Changes in muscle sympathetic nerve activity and calf blood flow during combined leg and forearm exercise

In order to examine efferent sympathetic nerve control of the peripheral circulation during exercise, muscle sympathetic nerve activity (MSNA), calf blood flow (CBF), heart rate (HR), blood pressure (BP) and oxygen uptake were measured during combined foot and forearm exercise. An initial period of rhythmic foot exercise (RFE) (60 min^-1 at 10% of maximal voluntary contraction (MVC) was followed by the addition of rhythmic handgrip exercise (RFE+OCCL) (60 min at 30% of MVC) and by forearm ischaemia after handgrip exercise while continuing RFE (RFE + OCCL). During RFE, CBF in the working leg, HR and oxygen increased respectively by 560%, 121% and 144% when compared with the control rest period, but MSNA (burst rate) was reduced by 13% (P > 0.05) and BP was unchanged. During RFE+RHG, HR, BP and oxygen uptake were greater than during RFE alone. There was no change in CBF, but a significant increase occurred in calf vascular resistance (CVR) and MSNA increased to 121% of the control level. During RFE + OCCL, MSNA, CVR and BP were all higher than during RFE alone, whereas HR and oxygen uptake decreased slightly, although they remained higher than the control values. The increase in CVR in the working leg and the rise in BP during RFE+RHG or RFE+OCCL might be linked to enhancement of MSNA, which may have been reflexly evoked by input from muscle metabolic receptors in the working forearm.     

Changes in muscle sympathetic nerve activity and calf blood flow during combined leg and forearm exercise.

In order to examine efferent sympathetic nerve control of the peripheral circulation during exercise, muscle sympathetic nerve activity (MSNA), calf blood flow (CBF), heart rate (HR), blood pressure (BP) and oxygen uptake were measured during combined foot and forearm exercise. An initial period of rhythmic foot exercise (RFE) (60 min-1 at 10% of maximal voluntary contraction (MVC) was followed by the addition of rhythmic handgrip exercise (RFE + OCCL) (60 min at 30% of MVC) and by forearm ischaemia after handgrip exercise while continuing RFE (RFE + OCCL). During RFE, CBF in the working leg, HR and oxygen increased respectively by 560%, 121% and 144% when compared with the control rest period, but MSNA (burst rate) was reduced by 13% (P > 0.05) and BP was unchanged. During RFE + RHG, HR, BP and oxygen uptake were greater than during RFE alone. There was no change in CBF, but a significant increase occurred in calf vascular resistance (CVR) and MSNA increased to 121% of the control level. During RFE + OCCL, MSNA, CVR and BP were all higher than during RFE alone, whereas HR and oxygen uptake decreased slightly, although they remained higher than the control values. The increase in CVR in the working leg and the rise in BP during RFE + RHG or RFE + OCCL might be linked to enhancement of MSNA, which may have been reflexly evoked by input from muscle metabolic receptors in the working forearm.     

Resistance exercise training enhances sympathetic nerve activity during fatigue-inducing isometric handgrip trials

Muscle sympathetic nerve activity (MSNA) was investigated 1 week before (pre-training), 1 week after, and 4–6 weeks after strength training using fatigue-inducing handgrip exercises and post-exercise forearm occlusion. Eighteen volunteers underwent forearm training, which consisted of 30 maximal effort, 10-s-duration static handgrips, 4 days per week for 4 weeks. A second group of 18 volunteers served as a control. MSNA was recorded from the tibial nerve by microneurography. Maximal handgrip force increased at 1 week post-training. The MSNA response during fatigued handgrip also increased at 1 week post-training, as compared to pre-training (52.6 ± 5.8 vs. 40.6 ± 4.4 bursts min⁻¹ (mean ± SEM), respectively). However, at 4 weeks post-training, MSNA activity returned to the pre-training level (44.0 ± 5.2 bursts min⁻¹; p < 0.0001 by ANOVA), while the control group showed no changes throughout this period. The MSNA response during post-exercise forearm occlusion was constant throughout the experiment in both groups. Our results indicate that an increased MSNA response after strength training is likely to be the result of central neural factors rather than the muscle metaboreflex.     

Differences in muscle sympathetic nerve response to isometric exercise in different muscle groups

The aim of this study was to examine the effects of muscle fibre composition on muscle sympathetic nerve activity (MSNA) in response to isometric exercise. The MSNA, recorded from the tibial nerve by a microneurographic technique during contraction and following arterial occlusion, was compared in three different muscle groups: the forearm (handgrip), anterior tibialis (foot dorsal contraction), and soleus muscles (foot plantar contraction) contracted separately at intensities of 20%, 33% and 50% of the maximal voluntary force. The increases in MSNA relative to control levels during contraction and occlusion were significant at all contracting forces for handgrip and at 33% and 50% of maximal for dorsal contraction, but there were no significant changes, except during exercise at 50%, for plantar contraction. The size of the MSNA response correlated with the contraction force in all muscle groups. Pooling data for all contraction forces, there were different MSNA responses among muscle groups in contraction forces (P = 0.0001, two-way analysis of variance), and occlusion periods (P = 0.0001). The MSNA increases were in the following order of magnitude: handgrip, dorsal, and plantar contractions. The order of the fibre type composition in these three muscles is from equal numbers of types I and II fibres in the forearm to increasing number of type I fibres in the leg muscles. The different MSNA responses to the contraction of different muscle groups observed may have been due in part to muscle metaboreflex intensity influenced by their metabolic capacity which is related to by their metabolic capacity which is related to the fibre type.     

Effect of heat stress on muscle blood flow during dynamic handgrip exercise

Summary During exercise in a hot environment, blood flow in the exercising muscles may be reduced in favour of the cutaneous circulation. The aim of our study was to examine whether an acute heat exposure (65–70°C) in sauna conditions reduces the blood flow in forearm muscles during handgrip exercise in comparison to tests at thermoneutrality (25° C). Nine healthy men performed dynamic handgrip exercise of the right hand by rhythmically squeezing a water-filled rubber tube at 13% (light), and at 34% (moderate) of maximal voluntary contraction. The left arm served as a control. The muscle blood flow was estimated as the difference in plethysmographic blood flow between the exercising and the control forearm. Skin blood flow was estimated by laser Doppler flowmetry in both forearms. Oesophageal temperature averaged 36.92 (SEM 0.08) ° C at thermo-neutrality, and 37.74 (SEM 0.07) ° C (P<0.01) at the end of the heat stress. The corresponding values for heart rate were 58 (SEM 2) and 99 (SEM 5) beats -min^–1 (P<0.01), respectively. At 25° C, handgrip exercise increased blood flow in the exercising forearm above the control forarm by 6.0 (SEM 0.8) ml · 100 ml^–1 · min^–1 during light exercise, and by 17.9 (SEM 2.5) ml · 100 ml^–1 · min^–1 during moderate exercise. In the heat, the increases were significantly higher: 12.5 (SEM 2:2) ml · 100 ml^–1 · min^–1 at the light exercise level (P<0.01), and 32.2 (SEM 5.9) ml · 100 ml^–1·min^–1 (P<0.05) at the moderate exercise level. Skin blood flow was not significantly different in any of the test conditions between the two forearms. These results suggested that hyperthermia of the observed magnitude did not reduce blood flow in active muscles during light or moderate levels of dynamic handgrip exercise.     

Exhausting handgrip exercise reduces the blood flow in the active calf muscle exercising at low intensity

The calf and forearm blood flows (Q _calf and Q _forearm respectively), blood pressure, heart rate and oxygen uptake of six men and women were studied during combined leg and handgrip exercise to determine whether a reduction of exercise-induced hyperaemia would occur in the active leg when exhausting rhythmic handgrip exercise at 50% maximal voluntary contraction (MVC) was superimposed upon rhythmic plantar flexion lasting for 10 min at 10% MVC (P₁₀) prior to this combined exercise. The Q _calf and Q _forearm were measured by venous occlusion plethysmography during 5-s rests interposed during every minute of P₁₀ exercise and immediately after combined exercise. The muscle sympathetic nerve activity (MSNA) changes were also recorded during leg exercise alone and combined exercise. During plantar flexion performed 60 times · min^–1 with a load equal to 10% MVC (P₁₀), Q _calf was maintained at a constant level, which was significantly higher than the resting value (P < 0.001). When rhythmic handgrip contraction at 50% MVC (H₅₀) and P₁₀ were performed simultaneously, the combined exercise was concluded due to forearm exhaustion after a mean of 51.2 (SEM 5.5) s. At exhaustion, Q _calf had decreased significantly from 20.6 (SEM 3.0) ml · 100 ml^–1 · min^–1 (10th min during P₁₀ exercise) to 15.3 (SEM) ml · 100 ml^–1 · min^–1 (P = 0.001), whereas Q _forearm had increased significantly (0.001 < P < 0.01) from 8.6 (SEM 1.9) ml · 100 ml^–1 · min^–1 (10th min of P₁₀ exercise) to 26.2 (SEM 3.2) ml · 100 ml^–1 · min^–1. The mean blood pressure remained at an almost constant level during the 3rd to 10th min of P₁₀ exercise and increased markedly when H₅₀ was added. The calf vascular conductance during combined exercise decreased significantly (0.001 < P < 0.01) compared with that at the 10th min of P₁₀ alone. Although the MSNA (expressed as burst rate) remained unchanged during P₁₀ exercise for 10 min, it increased markedly when exhausting H₅₀ and P₁₀ exercise were performed simultaneously. These findings indicated that superimposition of exhausting handgrip exercise at 50% MVC caused a vasoconstriction in the exercising calf due to increased MSNA, which counteracted the vasodilatation in this active muscle.     

Leg blood flow during static exercise

Summary Leg blood flow was studied with the constant infusion dye technique during static exercise of the thigh muscles (quadriceps) and during hand-grips at 15 and 25–30% of MVC.Blood flow and oxygen uptake in the leg increased in quadriceps exercise and reached their highest values (around 1.2 l/min and 165 ml/min respectively) at 25–30% of MVC, whereas leg vascular resistance decreased. Regional circulatory adaptations and the oxygen uptake — leg blood flow relationship were in close agreement with the responses found in dynamic leg exercise. In view of the marked rise in intramuscular pressure previously observed during quadriceps contractions, a restriction of blood flow and an increased vascular resistance had been expected. Involuntary activation of leg muscles other than the quadriceps may explain the finding.Contractions of the contralateral quadriceps induced a slight increase in leg blood flow, whereas hand-grips had no influence on blood flow or vascular resistance in the leg. The distribution of the cardiac output during static contractions is discussed, and it is concluded that during hand-grips the increase in blood flow is predominantly distributed to the upper part of the body.     

Comparison of muscle sympathetic nerve activity during exercise in dominant and nondominant forearm

Summary To determine whether or not muscle endurance training alters exercise-induced sympathetic nerve response, we recorded muscle sympathetic nerve activity (MSNA) microneurographically during forearm exercise and compared MSNA between dominant (D) and nondominant (ND) forearms of players of racket sports. Three kinds of forearm exercise were conducted on each side; static (SHG) and dynamic (DHG, at a rate of 1 Hz) handgrip exercise at a loading of 25°10 of maximal voluntary contraction until exhaustion, and 10-min submaximal dynamic handgrip (at a rate of 1 Hz) at an intensity of 0.9 W. Heart rate, ventilation and blood pressure were also monitored at rest and during SHG and DHG exercises. During the last minute of SHG exercise, MSNA burst rate had increased on average by 290 (SEM 46) % in D and 330 (SEM 46) % in ND, while during DHG it increased by 288 (SEM 38) % in D and 344 (SEM 36) % in ND, respectively. There were no significant differences in the MSNA responses between D and ND forearms in either exercise modes. Significant increases in heart rate, ventilation and blood pressure during the last minute of fatiguing SHG and DHG were observed, but there were no significant differences between the two forearms. During submaximal DHG, while MSNA increased significantly above control values in both D and ND, the MSNA response was less in D than that in ND forearm. The results would suggest that exercise-induced MSNA responsiveness is influenced little by muscle endurance training but the intensity of response may be due to the magnitude of metaboreceptor stimulation in the exercising muscle.     

Muscle sympathetic nerve activity at rest compared to exercise tolerance

Cardiovascular autonomic function is associated with physical performance and exercise training adaptation. The association between physical performance and sympathetic regulation is not well known. We hypothesized that sympathetic nervous system activity is associated with physical performance among male runners. The study population included 26 healthy male club runners [age 33 ± 5 years, body mass index (BMI) 24 ± 1 kg/m², VO_2max 58 ± 5 ml kg⁻¹ min⁻¹; mean ± SD]. Muscle sympathetic nerve activity (MSNA) was assessed from the peroneal nerve by the microneurography technique during 5 min of supine rest. Physical performance was assessed by time to exhaustion during treadmill running. The mean resting MSNA was 20 ± 6 bursts min⁻¹ (range 6–34). The mean time to exhaustion was 1,005 ± 136 s (range 720–1260). When the study group was divided into tertiles according to their running performance (866 ± 69, 994 ± 30 and 1154 ± 71 s in time to exhaustion, P < 0.0001 between the groups), MSNA was lower (P = 0.032) in the group with the best running performance (16 ± 5 bursts min⁻¹) compared to those with the worst running performance (23 ± 7 bursts min⁻¹). In conclusion, baseline sympathetic activity, measured by a microneurography at rest, may be associated with the maximal running performance of healthy subjects.     

Changes in blood pressure and muscle sympathetic nerve activity during water drinking in humans

To investigate the possible involvement of the sympathetic nervous system in pressor response during water drinking, muscle sympathetic nerve activity (MSNA), blood pressure (BP), and heart rate (HR) were continuously measured in healthy young volunteers throughout the experiments of a 5-min control, 2 min of drinking 500 ml water, and a 28-min recovery. To avoid the effects of water passing through the oropharyngeal and esophageal regions and/or effects of swallowing, an equal amount of water was directly infused to the stomach through a stomach tube for 2 min. Water drinking caused a transient increase in mean arterial pressure (MAP) and HR immediately after drinking (DeltaMAP, 12.6 +/- 2.1 mmHg; DeltaHR, +19.9 +/- 1.7 beats/min at the peak). An abrupt decrease of MSNA was observed directly during water drinking (Deltaburst rate, -6.9 +/- 1.3 bursts/min; Deltatotal activity, -2,606 +/- 491 U/min), and it increased to the baseline level thereafter. Gastric infusion had little or no effect on MAP, HR, and MSNA. The present study demonstrated that a pressor response during water drinking was associated with the attenuation of MSNA and not generated by gastric infusion of water at the same rate as in this drinking manner. In conclusion, the rapid rise in BP might be caused through stimulations from the oropharyngeal region, swallowing-induced factors, and/or a feedforward mechanism by a central descending signal from the higher brain centers.     

Responses in muscle sympathetic nerve activity to sustained hand-grips of different tensions in humans

Summary To clarify whether sympathetic nerve activity increases in relation to the tension of a sustained muscle contraction, muscle sympathetic nerve activity (MSA) was recorded directly from the peroneal nerve fascicle at the popliteal fossa by means of tungsten microelectrodes in five healthy male subjects. A sustained muscle contraction was performed by handgrip for two minutes in a supine position at tensions of 10, 30 and 45% of maximal grip strength (MGS). MSA, electrocardiogram (ECG) using bipolar electrodes from the chest and surface electromyogram (EMG) from the extensor pollicis longus were recorded simultaneously before and during the sustained handgrip. Arterial blood pressure was measured at the resting upper arm by auscultation. During handgrip with tensions of 10, 30 and 45% MGS, average MSA burst rate (bursts · min⁻¹) increased to 122, 152 and 230% of the resting value, respectively. During the same experimental procedures with tensions of 10, 30 and 45% MGS, average heart rate increased to 105, 110 and 111% of the resting value. These results confirm that sympathetic outflow to a resting muscle is increased with elevation of tension in an active muscle. This process would promote perfusion pressure in the active muscle.     

Blood flow in the triceps brachii muscle in humans during sustained submaximal isometric contractions

The main purpose of this study was to determine the extent to which blood flow through the profunda artery within the triceps brachii muscle may be compromised during maintained low-force isometric fatiguing contractions. Doppler ultrasound techniques were used to record mean blood velocity and arterial diameter of the profunda brachii artery during sustained isometric contractions of 20% maximal voluntary contraction. The arterial diameter did not change throughout the contraction. Thus, blood velocity was considered to be an indicator of blood flow. The mean blood velocity increased initially and then remained constant during the contraction period. When compared to rest [0.06 (SD 0.03) m s^–1] mean blood velocity was significantly larger at the start of the contraction [0.13 (SD 0.07) m s^–1] and larger yet during recovery following the contraction [0.30 (SD 0.14) m s^–1]. Although blood flow through the conduit artery did not drop during the contraction, the post-contraction hyperaemia suggested that circulatory compromise might have occurred at the level of the capillary beds. Electronic Publication     

Muscle blood flow during isometric activity and its relation to muscle fatigue

Summary The effect of isometric exercise on blood flow, blood pressure, intramuscular pressure as well as lactate and potassium efflux from exercising muscle was examined. The contractions performed were continuous or intermittent (5 s on, 5 s off) and varied between 5% and 50% maximal voluntary contraction (MVC). A knee-extensor and a hand-grip protocol were used. Evidence is presented that blood flow through the muscle is sufficient during low-level sustained contractions (<10% MVC). Despite this muscle fatigue occurs during prolonged contractions. One mechanism for this fatigue may be the disturbance of the potassium homeostasis. Such changes may also play a role in the development of fatigue during intermittent isometric contractions and even more so in the recovery from such exercise. In addition the role of impaired transport of substances within the muscle, due to longlasting daily oedema formation, is discussed in relation to fatigue in highly repetitive, monotonous jobs.     

Decoding rule from vasoconstrictor skin sympathetic nerve activity to nonglabrous skin blood flow in humans at normothermic rest

Although an importance of vasoconstrictor skin sympathetic nerve activity (SNA) in control of cutaneous circulation is widely recognized, the decoding rule that translate dynamic fluctuations of vasoconstrictor skin SNA into skin blood flow is not fully understood. In 10 male subjects who rested in supine position under normothermic condition, we measured skin blood flow index (by laser-Doppler flowmetry) at the dorsum pedis, and vasoconstrictor skin SNA (by microneurography) that was confirmed to innervate the same region as the flow index. We determined the transfer and coherence functions from the neural activity input to the flow and quantified the contribution and predictability from the input to output by system engineering technique. The results showed that in frequency-domain analysis, the transfer function from vasoconstrictor skin SNA to skin blood flow had low-pass filter characteristics with 3.6 ± 0.1 s of pure time delay. The coherence function was approximately 0.5 between 0.01 and 0.1 Hz and less above 0.1 Hz. In time-domain analysis, the predictability from the SNA to the skin blood flow was approximately 50%. These findings indicate that at normothermic rest, the decoding rule from vasoconstrictor skin SNA to skin blood flow of skin is characterized by low-pass filter with 3–4 s of pure time delay, and that the vasoconstrictor skin SNA contributes to a half of fluctuation of skin blood flow in the condition. The incomplete dependence of skin blood flow on vasoconstrictor skin SNA may confirm nonneural mechanisms to control cutaneous circulation even at normothermic rest.     

Skeletal muscle blood flow in humans and its regulation during exercise

Regional limb blood flow has been measured with dilution techniques (cardio-green or thermodilution) and ultrasound Doppler. When applied to the femoral artery and vein at rest and during dynamical exercise these methods give similar reproducible results. The blood flow in the femoral artery is ～0.3 L min^?1 at rest and increases linearly with dynamical knee-extensor exercise as a function of the power output to 6–10 L min^?1 (Q = 1.94 + 0.07 load). Considering the size of the knee-extensor muscles, perfusion during peak effort may amount to 2–3 L kg^?1 min^?1, i.e. ～100-fold elevation from rest. The onset of hyperaemia is very fast at the start of exercise with T_½ of 2–10 s related to the power output with the muscle pump bringing about the very first increase in blood flow. A steady level is reached within ～10–150 s of exercise. At all exercise intensities the blood flow fluctuates primarily due to the variation in intramuscular pressure, resulting in a phase shift with the pulse pressure as a superimposed minor influence. Among the many vasoactive compounds likely to contribute to the vasodilation after the first contraction adenosine is a primary candidate as it can be demonstrated to (1) cause a change in limb blood flow when infused i.a., that is similar in time and magnitude as observed in exercise, and (2) become elevated in the interstitial space (microdialysis technique) during exercise to levels inducing vasodilation. NO appears less likely since NOS blockade with L -NMMA causing a reduced blood flow at rest and during recovery, it has no effect during exercise. Muscle contraction causes with some delay (60 s) an elevation in muscle sympathetic nerve activity (MSNA), related to the exercise intensity. The compounds produced in the contracting muscle activating the group III–IV sensory nerves (the muscle reflex) are unknown. In small muscle group exercise an elevation in MSNA may not cause vasoconstriction (functional sympatholysis). The mechanism for functional sympatholysis is still unknown. However, when engaging a large fraction of the muscle mass more intensely during exercise, the MSNA has an important functional role in maintaining blood pressure by limiting blood flow also to exercising muscles.     

Frequency-dependent modulation of muscle sympathetic nerve activity by sinusoidal galvanic vestibular stimulation in human subjects

We have previously demonstrated that selective modulation of vestibular inputs, via sinusoidal galvanic vestibular stimulation (GVS) delivered at 0.5–0.8 Hz, can cause partial entrainment of muscle sympathetic nerve activity (MSNA). Given that we had seen interaction between the dynamic vestibular input and the normal cardiac-locked MSNA rhythm, we tested the hypothesis that frequencies of GVS remote from the cardiac frequency would cause a greater modulation of MSNA than those around the cardiac frequency. Bipolar binaural sinusoidal GVS (±2 mA, 200 cycles) was applied to the mastoid processes in 11 seated subjects at frequencies of 0.2, 0.5, 0.8, 1.1, 1.4, 1.7 and 2.0 Hz. In all subjects, the stimulation evoked robust vestibular illusions of “rocking in a boat” or “swinging from side to side.” Cross-correlation analysis revealed a cyclic modulation of MSNA at all frequencies, with the modulation index being similar between 1.1 Hz (78.5 ± 3.7%) and 2.0 Hz (77.0 ± 4.3%). However, vestibular modulation of MSNA was significantly stronger at 0.2 Hz (93.1 ± 1.7%) and significantly weaker at 0.8 Hz (67.2 ± 1.8%). The former suggests that low-frequency changes in vestibular input, such as those associated with postural changes, preferentially modulate MSNA; the latter suggests that vestibular inputs compete with the stronger baroreceptor inputs operating at the cardiac rhythm (~0.8 Hz), with vestibular modulation of MSNA being greater when this competition with the baroreceptors is reduced.     

Different responses of muscle sympathetic nerve activity to sustained and rhythmic handgrip exercises

Muscle sympathetic nerve activity (MSA) was recorded by microneurographic technique from the human tibial nerve before and during voluntary sustained and rhythmic handgrip exercises. The MSA increased significantly during sustained contractions but not during rhythmic contractions, whereas no differences in resting activity before the two modes of handgrip were seen at rest. The results demonstrate that MSA responses to sustained and rhythmic exercises are distinctly different, showing less sympathetic outflow during rhythmic than during sustained contraction.     

Initiation of increase in muscle sympathetic nerve activity delay during maximal voluntary contraction

To investigate the effects of maximal voluntary exercise on sympathetic nerve activity, contraction force and muscle sympathetic nerve activity (MSNA) were recorded during maximal (MVG) and submaximal voluntary isometric handgrip (SVG) for 2 min in eight healthy subjects. MSNA was determined by a microneurographic technique, and handgrip force, heart rate (HR) and arterial blood pressure (ABP) were measured by a non-invasive method during exercise. Grip force decayed rapidly to 58% of maximal grip force (MGF) at 10 s after commencement of exercise and was almost constant (≈ 30% of MGF) 40 s after exercise. MSNA increase was delayed by 20 s during MVG, followed by a gradual increase. HR was elevated immediately after onset of exercise, while mean ABP rise showed a 20 s lag from initiation of MVG exercise. During SVG increases in MSNA, HR and mean ABP were delayed by 50, 40 and 20 s, respectively, relative to commencement of exercise. Thereafter, these parameters increased time-dependently. These results suggested that the MSNA increase during MVG may be predominantly because of the metaboreflex.     

Lumbar sympathetic nerve activity and hindquarter blood flow during REM sleep in rats

The present study aimed to investigate the response of lumbar sympathetic nerve activity (LSNA) to the onset of rapid eye movement (REM) sleep and its contribution to the regulation of muscle blood flow during REM sleep in rats. Electrodes for the measurements of LSNA, electroencephalogram, electromyogram and electrocardiogram and a Doppler flow cuff for the measurements of blood flow in the common iliac and mesenteric arteries, also catheters for the measurements of systemic arterial and central venous pressures were implanted chronically. REM sleep resulted in a step increase in LSNA, by 22 ± 9% (mean ± s.e.m. , P < 0.05), a reduction of iliac vascular conductance, by −16 ± 3% ( P < 0.05) and a gradual increase in systemic arterial pressure, reaching a maximum value of 8.1 ± 2.0 mmHg ( P < 0.05) at 89 s after onset of REM sleep, while mesenteric vascular conductance increased simultaneously by 5 ± 2% ( P < 0.05). There was a significant (Pearson's correlation coefficient = 0.94, P < 0.05) inverse linear relationship between LSNA and the iliac blood flow. Unilateral lumbar sympathectomy blunted the reduction of iliac blood flow induced by the onset of REM sleep. The present observations suggest that the onset of REM sleep appears to be associated with a vasodilation in viscera and a vasoconstriction in skeletal muscle, such that systemic arterial pressure increases during REM sleep in rats.