decreased from 35±1% to 22±2% at 2 min after the infusion (P<0.01). A coronary constrictor response was observed at a 4-fold elevation in plasma ET. The reduction in coronary sinus blood flow lasted 20 min and coronary sinus oxygen saturation was still reduced 60 min after the infusion. Myocardial oxygen uptake or arterial oxygen saturation were not affected by ET-1. Myocardial lactate net uptake decreased by 40% whereas glucose uptake was unaffected. At the highest infusion rate there was a net removal of plasma ET by 24±3% over the myocardium (P<0.05). The results show that ET-1 induces long-lasting reduction in coronary sinus blood flow via a direct coronary vasoconstrictor effect in healthy humans observable at a 4-fold elevation in plasma ET-1. Furthermore, there is a net removal of circulating ET-1 by the myocardium.     

Importance of nitric oxide in hepatic arterial blood flow and total hepatic blood volume regulation in pigs

The importance of nitric oxide in regulating basal arterial blood flow has been examined in several different vascular beds by intra-arterial infusion of inhibitors of nitric oxide synthesis, but not in the arterial vascular bed of the liver. In the present study, N^G-nitro-L -arginine (L -NNA), in a dose of 0.5 and 1.0 μmol mL^?1 of hepatic arterial blood flow, was infused for 5 min into the hepatic artery in seven pigs anaesthetized with pentobarbital sodium. The haemodynamic effects observed by the first infusion were not further enhanced by the second infusion. Hepatic arterial resistance increased by 143 ± 38% and hepatic arterial blood flow declined by 38 ± 10%. A systemic effect due to `spillover' was observed, as evidenced by an increase in mean aortic blood pressure of 24 ± 4 mmHg. However, no significant increase in arterial mesenteric resistance was observed and total liver blood flow remained unchanged. Hepatic arterial vasodilation in response to occlusion of the portal vein, the arterial buffer response, remained intact after inhibition of nitric oxide synthesis. Liver lobe thickness, measured by an ultrasonic technique,was not found to change with inhibition of arterial nitric oxide synthesis, excluding a significant direct effect of arterial nitric oxide on liver capacitance. In conclusion, nitric oxide is an important regulator of hepatic arterial resistance, but does not mediate the hepatic arterial buffer response and was not found to play any significant role in total hepatic capacitance regulation.     

Power output and muscle metabolism during and following recovery from 10 and 20 s of maximal sprint exercise in humans

On two separate days eight male subjects performed a 10- or 20-s cycle ergometer sprint (randomized order) followed, after 2 min of recovery, by a 30-s sprint. Muscle biopsies were obtained from the vastus lateralis at rest, immediately after the first sprint and after the 2 min of recovery on both occasions.The anaerobic ATP turnover during the initial 10 s of sprint 1 was 129 ± 12 mmol kg dry weight^?1 and decreased to 63 ± 10 mmol kg dry weight^?1 between the 10th and 20th s of sprint 1. This was a result of a 300% decrease in the rate of phosphocreatine breakdown and a 35% decrease in the glycolytic rate. Despite this 51% reduction in anaerobic ATP turnover, the mean power between 10 and 20 s of sprint 1 was reduced by only 28%. During the same period, oxygen uptake increased from 1.30 ± 0.15 to 2.40 ± 0.23 L min^?1, which partially compensated for the decreased anaerobic metabolism. Muscle pH decreased from 7.06 ± 0.02 at rest to 6.94 ± 0.02 after 10 s and 6.82 ± 0.03 after 20 s of sprinting (for all changes P < 0.01). Muscle pH did not change following a 2-min recovery period after both the 10- and 20-s sprints, but phosphocreatine was resynthesized to 86 ± 3 and 76 ± 3% of the resting value, respectively (n.s. 10- vs. 20-s sprint). Following 2 min of recovery after the 10-s sprint subjects were able to reproduce peak but not mean power. Restoration of both mean and peak power following the 20-s sprint was 88% of sprint 1, and was lower compared with that after the 10-s sprint (P < 0.01). Total work during the second 30-s sprint after the 10- and the 20-s sprint was 19.3 ± 0.6 and 17.8 ± 0.5 kJ, respectively (P < 0.01). As oxygen uptake was the same during the 30-s sprints (2.95 ± 0.15 and 3.02 ± 0.16 L min^?1), and [Phosphocreatine] before the sprint was similar, the lower work may be related to a reduced glycolytic ATP regeneration as a result of the higher muscle acidosis.     

V˙O2peak and the gas-exchange anaerobic threshold during incremental arm cranking in able-bodied and paraplegic men

Resting energy expenditure, peak oxygen uptake (V˙O_2peak) and the gas-exchange anaerobic threshold (Th_an) were measured during incremental arm cranking (15?W?·?min^?1) in six able-bodied (AB) and six paraplegic (P) subjects. Only male subjects with traumatic spinal cord injuries in the area of the 10–12th thoracic segment were included in the P group. All AB and P subjects were physically active. Mean (SE) values for age and body mass were 28 (2)?years and 78.9 (3.9)?kg for the AB group and 32 (4)?years and 70.8 (7.9)?kg for the P group (P?>?0.05). Resting energy expenditure values were not found to be significantly different between AB [5.8 (0.2)?kJ?·?min^?1] and P [5.1 (0.3)?kJ?·?min^?1] subjects. Mean V˙O_2peak values were 29.3 (2.4)?ml?· kg^?1?· min^?1 and 29.6 (2.2)?ml?·?kg^?1?·?min^?1 for the AB and P groups, respectively (P?>?0.05). Absolute oxygen uptake values measured at two gas-exchange anaerobic threshold (Th_an) were not significantly different between the two groups. However, the Th_an occurred at a significantly higher percentage of V˙O_2peak in the P [58.9 (1.7)%] group than in the AB [50.0 (2.8)%] group (P?R) values obtained at the Th_an and at 15, 45, 60, 75 and 90?W of incremental exercise were significantly lower in the P group than in the AB group. Heart rates were significantly elevated at every submaximal work stage (15–120?W) in the P group compared to the AB group (P?R) during arm exercise. These local adaptations may be in part responsible for the significantly higher Th_an observed for arm exercise in P subjects, even though V˙O_2peak values were essentially the same for both groups.     

Functional significance of collateral blood flow in working skeletal muscle of the dog

Summary The semitendinosus muscle of the dog is supplied by two separate arteries and drained by two corresponding veins. In the muscles used in this study no blood entering via the distal artery was found to leave via the proximal vein during perfusion through both arteries (orthograde perfusion). Therefore, collateral flow (CF) could be determined as proximal venous outflow during occlusion of the proximal artery. During orthograde perfusion total blood flow averaged 12 ml × min⁻¹ × 100 g⁻¹ at rest and 58.4 ml × min⁻¹ × 100 g⁻¹ during exercise. CF was found to average 6.2 ml × min⁻¹ × 100 g⁻¹ at rest and increased to 9.2 ml × min⁻¹ × 100 g⁻¹ during exercise. CF was sufficient to cover the metabolic demand of resting muscle. During exercise the O₂-uptake ( ) of the distal muscle portion was increased 13.4 fold in comparison to a 3.1 fold increase in the proximal muscle portion. The average contractile power decreased by 46%. Additional infusion of adenosine into the distal artery resulted in an increase of CF to 11.4 ml × min⁻¹ × 100 g⁻¹ and of orthograde flow to 71 ml × min⁻¹ × 100 g⁻¹. The average contractile power of the muscle increased by 13%. Both orthograde flow and CF were found to decrease with increasing muscle load. But this decrease was significantly more pronounced in the case of CF especially at a. lower range of loads. It is concluded that after acute occlusion of orthograde flow, CF is limited by the number, the size and the dilatory capacity of precapillary network vessels. Furthermore, CF is influenced considerably by changes of extravascular support. Presented in part at the 43rd Meeting of the Deutsche Physiologische Gesellschaft [9] and at the XXVI International Congress of Physiological Sciences, New Delhi [6] Supported by the Deutsche Forschungsgemeinschaft (Hi 137/6)     

Skeletal muscle glycolysis during submaximal exercise following acute β-adrenergic blockade in man

The present study describes the influence of β-adrenergic blockade on glycogen utilization and lactate accumulation in skeletal muscle of exercising man. Twelve physically active men were examined during 25 min of continuous cycle exercise equivalent to 65% of their maximal oxygen uptake both with and without oral administration of 80 mg of propranolol (Inderal®). Heart rate, oxygen uptake, rate of perceived exertion (RPE) and blood lactate concentration were measured during exercise. Muscle biopsies were obtained from m. vastus lateralis after 5 and 25 min of exercise, β-adrenergic blockade decreased steady state exercise heart rate by (mean + SD) 35 ± 10 beats min^-1 (P < 0.001) and oxygen uptake from 2.47 to 2.39 1-min^-1 (P < 0.01). Muscle glycogen decreased from the 5th to the 25th min of exercise, and β-blockade had no significant effect on this decrease. In contrast to without drug, β-blockade resulted in a decrease (P < 0.05) in muscle lactate concentration from the 5th (6.9 mmolkg^-1 w./w.) to the 25th min (4.8 mmolkg^-1 w./w.). Similarly blood lactate levels were lower (P < 0.05) with than without β-blockade in the last but not the first 10 min of exercise. The alteration in muscle lactate concentration pattern following β-blockade, may imply that adrenergic effects per se contribute to the stimulation of glycolysis during submaximal exercise, except in its earliest phase. Nevertheless, the effect is not great enough to produce substantial differences in glycogen utilization.