Jon W. Williamson

New insights into central cardiovascular control during exercise in humans: a central command update

The autonomic adjustments to exercise are mediated by central signals from the higher brain (central command) and by a peripheral reflex arising from working skeletal muscle (exercise pressor reflex), with further modulation provided by the arterial baroreflex. Although it is clear that central command, the exercise pressor reflex and the arterial baroreflex are all requisite for eliciting appropriate cardiovascular adjustments to exercise, this review will be limited primarily to discussion of central command. Central modulation of the cardiovascular system via descending signals from higher brain centres has been well recognized for over a century, yet the specific regions of the human brain involved in this exercise‐related response have remained speculative. Brain mapping studies during exercise as well as non‐exercise conditions have provided information towards establishing the cerebral cortical structures in the human brain specifically involved in cardiovascular control. The purpose of this review is to provide an update of current concepts on central command in humans, with a particular emphasis on the regions of the brain identified to alter autonomic outflow and result in cardiovascular adjustments.

Activation of the insular cortex during dynamic exercise in humans

1 The insular cortex has been implicated as a region of cortical cardiovascular control, yet its role during exercise remains undefined. The purpose of the present investigation was to determine whether the insular cortex was activated during volitional dynamic exercise and to evaluate further its role as a site for regulation of autonomic activity. 2 Eight subjects were studied during voluntary active cycling and passively induced cycling. Additionally, four of the subjects underwent passive movement combined with electrical stimulation of the legs. 3 Increases in regional cerebral blood flow (rCBF) distribution were determined for each individual using single‐photon emission‐computed tomography (SPECT) co‐registered with magnetic resonance (MR) images to define exact anatomical sites of cerebral activation during each condition. 4 The rCBF significantly increased in the left insula during active, but not passive cycling. There were no significant changes in rCBF for the right insula. Also, the magnitude of rCBF increase for leg primary motor areas was significantly greater for both active cycling and passive cycling combined with electrical stimulation compared with passive cycling alone. 5 These findings provide the first evidence of insular activation during dynamic exercise in humans, suggesting that the left insular cortex may serve as a site for cortical regulation of cardiac autonomic (parasympathetic) activity. Additionally, findings during passive cycling with electrical stimulation support the role of leg muscle afferent input towards the full activation of leg motor areas.

Changes in supraspinal activation patterns following robotic locomotor therapy in motor-incomplete spinal cord injury.

Objectives. Body weight-supported treadmill training (BWSTT) is a task-specific rehabilitation strategy that enhances functional locomotion in patients following spinal cord injury (SCI). Supraspinal centers may play an important role in the recovery of over-ground locomotor function in patients with motor-incomplete SCI. The purpose of this study was to evaluate the potential for supraspinal reorganization associated with 12 weeks of robotic BWSTT using functional magnetic resonance imaging (fMRI). Methods. Four men with motor-incomplete SCI participated in this study. Time since onset ranged from 14 weeks to 48 months post-SCI injury. All subjects were trained with BWSTT 3 times weekly for 12 weeks. This training was preceded and followed by fMRI study of supraspinal activity during a movement task. Testing of locomotor disability included the Walking Index for Spinal Cord Injury (WISCI II) and over-ground gait speed. Results. All subjects demonstrated some degree of change in the blood-oxygen-level-dependent (BOLD) signal following BWSTT. fMRI results demonstrated greater activation in sensorimotor cortical regions (S1, S2) and cerebellar regions following BWSTT. Conclusions. Intensive task-specific rehabilitative training, such as robotic BWSTT, can promote supraspinal plasticity in the motor centers known to be involved in locomotion. Furthermore, improvement in over-ground locomotion is accompanied by an increased activation of the cerebellum.

Reflex increase in blood pressure induced by leg compression in man.

1. We tested the hypotheses that the increase in mean arterial pressure with the application of external leg compression in man is (i) blocked with epidural anaesthesia, and (ii) dependent upon the level of external pressure applied, the quantity of leg muscle mass compressed and the vascular volume of the leg. Fourteen healthy subjects were fitted with an anti‐shock trouser garment to provide three levels (30, 60 and 90 mmHg) of leg compression, while cephalad translocation of fluid was prevented by upper‐thigh cuffs inflated to a supra‐systolic pressure. Cardiovascular responses were recorded during leg compression before and after the administration of epidural anaesthesia in eight subjects, while blood pressure responses from six subjects were compared with their single leg pressor response. 2. Both mean arterial and diastolic pressures were elevated with increasing leg compression, with no changes in heart rate, cardiac output, thoracic impedance, and central venous pressure. The leg compression‐induced blood pressure increases were abolished by epidural anaesthesia. Furthermore, when only one leg was compressed at 90 mmHg, the pressor response was less than that elicited from compression of both legs at the same external pressure. Changes in vascular volume of the leg did not influence the pressor response to leg compression. 3. The results indicate that the mean arterial pressure increases in response to external compression of the legs and that a reflex mechanism, mediated by muscle afferent nerves, is involved. The response is dependent upon both the changes in intramuscular pressure and the quantity of muscle mass compressed.

Cardiovascular responses to active and passive cycling movements

Ten healthy subjects were evaluated at rest and at 5 min of unloaded active (AC) and passive (PC) cycling. Passive limb movements were accomplished using a tandem bicycle with a second rider performing the movements. We measured heart rate (HR), mean arterial pressure (MAP), cardiac output (CO), oxygen uptake (VO2), rating of perceived exertion (RPE), and electrical activity (EMG) of lower limbs muscles. Values for stroke volume (SV) and peripheral vascular resistance (PVR) were calculated. EMG, RPE, and VO2 were higher during AC than during PC (P < 0.001). CO increased during both modes of cycling, but during AC it resulted from a HR acceleration (73 +/- 2 at rest to 82 +/- 2 beats.min-1 at 60 rpm; P < 0.001) with no change in SV whereas during PC, SV increased from rest (65 +/- 4 at rest to 71 +/- 3 ml at 60 rpm; P = 0.003) along with no change in HR. PVR remained constant during PC, but decreased by 13% during AC (P < 0.001) and MAP increased only during PC (93 +/- 2 at rest to 107 +/- 2 mm Hg at 60 rpm). These results supports the concept that central command determines the HR response to dynamic exercise. The increase in SV and consequently in MAP during PC was probably due to increased venous return and/or to muscle mechanoreceptor-evoked increased myocardial contractility.

The relevance of central command for the neural cardiovascular control of exercise

This paper briefly reviews the role of central command in the neural control of the circulation during exercise. While defined as a feedfoward component of the cardiovascular control system, central command is also associated with perception of effort or effort sense. The specific factors influencing perception of effort and their effect on autonomic regulation of cardiovascular function during exercise can vary according to condition. Centrally mediated integration of multiple signals occurring during exercise certainly involves feedback mechanisms, but it is unclear whether or how these signals modify central command via their influence on perception of effort. As our understanding of central neural control systems continues to develop, it will be important to examine more closely how multiple sensory signals are prioritized and processed centrally to modulate cardiovascular responses during exercise. The purpose of this article is briefly to review the concepts underlying central command and its assessment via perception of effort, and to identify potential areas for future studies towards determining the role and relevance of central command for neural control of exercise.

Left ventricular volumes and hemodynamic responses to postexercise ischemia in healthy humans.

PURPOSE The purpose of this study was to determine the cardiac mechanisms involved in cardiovascular adjustments during postexercise circulatory occlusion (OCCL). METHOD Heart rate (HR), mean arterial pressure (MAP), left ventricular end-diastolic (EDV) and end-systolic volumes (ESV), stroke volume (SV), cardiac output (CO), and total peripheral vascular resistance (total peripheral resistance (TPR)) were assessed in nine healthy volunteers during rest and static exercise at 30% of maximum voluntary contraction followed by either OCCL for 3 min or non-OCCL in a randomized crossover protocol. RESULTS During handgrip, HR (+20%; P < 0.001), CO (+11%; P = 0.003), MAP (+18%; P = 0.001), and TPR (+6%; P = 0.004) increased, SV (-8%; P = 0.001) and EDV (-5%; P < 0.001) decreased, while ESV did not change (P > 0.05). These responses were similar between conditions (P > 0.05). During OCCL, HR, SV, and CO returned to baseline, whereas MAP (+19%; P < 0.001) and TPR (+9%; P = 0.004) remained elevated. EDV (+12%; P < 0.001) and ESV (+23%; P < 0.001) increased in parallel above resting values. CONCLUSION Activation of muscle metaboreceptors during OCCL increased MAP by elevating TPR. Despite the higher afterload and increased ESV, CO and SV were kept similar to resting values because EDV also increased, implying the involvement of the Frank-Starling mechanism.

Cardiovascular responses to static exercise in patients with Brown-Séquard syndrome

1 The purpose of this study was to determine the contributions of central command and the exercise pressor reflex in regulating the cardiovascular response to static exercise in patients with Brown‐Séquard syndrome. In this rare condition, a hemisection of the spinal cord typically leaves one side of the body with diminished sensation and normal motor function and the other side with diminished motor function and normal sensation. 2 Four, otherwise healthy, patients with Brown‐Séquard syndrome and varying degrees of motor and sensory dysfunction were studied during four isometric knee extension protocols involving both voluntary contraction and electrically stimulated contractions of each leg. Heart rate, blood pressure, force production and ratings of perceived exertion were measured during all conditions. Measurements were also made during post‐contraction thigh cuff occlusion and during a cold pressor test. 3 With the exception of electrical stimulation of the leg with a sensory deficit, protocols yielded increases in heart rate and blood pressure. Cuff occlusion sustained blood pressure above resting levels only when the leg had intact sensation. 4 While voluntary contraction (or attempted contraction) of the leg with a motor deficit produced the lowest force, it produced the highest ratings of perceived exertion coupled with the greatest elevations in heart rate and blood pressure. 5 These data show that the magnitude of the heart rate and blood pressure responses in these patients was greatly affected by an increased central command; however, there were marked cardiovascular responses due to activation of the exercise pressor reflex in the absence of central command.

Blood pressure responses to dynamic exercise with lower-body positive pressure

Cardiovascular responses were obtained during cycling with graded levels of lower-body positive pressure (LBPP) applied to the exercising limbs. Seven men performed four incremental work rate (25 W.min-1) exercise (IWREx) tests to their limit of tolerance while exposed to 0, 15, 30, or 45 Torr LBPP. They also performed four, 6-min constant work rate exercise (CWREx) bouts at two work rates with LBPPs of 0 and 45 Torr. Cardiovascular data were obtained at rest and at 40%, 55%, 75%, and 90% of VO2peak, as well as at minute 5 of CWREx. LBPP did not alter VO2, HR, SV, or cardiac output (Qc) responses at rest or during exercise. However, both 30 and 45 Torr LBPP produced increases in MAP at rest and during exercise (P < 0.05). During CWREx, elevations in blood pressure were mediated via increases in TPR (P < 0.05). Only 45 Torr LBPP elicited a significantly greater blood pressure increase during exercise than rest, suggesting muscle blood flow restriction at this level of LBPP was sufficient to activate a muscle metabo-reflex. These findings suggest that the muscle metabo-reflex is not tonically active during dynamic exercise under normal conditions, but may instead require a critical reduction in muscle blood flow before it is activated.

Heart rate and blood pressure responses at the onset of dynamic exercise: effect of Valsalva manoeuvre

AbstractThe influence of respiration on the mean blood pressure