Metabolic responses to light arm and leg exercise when sitting

Seven male subjects performed progressive exercises with a light work load on an upper limb or bicycle ergometer in the sitting position. At any comparable work load above zero, arm exercise induced higher oxygen uptake, ventilation, heart rate, oxygen pulse, respiratory rate and tidal volume than leg exercise. At similar levels of VO2 above 0.45 1 X min-1, heart rate and ventilation were higher during arm exercise. A close linear relationship between carbon dioxide output and oxygen uptake was observed during both arm and leg exercises, the slope for arm work being steeper. The ventilatory equivalent for VCO2 (VE/VCO2) gradually decreased during both types of exercise. The ventilatory equivalent for VO2(VE/VO2) remained constant (arm) while it rose (leg) to a peak at 9.8 W and then gradually decreased. Ventilation in relation to tidal volume had a linear relationship with leg exercise, but became curvilinear with arm exercise after tidal volume exceeded 1100 ml. The observed differences in response between arm and leg exercises at a given work load appear to be influenced by differences in sympathetic outflow due to the greater level of static contraction of the relatively small muscle groups required by arm exercise.     

Perceived exertion related to heart rate and blood lactate during arm and leg exercise

To compare some psychophysiological responses to arm exercise with those to leg exercise, an experiment was carried out on electronically braked bicycle ergometers, one being adapted for arm exercise. Eight healthy males took part in the experiment with stepwise increases in exercise intensity every 4 min: 40-70-100-150-200 W in cycling and 20-35-50-70-100 W in arm cranking. Towards the end of each 4 min period, ratings of perceived exertion were obtained on the RPE scale and on a new category ratio (CR) scale:heart rate (HR) and blood lactate accumulation (BL) were also measured. The responses obtained were about twice as high or more for arm cranking than for cycling. The biggest difference was found for BL and the smallest for HR and RPE. The incremental functions were similar in both activities, with approximately linear increases in HR and RPE and positively accelerating functions for CR (exponents about 1.9) and BL (exponents 2.5 and 3.3 respectively). When perceived exertion (according to the CR scale) was set as the dependent variable and a simple combination of HR and BL was used as the independent variable, a linear relationship was obtained for both kinds of exercise, as has previously been found in cycling, running, and walking. The results thus give support for the following generalization: For exercise of a steady state type with increasing loads the incremental curve for perceived exertion can be predicted from a simple combination of HR and BL.     

Greater serum GH response to arm than to leg exercise performed at equivalent oxygen uptake

The aim of this study was to provide information concerning the mechanism of exercise-induced stimulation of growth hormone (GH) release in human subjects. For this reason serum GH as well as some hemodynamic variables and blood concentrations of noradrenaline (NA), insulin (IRI), lactate (LA), glucose (BG), and free fatty acids (FFA) were determined in seven healthy male subjects exercising on a bicycle ergometer with arms or legs and running on a treadmill at equivalent oxygen consumption levels. Significantly greater increases in serum GH concentration accompanied arm exercises than those observed during the leg exercises. This was accompanied by greater increases in heart rate, blood pressure, and plasma NA and blood lactate concentrations. Serum IRI decreased during both leg exercises and did not change during the arm exercise. There were no differences in BG and plasma FFA concentrations between the three types of exercise. The role of humoral and neural signals responsible for the greater GH response to arm exercise is discussed. The findings are consistent with the hypothesis that neural afferent signals sent by muscle "metabolic receptors" participate in the activation of GH release during physical exercise. It seems likely that the stimulation of these chemoreceptors is more pronounced when smaller muscle groups are engaged at a given work load. However, a contribution of efferent impulses derived from the brain motor centres to the control system of GH secretion during exercise is also possible.     

Plasma volume shifts during progressive arm and leg exercise

Upper and lower body exercise was performed to assess the influence muscle mass has on plasma volume (PV) shifts. Nine male subjects (mean = 28 yr) completed a progressive intensity, discontinuous test with an arm crank (AC) and cycle (CY) ergometer. Power output (PO) levels for the AC were 25, 74, 98, and 133 W. PO levels for the CY were 49, 98, 147, and 263 W. At a given submaximal oxygen uptake (VO2), PV efflux was significantly greater for AC compared with CY exercise. When PV efflux was related to the relative intensity of the exercise (ergometer specific % peak VO2), responses were nearly identical. Maximal PV efflux was 18% for both AC and CY exercise. Mean arterial pressure (MAP) was significantly greater for AC compared with CY exercise for a given VO2. MAP plotted against the relative intensity of exercise, however, was similar for both AC and CY exercise. These results suggest that the amount of plasma efflux during exercise is related to the MAP, which is directly related to the relative intensity of the exercise.     

Catecholamines, heart rate, and oxygen uptake during exercise in persons with spinal cord injury

The purpose ofthis study was to investigate the influence of different injury levelsin persons with spinal cord injury (SCI) on epinephrine (Epi) andnorepinephrine (NE) at rest and during graded wheelchair exercise andthe related changes in heart rate andO₂ uptake(O₂). Twenty tetraplegics(Tetra), 10 high-lesion paraplegics (HLPara), 20 paraplegics with SCIbelow T₅ (MLPara), and 18 able-bodied, nonhandicapped persons (AB) were examined. Because of thehigher level of interruption of the sympathetic pathways, Tetra personsshowed lower Epi and NE at rest and only slight increases duringexercise compared with all other groups; the Tetra subjects' impairedcardiac sympathetic innervation caused restricted cardioaccelerationand strongly reduced maximalO₂. Whencompared with AB persons, HLPara had comparable NE but lower Epi levelsas a result of partial innervation of the noradrenergic system anddenervation of the adrenal medulla. MLPara subjects showed an augmentedbasal and exercise-induced upper spinal thoracic sympathetic activitycompared with AB subjects. The increase in heart rate in relation toO₂ was higher in HLParabecause of a smaller stroke volume as a result of venous blood pooling.The different exercise response in persons with SCI is a result of theinterruption of pathways in the spinal cord to the peripheral sympathetic nervous system in addition to the motor paralysis.

     

Oxygen uptake and heart rate in young Green turtles (Chelonia mydas)

Oxygen uptake. heart rate and breathing frequencies were monitored in yearling Green turtles. Routine fed animals used about 100μ O₂ g live turtle^-1 h^-1 at 25C; this value was not significantly affected by size or short term food deprivation. Starved turtle showed a doubling of oxygen uptake after a satiation meal and heightened uptake persisted for five days. Between 15 and 30C oxygen consumption increased with rising temperature; below 15C there was falling temperature. Vigorous activity increased oxygen uptake to two or three times thr routine fed levels.
Turtles swimming gently at 25C exhibited a heart rate of around 46–48 beats min^-1; this rose to 64–68 beats min^-1 during vigorous and continuous activity. Contrary to expectations profound bradycardia was not seen during diving; even during 10 min dives a rate of 25–28 beats min^-1 was sustained. Significantly lower heart rates were only seen in turtles which were apparently asleep.     

Oxygen uptake as related to work rate increment during cycle ergometer exercise

We postulated that the commonly observed constant linear relationship between VO2 and work rate during cycle ergometry to exhaustion is fortuitous and not due to an unchanging cost of external work. Therefore we measured VO2 continuously in 10 healthy men during such exercise while varying the rate of work incrementation and analyzed by linear regression techniques the relationship between VO2 and work rate (delta VO2/delta wr). After excluding the first and last portions of each test we found the mean +/- SD of the delta VO2/delta wr in ml.min-1.W-1 to be 11.2 +/- 0.15, 10.2 +/- 0.16, and 8.8 +/- 0.15 for the 15, 30, and 60 W.min-1 tests, respectively, expressed as ml.J-1 the values were 0.187 +/- 0.0025, 0.170 +/- 0.0027 and 0.147 +/- 0.0025. The slopes of the lower halves of the 15 and 30 W.min-1 tests were 9.9 +/- 0.2 ml.min-1.W-1 similar to the values for aerobic work reported by others. However the upper halves of the 15, 30, and 60 W.min-1 tests demonstrated significant differences: 12.4 +/- 0.36 vs 10.5 +/- 0.31 vs 8.7 +/- 0.23 ml.min-1.W-1 respectively. We postulate that these systematic differences are due to two opposing influences: 1) the fraction of energy from anaerobic sources is larger in the brief 60 W.min-1 tests and 2) the increased energy requirement per W of heavy work is evident especially in the long 15 W.min-1 tests.     

Cardiovascular responses to arm cranking and FNS-induced leg exercise in paraplegics

Twelve spinal cord-injured males performed arm-crank exercise (ACE) with and without concurrent functional neuromuscular stimulation (FNS) of paralyzed leg muscles to investigate the hypothesis that FNS would augment cardiovascular performance during submaximal ACE. Six men who exhibited vigorous isometric contractions of thigh and calf muscles were classed as "responders" to FNS (R), and the remaining subjects with poor or nonexistent contractions served as "nonresponder controls" (C). Steady-state heart rate and oxygen uptake during ACE at 30, 60, and 90 W were not appreciably different from the ACE + FNS condition. However, cardiac outputs in R were augmented by 30% during FNS at rest (from 4.9 to 6.4 l/min), by 18% during 30-W ACE + FNS (from 8.6 to 10.1 l/min), and by 28% during 90-W ACE + FNS (from 12.1 to 15.6 l/min). Similarly, resting stroke volumes were increased by 18% (9 ml) and by 23% (19 ml) at 60 W during FNS in the R group. Calculated total peripheral resistance was reduced at rest and during 90-W ACE + FNS by approximately 24%. In contrast, no alterations of circulatory hemodynamics were observed for C subjects. These data indicate that FNS-induced contractions of paralyzed leg muscles augment venous return to aid central cardiovascular control during upper-body submaximal exercise in paraplegics.     

Kinetics of oxygen uptake and heart rate at onset of exercise in children

Requirements for cellular homeostasis appear to be unchanged between childhood and maturity. We hypothesized, therefore, that the kinetics of O2 uptake (VO2) in the transition from rest to exercise would be the same in young children as in teenagers. To test this, VO2 and heart rate kinetics from rest to constant work rate (75% of the subject's anaerobic threshold) in 10 children (5 boys and 5 girls) aged 7-10 yr were compared with values found in 10 teenagers (5 boys and 5 girls) aged 15-18 yr. Gas exchange was measured breath to breath, and phases I and II of the transition and phase III (steady-state exercise) were evaluated from multiple transitions in each child. Phase I (the VO2 at 20 s of exercise expressed as percent rest-to-steady-state exercise VO2) was not significantly correlated with age or weight [mean value 42.5 +/- 8.9% (SD)] nor was the phase II time constant for VO2 [mean 27.3 +/- 4.7 (SD) s]. The older girls had significantly slower kinetics than the other children but were also found to be less fit. When the teenagers exercised at work rates well below 75% of their anaerobic threshold, phase I VO2 represented a higher proportion of the overall response, but the phase II kinetics were unchanged. The temporal coupling between the cellular production of mechanical work at the onset of exercise and the uptake of environmental O2 appears to be controlled throughout growth in children.     

Substrate utilization by the inactive leg during one-leg or arm exercise.

Substrate utilization by the nonexercising leg was studied in healthy subjects during one-leg exercise at an average work load of 105 W for 40 min (n equals 8) or during arm exercise at 65 W for 20 min (n equals 5). During one-leg exercise both the blood flow and the A-FV difference of oxygen for the non exercising leg rose, resulting in an approximately five fold increment in oxygen uptake. EMG activity of the leg was increased above basal. Despite unchanged or falling arterial levels of insulin, the A-FV difference for glucose across the nonexercising leg rose during exercise and the estimated glucose uptake increased approximately fourfold. Release of lactate in the basal state reverted to a significant net uptake of lactate by the nonexercising leg. During arm exercise there was a 20-70% rise in leg blood flow and the leg oxygen uptake rose 25-45% in spite of minimal EMG activity from the thigh muscles. There was a large uptake of lactate by the legs during arm exercise. We conclude that several important metabolic alterations take place in the nonexercising leg tissues during physical exertion: 1) blood flow and oxygen uptake rise, partly as a consequence of motor activation; 2) substrate utilization shifts from a predominant FFA uptake in the basal state to a greater utilization of carbohydrate; 3) nonexercising muscle, and possibly adipose tissue, play an important role in the removal of lactate during exercise.     

Comparison of skin sympathetic nerve responses to isometric arm and leg exercise.

Measurement of skin sympathetic nerve activity (SSNA) during isometric exercise has been previously limited to handgrip. We hypothesized that isometric leg exercise due to the greater muscle mass of the leg would elicit greater SSNA responses than arm exercise because of presumably greater central command and muscle mechanoreceptor activation. To compare the effect of isometric arm and leg exercise on SSNA and cutaneous end-organ responses, 10 subjects performed 2 min of isometric knee extension (IKE) and handgrip (IHG) at 30% of maximal voluntary contraction followed by 2 min of postexercise muscle ischemia (PEMI) in a normothermic environment. SSNA was recorded from the peroneal nerve. Cutaneous vascular conductance (laser-Doppler flux/mean arterial pressure) and electrodermal activity were measured within the field of cutaneous afferent discharge. Heart rate and mean arterial pressure significantly increased by 16 +/- 3 and 23 +/- 3 beats/min and by 22 +/- 2 and 27 +/- 3 mmHg from baseline during IHG and IKE, respectively. Heart rate and mean arterial pressure responses were significantly greater during IKE compared with IHG. SSNA increased significantly and comparably during IHG and IKE (52 +/- 20 and 50 +/- 13%, respectively). During PEMI, SSNA and heart rate returned to baseline, whereas mean arterial pressure remained significantly elevated (Delta12 +/- 2 and Delta13 +/- 2 mmHg from baseline for IHG and IKE, respectively). Neither cutaneous vascular conductance nor electrodermal activity was significantly altered by either exercise or PEMI. These results indicate that, despite cardiovascular differences in response to IHG and IKE, SSNA responses are similar at the same exercise intensity. Therefore, the findings suggest that relative effort and not muscle mass is the main determinant of exercise-induced SSNA responses in humans.     

Early dynamics of O2 uptake and heart rate as affected by exercise work rate

The kinetics of O2 uptake (Vo2) and heart rate (HR) in response to constant work rate exercise have been characterized as two phases, an immediate response as the result largely of abrupt hemodynamic changes and a slower response as the result of increases in both blood flow and arteriovenous O2 difference (avDo2). There are few data reported concerning Vo2 and HR during phase I or the relationship between their kinetics and work rate or intensity. Because phase I responses depend on abrupt cardiovascular adjustments, it was hypothesized that phase I increases in Vo2 and HR would be greater the more "fit" the subject and would be relatively independent of work rate. To test this, 10 normal subjects exercised from rest to each of five work rates ranging from unloaded cycling to 150 W. The phase I increases of Vo2, HR, and Vo2/HR had small but significant correlations with work rate but not with fitness. At very low work rates (unloaded cycling and 25 W), Vo2 and HR often exceeded their steady-state levels in phase I. There was therefore no phase II increase for Vo2 or HR at these work rates, the entire O2 requirement having been met by phase I circulatory adjustments. For all other work rates, mean response times for Vo2 and HR were related to fitness and were slower than those for Vo2/HR, suggesting that avDo2 reached a steady state before cardiac output did.     

Effects of caffeine on blood pressure, heart rate, and forearm blood flow during dynamic leg exercise

This study examined the acute effects of caffeine on thecardiovascular system during dynamic leg exercise. Ten trained,caffeine-naive cyclists (7 women and 3 men) were studied at rest andduring bicycle ergometry before and after the ingestion of 6 mg/kgcaffeine or 6 mg/kg fructose (placebo) with 250 ml of water. Afterconsumption of caffeine or placebo, subjects either rested for 100 min(rest protocol) or rested for 45 min followed by 55 min of cycleergometry at 65% of maximal oxygen consumption (exercise protocol).Measurement of mean arterial pressure (MAP), forearm blood flow (FBF),heart rate, skin temperature, and rectal temperature and calculation offorearm vascular conductance (FVC) were made at baseline and at 20-minintervals. Plasma ANG II was measured at baseline and at 60 minpostingestion in the two exercise protocols. Before exercise, caffeineincreased both systolic blood pressure (17%) and MAP (11%) withoutaffecting FBF or FVC. During dynamic exercise, caffeine attenuated theincrease in FBF (53%) and FVC (50%) and accentuated exercise-inducedincreases in ANG II (44%). Systolic blood pressure and MAP were alsohigher during exercise plus caffeine; however, these increases weresecondary to the effects of caffeine on resting bloodpressure. No significant differences were observed inheart rate, skin temperature, or rectal temperature. These findingsindicate that caffeine can alter the cardiovascular response to dynamicexercise in a manner that may modify regional blood flow andconductance.