Combined inhibition of nitric oxide and prostaglandins reduces human skeletal muscle blood flow during exercise

The vascular endothelium is an important mediator of tissue vasodilatation, yet the role of the specific substances, nitric oxide (NO) and prostaglandins (PG), in mediating the large increases in muscle perfusion during exercise in humans is unclear. Quadriceps microvascular blood flow was quantified by near infrared spectroscopy and indocyanine green in six healthy humans during dynamic knee extension exercise with and without combined pharmacological inhibition of NO synthase (NOS) and PG by l -NAME and indomethacin, respectively. Microdialysis was applied to determine interstitial release of PG. Compared to control, combined blockade resulted in a 5- to 10-fold lower muscle interstitial PG level. During control incremental knee extension exercise, mean blood flow in the quadriceps muscles rose from 10 ± 0.8 ml (100 ml tissue)⁻¹ min⁻¹ at rest to 124 ± 19, 245 ± 24, 329 ± 24 and 312 ± 25 ml (100 ml tissue)⁻¹ min⁻¹ at 15, 30, 45 and 60 W, respectively. During inhibition of NOS and PG, blood flow was reduced to 8 ± 0.5 ml (100 ml tissue)⁻¹ min⁻¹ at rest, and 100 ± 13, 163 ± 21, 217 ± 23 and 256 ± 28 ml (100 ml tissue)⁻¹ min⁻¹ at 15, 30, 45 and 60 W, respectively ( P < 0.05 vs. control). In conclusion, combined inhibition of NOS and PG reduced muscle blood flow during dynamic exercise in humans. These findings demonstrate an important synergistic role of NO and PG for skeletal muscle vasodilatation and hyperaemia during muscular contraction.     

Neurovascular responses to mental stress

The effects of mental stress (MS) on muscle sympathetic nerve activity (MSNA) and limb blood flows have been studied independently in the arm and leg, but they have not been studied collectively. Furthermore, the cardiovascular implications of postmental stress responses have not been thoroughly addressed. The purpose of the current investigation was to comprehensively examine concurrent neural and vascular responses during and after mental stress in both limbs. In Study 1, MSNA, blood flow (plethysmography), mean arterial pressure (MAP) and heart rate (HR) were measured in both the arm and leg in 12 healthy subjects during and after MS (5 min of mental arithmetic). MS significantly increased MAP (Δ15 ± 3 mmHg; P < 0.01) and HR (Δ19 ± 3 beats min⁻¹; P < 0.01), but did not change MSNA in the arm (14 ± 3 to 16 ± 3 bursts min⁻¹; n = 6) or leg (14 ± 2 to 15 ± 2 bursts min⁻¹; n = 8). MS decreased forearm vascular resistance (FVR) by −27 ± 7% ( P < 0.01; n = 8), while calf vascular resistance (CVR) did not change (−6 ± 5%; n = 11). FVR returned to baseline during recovery, whereas MSNA significantly increased in the arm (21 ± 3 bursts min⁻¹; P < 0.01) and leg (19 ± 3 bursts min⁻¹; P < 0.03). In Study 2, forearm and calf blood flows were measured in an additional 10 subjects using Doppler ultrasound. MS decreased FVR (−27 ± 10%; P < 0.02), but did not change CVR (5 ± 14%) as in Study 1. These findings demonstrate differential vascular control of the arm and leg during MS that is not associated with muscle sympathetic outflow. Additionally, the robust increase in MSNA during recovery may have acute and chronic cardiovascular implications.     

Inspiratory muscle training attenuates the human respiratory muscle metaboreflex

We hypothesized that inspiratory muscle training (IMT) would attenuate the sympathetically mediated heart rate (HR) and mean arterial pressure (MAP) increases normally observed during fatiguing inspiratory muscle work. An experimental group (Exp, n = 8) performed IMT 6 days per week for 5 weeks at 50% of maximal inspiratory pressure (MIP), while a control group (Sham, n = 8) performed IMT at 10% MIP. Pre- and post-training, subjects underwent a eucapnic resistive breathing task (RBT) (breathing frequency = 15 breaths min⁻¹, duty cycle = 0.70) while HR and MAP were continuously monitored. Following IMT, MIP increased significantly ( P < 0.05) in the Exp group (−125 ± 10 to −146 ± 12 cmH₂O; mean ± s.e.m. ) but not in the Sham group (−141 ± 11 to −148 ± 11 cmH₂O). Prior to IMT, the RBT resulted in significant increases in HR (Sham: 59 ± 2 to 83 ± 4 beats min⁻¹; Exp: 62 ± 3 to 83 ± 4 beats min⁻¹) and MAP (Sham: 88 ± 2 to 106 ± 3 mmHg; Exp: 84 ± 1 to 99 ± 3 mmHg) in both groups relative to rest. Following IMT, the Sham group observed similar HR and MAP responses to the RBT while the Exp group failed to increase HR and MAP to the same extent as before (HR: 59 ± 3 to 74 ± 2 beats min⁻¹; MAP: 84 ± 1 to 89 ± 2 mmHg). This attenuated cardiovascular response suggests a blunted sympatho-excitation to resistive inspiratory work. We attribute our findings to a reduced activity of chemosensitive afferents within the inspiratory muscles and may provide a mechanism for some of the whole-body exercise endurance improvements associated with IMT.     

Mechanical load plays little role in contraction-mediated glucose transport in mouse skeletal muscle

The factors responsible for control of glucose transport during exercise are not fully understood. We investigated the role of mechanical load in contraction-mediated glucose transport in an isolated muscle preparation. Mouse extensor digitorum longus muscles were stimulated with repeated contractions for 10 min with or without N -benzyl-p-toluene sulphonamide (BTS, an inhibitor of myosin II ATPase) to block crossbridge activity. BTS inhibited force production during repeated contraction to ∼5% of control. In contrast, BTS had little effect on glucose transport in the basal state (control = 0.55 ± 0.04; BTS = 0.47 ± 0.09 μmol (20 min)⁻¹ ml⁻¹) or after contraction (control = 2.27 ± 0.15; BTS = 2.10 ± 0.16 μmol (20 min)⁻¹ ml⁻¹). BTS did not significantly alter the contraction-mediated changes in high-energy phosphates, glutathione status (a measure of oxidant status) or AMP-activated protein kinase activity. In conclusion, these data show that mechanical load plays little role in contraction-mediated glucose transport. Instead, it is likely that the increased glucose transport during contraction is a consequence of the increase in myoplasmic Ca²⁺ and the subsequent alterations in metabolism, e.g. increased energy turnover and production of reactive oxygen species.     

Central modulation of exercise-induced muscle pain in humans

The purpose of the current study was to determine if exercise-induced muscle pain is modulated by central neural mechanisms (i.e. higher brain systems). Ratings of muscle pain perception (MPP) and perceived exertion (RPE), muscle sympathetic nerve activity (MSNA), arterial pressure, and heart rate were measured during fatiguing isometric handgrip (IHG) at 30% maximum voluntary contraction and postexercise muscle ischaemia (PEMI). The exercise trial was performed twice, before and after administration of naloxone (16 mg intravenous; n = 9) and codeine (60 mg oral; n = 7). All measured variables increased with exercise duration. During the control trial in all subjects ( n = 16), MPP significantly increased during PEMI above ratings reported during IHG (6.6 ± 0.8 to 9.5 ± 1.0; P < 0.01). However, MSNA did not significantly change compared with IHG (7 ± 1 to 7 ± 1 bursts (15 s)⁻¹), whereas mean arterial blood pressure was slightly reduced (104 ± 4 to 100 ± 3 mmHg; P < 0.05) and heart rate returned to baseline values during PEMI (83 ± 3 to 67 ± 2 beats min⁻¹; P < 0.01). These responses were not significantly altered by the administration of naloxone or codeine. There was no significant relation between arterial blood pressure and MSNA with MPP during either IHG or PEMI. A second study ( n = 8) compared MPP during ischaemic IHG to MPP during PEMI. MPP was greater during PEMI as compared with ischaemic IHG. These findings suggest that central command modulates the perception of muscle pain during exercise. Furthermore, endogenous opioids, arterial blood pressure and MSNA do not appear to modulate acute exercise-induced muscle pain.     

Tetrahydrobiopterin augments endothelium-dependent dilatation in sedentary but not in habitually exercising older adults

Endothelium-dependent dilatation (EDD) is impaired with ageing in sedentary, but not in regularly exercising adults. We tested the hypotheses that differences in tetrahydrobiopterin (BH₄) bioactivity are key mechanisms explaining the impairment in EDD with sedentary ageing, and the maintenance of EDD with ageing in regularly exercising adults. Brachial artery flow-mediated dilatation (FMD), normalized for local shear stress, was measured after acute oral placebo or BH₄ in young sedentary (YS) ( n = 10; 22 ± 1 years, mean ± s.e.m. ), older sedentary (OS) ( n = 9; 62 ± 2), and older habitually aerobically trained (OT) ( n = 12; 66 ± 1) healthy men. At baseline, FMD was ∼50% lower in OS versus YS (1.12 ± 0.09 versus 0.57 ± 0.09 (Δmm (dyn cm⁻²)) × 10⁻², P < 0.001; 1 dyn = 10⁻⁵ N), but was preserved in OT (0.93 ± 0.08 (Δmm (dyn cm⁻²)) × 10⁻²). BH₄ administration improved FMD by ∼45% in OS (1.00 ± 0.10 (Δmm (dyn cm⁻²)) × 10⁻², P < 0.01 versus baseline), but did not affect FMD in YS or OT. Endothelium-independent dilatation neither differed between groups at baseline nor changed with BH₄ administration. These results suggest that BH₄ bioactivity may be a key mechanism involved in the impairment of conduit artery EDD with sedentary ageing, and the EDD-preserving effect of habitual exercise.     

Mechanisms of acute natriuresis in normal humans on low sodium diet

This study evaluates the relative importance of several mechanisms possibly involved in the natriuresis elicited by slow sodium loading, i.e. the renin-angiotensin-aldosterone system (RAAS), mean arterial blood pressure (MAP), glomerular filtration rate (GFR), atrial natriuretic peptide (ANP), oxytocin and nitric oxide (NO). Eight seated subjects on standardised sodium intake (30 mmol NaCl day⁻¹) received isotonic saline intravenously (NaLoading: 20 μmol Na⁺ kg⁻¹ min⁻¹ or ≈11 ml min⁻¹ for 240 min). NaLoading did not change MAP or GFR (by clearance of ⁵¹Cr-EDTA). Significant natriuresis occurred within 1 h (from 9 ± 3 to 13 ± 2 μmol min⁻¹). A 6-fold increase was found during the last hour of infusion as plasma renin activity, angiotensin II (ANGII) and aldosterone decreased markedly. Sodium excretion continued to increase after NaLoading. During NaLoading, plasma renin activity and ANGII were linearly related ( R = 0.997) as were ANGII and aldosterone ( R = 0.999). The slopes were 0.40 p m ANGII (mi.u. renin activity)⁻¹ and 22 p m aldosterone (p m ANGII)⁻¹. Plasma ANP and oxytocin remained unchanged, as did the urinary excretion rates of cGMP and NO metabolites (NO_x). In conclusion, sodium excretion may increase 7-fold without changes in MAP, GFR, plasma ANP, plasma oxytocin, and cGMP- and NO_x excretion, but concomitant with marked decreases in circulating RAAS components. The immediate renal response to sodium excess appears to be fading of ANGII-mediated tubular sodium reabsorption. Subsequently the decrease in aldosterone may become important.     

Nitric oxide contributes to the augmented vasodilatation during hypoxic exercise

We tested the hypotheses that (1) nitric oxide (NO) contributes to augmented skeletal muscle vasodilatation during hypoxic exercise and (2) the combined inhibition of NO production and adenosine receptor activation would attenuate the augmented vasodilatation during hypoxic exercise more than NO inhibition alone. In separate protocols subjects performed forearm exercise (10% and 20% of maximum) during normoxia and normocapnic hypoxia (80% arterial O₂ saturation). In protocol 1 ( n = 12), subjects received intra-arterial administration of saline (control) and the NO synthase inhibitor N ^G-monomethyl- l -arginine ( l -NMMA). In protocol 2 ( n = 10), subjects received intra-arterial saline (control) and combined l -NMMA–aminophylline (adenosine receptor antagonist) administration. Forearm vascular conductance (FVC; ml min⁻¹ (100 mmHg)⁻¹) was calculated from forearm blood flow (ml min⁻¹) and blood pressure (mmHg). In protocol 1, the change in FVC (Δ from normoxic baseline) due to hypoxia under resting conditions and during hypoxic exercise was substantially lower with l -NMMA administration compared to saline (control; P < 0.01). In protocol 2, administration of combined l -NMMA–aminophylline reduced the ΔFVC due to hypoxic exercise compared to saline (control; P < 0.01). However, the relative reduction in ΔFVC compared to the respective control (saline) conditions was similar between l -NMMA only (protocol 1) and combined l -NMMA–aminophylline (protocol 2) at 10% (−17.5 ± 3.7 vs. −21.4 ± 5.2%; P = 0.28) and 20% (−13.4 ± 3.5 vs. −18.8 ± 4.5%; P = 0.18) hypoxic exercise. These findings suggest that NO contributes to the augmented vasodilatation observed during hypoxic exercise independent of adenosine.     

Antagonism of orexin receptor-1 in the retrotrapezoid nucleus inhibits the ventilatory response to hypercapnia predominantly in wakefulness

Recent data from transgenic mice suggest that orexin plays an important role in the ventilatory response to CO₂ during wakefulness. We hypothesized that orexin receptor-1 (OX₁R) in the retrotrapezoid nucleus (RTN) contributes to chemoreception. In unanaesthetized rats, we measured ventilation using a whole-body plethysmograph, together with EEG and EMG. We dialysed the vehicle and then SB-334867 (OX₁R antagonist) into the RTN to focally inhibit OX₁R and studied the effects of both treatments on breathing in air and in 7% CO₂. During wakefulness, SB-334867 caused a 30% reduction of the hyperventilation induced by 7% CO₂ (mean ± S.E.M., 135 ± 10 ml (100 g)⁻¹ min⁻¹) compared with vehicle (182 ± 10 ml (100 g)⁻¹ min⁻¹) ( P < 0.01). This effect was due to both decreased tidal volume and breathing frequency. There was a much smaller, though significant, effect in sleep (9% reduction). Neither basal ventilation nor oxygen consumption was affected. The number and duration of apnoeas were similar between control and treatment periods. No effect was observed in a separate group of animals who had the microdialysis probe misplaced (peri-RTN). We conclude that projections of orexin-containing neurons to the RTN contribute, via OX₁Rs in the region, to the hypercapnic chemoreflex control during wakefulness and to a lesser extent, non-rapid eye movement sleep.     

Glucose clearance is higher in arm than leg muscle in type 2 diabetes

Insulin-mediated glucose clearance (GC) is diminished in type 2 diabetes. Skeletal muscle has been estimated to account for essentially all of the impairment. Such estimations were based on leg muscle and extrapolated to whole body muscle mass. However, skeletal muscle is not a uniform tissue and insulin resistance may not be evenly distributed. We measured basal and insulin-mediated (1 pmol min⁻¹ kg⁻¹) GC simultaneously in the arm and leg in type 2 diabetes patients (TYPE 2) and controls (CON) ( n = 6 for both). During the clamp arterio-venous glucose extraction was higher in CON versus TYPE 2 in the arm (6.9 ± 1.0 versus 4.7 ± 0.8%; mean ± s.e.m. ; P = 0.029), but not in the leg (4.2 ± 0.8 versus 3.1 ± 0.6%). Blood flow was not different between CON and TYPE 2 but was higher ( P < 0.05) in arm versus leg (CON: 74 ± 8 versus 56 ± 5; TYPE 2: 87 ± 9 versus 43 ± 6 ml min⁻¹ kg⁻¹ muscle, respectively). At basal, CON had 84% higher arm GC ( P = 0.012) and 87% higher leg GC ( P = 0.016) compared with TYPE 2. During clamp, the difference between CON and TYPE 2 in arm GC was diminished to 54% but maintained at 80% in the leg. In conclusion, this study shows that glucose clearance is higher in arm than leg muscles, regardless of insulin resistance, which may indicate better preserved insulin sensitivity in arm than leg muscle in type 2 diabetes.     

Resistance training and insulin action in humans: effects of de-training

Aerobic endurance training increases insulin action in skeletal muscle, but the effect of resistance training has not been well described. Controversy exists about whether the effect of resistance training is merely due to an increase in muscle mass. We studied the effect of cessation of resistance training in young, healthy subjects by taking muscle biopsies and measuring insulin-mediated whole body and leg glucose uptake rates after 90 days of heavy resistance training (T) and again after 90 days of de-training (dT). Data on leg glucose uptake were expressed relative to accurate measures of leg muscle mass by MRI scanning. Muscle strength (239 ± 43 vs. 208 ± 33 N m), quadriceps area (8463 ± 453 vs. 7763 ± 329 mm²) and glycogen content (458 ± 22 vs. 400 ± 26 mmol (kg dry weight muscle)⁻¹) decreased, while myosin heavy chain isoform IIX increased 4-fold in dT vs. T, respectively (all P < 0.05). GLUT4 mRNA levels and enzyme activities and mRNA levels of glycolytic, lipolytic and glyconeogenic enzymes did not change with de-training. Likewise, capillary density did not change. Whole body glucose uptake decreased 11 % and leg glucose uptake decreased from 75 ± 11 (T) to 50 ± 6 (dT) nmol min⁻¹ (mm muscle)⁻² ( P < 0.05) at maximal insulin, the latter decrease being due to decreased arterio-femoral venous glucose extraction. The decrease was mainly due to reduced non-oxidative glucose disposal. We have thus shown that 90 days after the termination of heavy resistance training, insulin-mediated glucose uptake rates per unit of skeletal muscle have decreased significantly.     

PPARδ agonism inhibits skeletal muscle PDC activity, mitochondrial ATP production and force generation during prolonged contraction

We have recently shown that PPARδ agonism, used clinically to treat insulin resistance, increases fat oxidation and up-regulates mitochondrial PDK4 mRNA and protein expression in resting skeletal muscle. We hypothesized that PDK4 up-regulation, which inhibits pyruvate dehydrogenase complex (PDC)-dependent carbohydrate (CHO) oxidation, would negatively affect muscle function during sustained contraction where the demand on CHO is markedly increased. Three groups of eight male Wistar rats each received either vehicle or a PPARδ agonist (GW610742X) at two doses (5 and 100 mg (kg body mass (bm))⁻¹ orally for 6 days. On the seventh day, the gastrocnemius–soleus–plantaris muscle group was isolated and snap frozen, or underwent 30 min of electrically evoked submaximal intensity isometric contraction using a perfused hindlimb model. During contraction, the rate of muscle PDC activation was significantly lower at 100 mg (kg bm)⁻¹ compared with control ( P < 0.01). Furthermore, the rates of muscle PCr hydrolysis and lactate accumulation were significantly increased at 100 mg (kg bm)⁻¹ compared with control, reflecting lower mitochondrial ATP generation. Muscle tension development during contraction was significantly lower at 100 mg (kg bm)⁻¹ compared with control (25%; P < 0.05). The present data demonstrate that PPARδ agonism inhibits muscle CHO oxidation at the level of PDC during prolonged contraction, and is paralleled by the activation of anaerobic metabolism, which collectively impair contractile function.     

Attenuated vascular responsiveness to noradrenaline release during dynamic exercise in dogs

During dynamic exercise, there is reduced responsiveness to α₁- and α₂-adrenergic receptor agonists in skeletal muscle vasculature. However, it is desirable to examine the sympathetic responsiveness to endogenous release of neurotransmitter, since exogenous sympathomimetic agents are dependent upon their ability to reach the abluminal receptor. Therefore, to further our understanding of sympathetic control of vasomotor tone during exercise, we employed a technique that would elicit the release of endogenous noradrenaline (norepinephrine) during dynamic exercise. Mongrel dogs ( n = 8, 19-24 kg) were instrumented chronically with transit time ultrasound flow probes on both external iliac arteries. A catheter was placed in a side branch of the femoral artery for intra-arterial administration of tyramine, an agent which displaces noradrenaline from the nerve terminal. Doses of 0.5, 1.0 and 3.0 μg ml⁻¹ min⁻¹ of iliac blood flow were infused for 1 min at rest and during graded intensities of exercise. Dose-related decreases in iliac vascular conductance were achieved with these concentrations of tyramine. The reductions in iliac vascular conductance (means ± s.e.m .) were 45 ± 6 %, 30 ± 4 %, 26 ± 3 % and 17 ± 2 %, for the 1.0 μg ml⁻¹ min⁻¹ dose at rest, 3.0 miles h⁻¹, 6.0 miles h⁻¹ and 6.0 miles h⁻¹, 10 % gradient, respectively. At all doses, the magnitude of vasoconstriction caused by administration of tyramine was inversely related to workload. We conclude that there is a reduced vascular responsiveness to sympathoactivation in dynamically exercising skeletal muscle.     

Organization of the central control of muscles of facial expression in man

The capacity of the vascular endothelium locally to release tissue-type plasminogen activator (t-PA) is critical for effective endogenous fibrinolysis. We determined the influence of ageing and regular aerobic exercise on the net release of t-PA across the human forearm in vivo using both cross-sectional and intervention approaches. First, we studied 62 healthy men aged 22-35 or 50-75 years of age who were either sedentary or endurance exercise-trained. Net endothelial release rates of t-PA were calculated as the product of the arteriovenous concentration gradient and forearm plasma flow to intra-arterial bradykinin and sodium nitroprusside. Second, we studied 10 older (60 ± 2 years) healthy sedentary men before and after a 3 month aerobic exercise intervention. Net endothelial t-PA release was significantly blunted with age in the sedentary men. At the highest dose of bradykinin the increase in t-PA antigen release was ≈35 % less (   P < 0.05  ) in the older (from −1.0 ± 0.4 to 37.8 ± 3.8 ng (100 ml tissue)⁻¹ min⁻¹) compared with young (from 0.1 ± 0.6 to 56.6 ± 9.2 ng (100 ml tissue)⁻¹ min⁻¹) men. In contrast, the endurance-trained men did not demonstrate an age-related decline in the net release of t-PA antigen. After the exercise intervention, the capacity of the endothelium to release t-PA increased ≈55 % (   P < 0.05  ) to levels similar to those of the young adults and older endurance-trained men. Regulated endothelial t-PA release declines with age in sedentary men. Regular aerobic exercise may not only prevent, but could also reverse the age-related loss in endothelial fibrinolytic function.     

A respiratory response to the activation of the muscle metaboreflex during concurrent hypercapnia in man

In this study, we aimed to assess the ventilatory and cardiovascular responses to the combined activation of the muscle metaboreflex and the ventilatory chemoreflex, achieved by postexercise circulatory occlusion (PECO) and euoxic hypercapnia (end-tidal partial pressure of CO₂ 7 mmHg above normal), respectively. Eleven healthy subjects (4 women and 7 men; 29 ± 4.4 years old; mean ± s.d. ) undertook the following four trials, in random order: 2 min of isometric handgrip exercise followed by 2 min of PECO with hypercapnia; 2 min of isometric handgrip exercise followed by 2 min of PECO while breathing room air; 4 min of rest with hypercapnia; and 4 min of rest while breathing room air. Ventilation was significantly increased during exercise in both the hypercapnic (+3.17 ± 0.82 l min⁻¹) and the room air breathing trials (+2.90 ± 0.26 l min⁻¹; all P < 0.05). During PECO, ventilation returned to pre-exercise levels when breathing room air (+0.52 ± 0.37 l min⁻¹; P > 0.05), but it remained elevated during hypercapnia (+3.77 ± 0.23 l min⁻¹; P < 0.05). The results indicate that the muscle metaboreflex stimulates ventilation with concurrent chemoreflex activation. These findings have implications for disease states where effort intolerance and breathlessness are linked.     

An association between cutaneous sensitivity to histamine and HLA phenotype

Four hundred and twenty randomly chosen subjects from a normal population were HLA typed and tested for cutaneous sensitivity to histamine by prick testing with 5 concentrations of histamine (10⁻³, 10⁻², 10⁻¹, 1, 10 mg ± ml⁻¹). Positive responses to 10⁻¹ mg ± ml⁻¹ histamine occurred in 41% of the subjects, and particularly those with HLA-B7 (55%) (p < 0.005). It is concluded that genes within the major histocomptability complex influence cutaneous responses to histamine.     

Cerebral non-oxidative carbohydrate consumption in humans driven by adrenaline

During brain activation, the decrease in the ratio between cerebral oxygen and carbohydrate uptake (6 O₂/(glucose +  ¹/₂  lactate); the oxygen–carbohydrate index, OCI) is attenuated by the non-selective β-adrenergic receptor antagonist propranolol, whereas OCI remains unaffected by the β₁-adrenergic receptor antagonist metroprolol. These observations suggest involvement of a β₂-adrenergic mechanism in non-oxidative metabolism for the brain. Therefore, we evaluated the effect of adrenaline (0.08 μg kg⁻¹ min⁻¹ i.v. for 15 min) and noradrenaline (0.5, 0.1 and 0.15 μg kg⁻¹ min⁻¹ i.v. for 20 min) on the arterial to internal jugular venous concentration differences (a-v diff) of O₂, glucose and lactate in healthy humans. Adrenaline ( n = 10) increased the arterial concentrations of O₂, glucose and lactate ( P < 0.05) and also increased the a-v diff for glucose from 0.6 ± 0.1 to 0.8 ± 0.2 m m (mean ± s.d. ; P < 0.05). The a-v diff for lactate shifted from a net cerebral release to an uptake and OCI was lowered from 5.1 ± 1.5 to 3.6 ± 0.4 ( P < 0.05) indicating an 8-fold increase in the rate of non-oxidative carbohydrate uptake during adrenaline infusion ( P < 0.01). Conversely, noradrenaline ( n = 8) did not affect the OCI despite an increase in the a-v diff for glucose ( P < 0.05). These results support that non-oxidative carbohydrate consumption for the brain is driven by a β₂-adrenergic mechanism, giving neurons an abundant provision of energy when plasma adrenaline increases.     

Differential effect of angiotensin II on blood circulation in the renal medulla and cortex of anaesthetised rats

The renal medulla is sensitive to hypoxia, and a depression of medullary circulation, e.g. in response to angiotensin II (Ang II), could endanger the function of this zone. Earlier data on Ang II effects on medullary vasculature were contradictory. The effects of Ang II on total renal blood flow (RBF), and cortical and medullary blood flow (CBF and MBF: by laser-Doppler flux) were studied in anaesthetised rats. Ang II infusion (30 ng kg⁻¹ min⁻¹ i.v. ) decreased RBF 27 ± 2 % (mean ± s.e.m. ), whereas MBF increased 12 ± 2 % (both P < 0.001). Non-selective blockade of Ang II receptors with saralasin (3 μg kg⁻¹ min⁻¹ i.v. ) increased RBF 12 ± 2 % and decreased MBF 8 ± 2 % ( P < 0.001). Blockade of AT₁ receptors with losartan (10 mg kg⁻¹) increased CBF 10 ± 2 % ( P < 0.002) and did not change MBF. Losartan given during Ang II infusion significantly increased RBF (53 ± 7 %) and decreased MBF (27 ± 7 %). Blockade of AT₂ receptors with PD 123319 (50 μg kg⁻¹ min⁻¹ i.v. ) did not change CBF or MBF. Intramedullary infusion of PD 123319 (10 μg min⁻¹) superimposed on intravenous Ang II infusion did not change RBF, but slightly decreased MBF (4 ± 2 %, P < 0.05). We conclude that in anaesthetised surgically prepared rats, exogenous or endogenous Ang II may not depress medullary circulation. In contrast to the usual vasoconstriction in the cortex, vasodilatation was observed, possibly related to secondary activation of vasodilator paracrine agents rather than to a direct action via AT₂ receptors.     

Arm Blood Flow and Oxygenation on the Transition from Arm to Combined Arm and Leg Exercise in Humans

The cardiovascular response to exercise with several groups of skeletal muscle implies that work with the legs may reduce arm blood flow. This study followed arm blood flow ( _arm) and oxygenation on the transition from arm cranking (A) to combined arm and leg exercise (A+L). Seven healthy male subjects performed A at ∼80 % of maximum work rate ( W _max) and A at ∼80 % W _max combined with L at ∼60 % W _max. A transition trial to volitional exhaustion was performed where L was added after 2 min of A. The _arm was determined by constant infusion thermodilution in the axillary vein and changes in biceps muscle oxygenation were measured with near-infrared spectroscopy. During A+L _arm was lowered by 0.38 ± 0.06 l min⁻¹ (10.4 ± 3.3 %,   P < 0.05  ) from 2.96 ± 1.54 l min⁻¹ during A. Total (HbT) and oxygenated haemoglobin (HbO₂) concentrations were also lower. During the transition from A to A+L _arm decreased by 0.22 ± 0.03 l min⁻¹ (7.9 ± 1.8 %,   P < 0.05  ) within 9.6 ± 0.2 s, while HbT and HbO₂ decreased similarly within 30 ± 2 s. At the same time mean arterial pressure and arm vascular conductance also decreased. The data demonstrate reduction in blood flow to active skeletal muscle during maximal whole body exercise to a degree that arm oxygen uptake and muscle tissue oxygenation are compromised.     

Interleukin-6 production in human subcutaneous abdominal adipose tissue: the effect of exercise

The interleukin-6 (IL-6) output from subcutaneous, abdominal adipose tissue was studied in nine healthy subjects before, during and for 3 h after 1 h two-legged bicycle exercise at 60 % maximal oxygen consumption. Seven subjects were studied in control experiments without exercise. The adipose tissue IL-6 output was measured by direct Fick technique. An artery and a subcutaneous vein on the anterior abdominal wall were catheterized. Adipose tissue blood flow was measured using the ¹³³Xe-washout method. In both studies there was a significant IL-6 output in the basal state and no significant change was observed during exercise. Post-exercise the IL-6 output began to increase after 30 min. Three hours post-exercise it was 58.6 ± 22.2 pg (100 g)⁻¹ min⁻¹. In the control experiments the IL-6 output also increased, but it only reached a level of 3.5 ± 0.8 pg (100 g)⁻¹ min⁻¹. The temporal profile of the post-exercise change in the IL-6 output closely resembles the changes in the outputs of glycerol and fatty acids, which we have described previously in the same adipose tissue depot. The difference is that it begins to increase ≈30 min before the glycerol and fatty acid outputs begin to increase. Thus, we suggest that the enhanced IL-6 production post-exercise in abdominal, subcutaneous adipose tissue may act locally via autocrine/paracrine mechanisms influencing lipolysis and fatty acid mobilization rate from this lipid depot.