Central and peripheral cardiovascular adaptations to exercise in endurance-trained children

Stroke volume (SV) response to exercise depends on changes in cardiac filling, intrinsic myocardial contractility and left ventricular afterload. The aim of the present study was to identify whether these variables are influenced by endurance training in pre-pubertal children during a maximal cycle test. SV, cardiac output (Doppler echocardiography), left ventricular dimensions (time-movement echocardiography) as well as arterial pressure and systemic vascular resistances were assessed in 10 child cyclists (VO2max: 58.5 +/- 4.4 mL min-1 kg-1) and 13 untrained children (UTC) (VO2max: 45.9 +/- 6.7 mL min-1 kg-1). All variables were measured at the end of the resting period, during the final minute of each workload and during the last minute of the progressive maximal aerobic test. At rest and during exercise, stroke index was significantly higher in the child cyclists than in UTC. However, the SV patterns were strictly similar for both groups. Moreover, the patterns of diastolic and systolic left ventricular dimensions, and the pattern of systemic vascular resistance of the child cyclists mimicked those of the UTC. SV patterns, as well as their underlying mechanisms, were not altered by endurance training in children. This result implied that the higher maximal SV obtained in child cyclists depended on factors influencing resting SV, such as cardiac hypertrophy, augmented myocardium relaxation properties or expanded blood volume.     

Stroke volume response to cycle ergometry in trained and untrained older men

The aims of this study were threefold: (1) to investigate the stroke volume (SV) response of trained older male cyclists [Cyclists: 65 (2.1) years; n?=?10] during incremental cycle ergometry (20 W?·?min^?1); (2) to determine the SV dynamics and total peripheral resistance response of untrained, but healthy and active older male controls [Controls: 66 (1.1) years; n?=?10]; (3) to compare the maximum oxygen consumption (˙VO_2max) and SV response of trained older male runners [Runners: 65 (3.4) years; n?=?11] with that of age-matched Cyclists. Impedance cardiography was used to assess the response of cardiac output (CO), SV and total peripheral resistance to exercise involving cycle ergometry. The mean ˙VO_2max of the trained Cyclists [54 (1.6) ml?·?kg^?1?·?min^?1] was significantly higher (P??1?·?min^?1], whereas both groups possessed a significantly higher ˙VO_2max than the Controls [28 (1.3) ml?·?kg^?1?·?min^?1]. During exercise, at a heart rate of 90 beats?·?min^?1, the SV of the Cyclists increased by 41%, that of the Runners increased by 47%, and that of the Controls increased by 31%. However, the Cyclists' and Runners' SV response was significantly greater than that of the Controls. The SV for cyclists and controls peaked at 30% of ˙VO_2max. This early increase in SV was a major factor underlying the increase in CO during exercise in both the trained and the untrained subjects. In addition, all three groups showed a significant decrease in total peripheral resistance throughout exercise. The finding that older male runners possessed a large exercise SV and high ˙VO_2max suggests that run training results in enhanced cardiovascular performance during cycle ergometry.     

Blood lactate in trained cyclists during cycle ergometry at critical power

Summary The purposes of this investigation were to determine the validity of critical power (CP) as a measure of the work rate that can be maintained for a very long time without fatigue and to determine whether this corresponded with the maximal lactate steady-state (la_ss,max). Eight highly trained endurance cyclists (maximal oxygen uptake 74.1 ml · kg^–1 · min^–1, SD 5.3) completed four cycle ergometer tests to exhaustion at predetermined work rates (360, 425, 480 and 520 W). From these four co-ordinates of work and time to fatigue the regression of work limit on time limit was calculated for each individual (CP). The cyclists were then asked to exercise at their CP for 30 min. If CP could not be maintained, the resistance was reduced minimally to allow the subject to complete the test and maintain a blood lactate plateau. Capillary blood was sampled at 0, 5, 10, 20 and 30 min into exercise for the analysis of lactate. Six of the eight cyclists were unable to maintain CP for 30 min without fatigue. In these subjects, the mean power attained was 6.4% below that estimated by CP. Mean blood lactates (n = 8) reached a steady-state (8.9 mmol · l^–1, SD 1.6) during the last 20 min of exercise indicating that CP slightly overestimated la_{ss, max}. Individual blood lactates during the last 20 min of exercise were more closely related to the y-intercept of the CP curve (r=0.78, P<0.05) than either CP (0.34, NS) or mean power output (r=0.42, NS). The present investigation has shown that highly trained endurance cyclists can tolerate previously unreported levels of blood lactate during 30 min of exercise at or near their CP. Blood lactates during continuous exercise are higher than at the same work rate during an incremental test. The CP provides a simple and inexpensive means of assessing the exercise intensity which can be maintained continuously, while avoiding the methodological difficulties associated with ventilatory and lactate thresholds.     

Training-induced increases in sea level V˙O2 m a x and endurance are not enhanced by acute hypobaric exposure

The present study used untrained subjects to examine the effect of acute hypobaric exposure during endurance training on subsequent exercise performance at sea level. Two groups, each of nine subjects, completed 5 weeks of endurance training [cycle ergometer exercise for 45 min, three times per week at a heart rate corresponding to 70% of that achieved at the maximal O₂ consumption (V˙O_{2 max} ) either at sea level or at high altitude] in a hypobaric chamber, under either normobaric [sea level, SL; 750 mmHg (100 kPa) ≈90 m] or hypobaric [altitude, ALT; 554 mmHg (73.4 kPa) ≈ 2500 m] conditions and the changes in SL V˙O_{2 max} , SL endurance time and peak blood lactate during the endurance test compared. While each group showed increases in both SL V˙O_{2 max} (≈12%) and SL endurance time (≈71%), there were no significant differences between the groups [SL V˙O_{2 max} , mean (SE) – SL group: pre-training = 42.4 (3.5), post-training = 46.1 (3.5) ml · kg^?1· min^?1, P < 0.005; ALT group: pre-training = 40.8 (2.6), post-training = 47.2 (3.4) ml · kg^?1· min^?1, P < 0.01; SL endurance time – SL group: pre-training 7.1 (1.5), post-training 11.8 (2.9) min, P < 0.01; ALT group: pre-training = 7.5 (0.6), post-training = 13.3 (1.4) min, P < 0.001]. Peak blood lactate during the endurance test was not altered by either training regimen. It is concluded that acute exposure of untrained subjects to hypobaric hypoxia during endurance training has no synergistic effect on the degree of improvement in either SL V˙O_{2 max} or endurance time.     

Attenuated relationship between cardiac output and oxygen uptake during high-intensity exercise

Aim: Recent findings have challenged the belief that the cardiac output (CO) and oxygen consumption (VO₂) relationship is linear from rest to maximal exercise. The purpose of this study was to determine the CO and stroke volume (SV) response to a range of exercise intensities, 40–100% of VO_2max, during cycling. Methods: Ten well‐trained cyclists performed a series of discontinuous exercise bouts to determine the CO and SV vs. VO₂ responses. Results: The rate of increase in CO, relative to VO₂, during exercise from 40 to 70% of VO_2max was 4.4 ± 1.4 L L^?1. During exercise at 70–100% of VO_2max, the rate of increase in CO was reduced to 2.1 ± 0.9 L L^?1 (P = 0.01). Stroke volume during exercise at 80–100% of VO_2max was reduced by 7% when compared to exercise at 50–70% of VO_2max (134 ± 5 vs. 143 ± 5 mL per beat, P = 0.02). Whole body arterial‐venous O₂ difference increased significantly as intensity increased. Conclusion: The observation that the rate of increase in CO is reduced as exercise intensity increases suggests that cardiovascular performance displays signs of compromised function before maximal VO₂ is reached.     

Ventilatory response at the onset of voluntary exercise and passive movement in endurance runners

The present study was performed to examine whether or not the ventilatory response at the onset of voluntary exercise and passive movement in endurance runners is the same as in untrained subjects. Twelve long-distance runners belonging to the varsity athletic club and 13 untrained subjects of our university participated as subjects in this study. Maximum oxygen uptake was significantly higher in the endurance runner group [mean (SD) 70.8 (4.7) ml?·?kg^?1?·?min^?1] than in the untrained group [49.8 (6.3) ml?·?kg^?1?·?min^?1]. Cardiorespiratory responses during voluntary exercise and passive movement of alternate flexion-extension of the right and left legs for about 15 s at a frequency of about 60?rpm, were determined by means of breath-by-breath techniques. Minute inspiratory ventilation (V˙ _I), tidal volume (V _T), respiratory frequency (f _b), cardiac output (Q˙ _c), stroke volume (SV) and heart rate (HR) increased significantly immediately at the onset of voluntary exercise and passive movement. The incremental rate for V˙ _I was greater than that for Q˙ _c. Average values and standard deviations of changes in V˙ _I were calculated as the difference between the mean of the first and second breath and the mean of five breaths preceding the exercise or movement. The rates obtained in voluntary exercise and passive movement in the endurance runner group [2.34 (0.82) and 1.72 (0.71 l?·?min^?1), respectively] were significantly (P<0.05) lower than those in the untrained group [4.16 (2.66) and 2.71 (1.56 l?·?min^?1), respectively]. Also changes in V _T and HR were significantly lower in the endurance group than in the untrained group with regard to both voluntary exercise and passive movement. The results suggest that the magnitude of cardiorespiratory responses at the onset of voluntary exercise and passive movement in humans is influenced by chronic endurance training for long periods.     

Identification of histamine H1- and H2-receptors by means of mepyramine,cimetidine and theophylline in the cardiovascular system of the dog

The haemodynamic effects of histamine infusions (0.5 to 8 g kg^–1 min^–1) were studied in anaesthetized dogs previously instrumented for measurements of left ventricular pressure (LVP),dP/dt _max, aortic and femoral blood pressure (P _AO;P _AF) and femoral blood flow (F _AF). Blockage of H₁- or H₂-receptors alone with either mepyramine (1 mg kg^–1 min^–1) or cimetidine (2 mg kg^–1 min^–1) did not prevent the dose-dependent decrease in contractility and blood pressure responses to histamine. Since, however, both antihistamines administered in combination competitively antagonized responses to histamine, it is concluded that peripheral and cardiac effects of histamine involve interaction with both H₁- and H₂-receptors. The potentiation ofdP/dt _max,P _AO andF _AF responses to histamine as produced by theophylline (4 mg kg^–1 min^–1) was completely reversed by cimetidine, which thus may be taken as an indication that also under in vivo conditions cyclic AMP serves as a mediator only for histamine H₂-responses. However, since these results do not allow clearly to separate between primary cardiac and peripheral responses in a further set of experiments blood pressure was held constant during histamine infusions. When peripheral mechanisms were excluded as responsible for cardiac actions of histamine by this procedure histamine evoked small positive inotropic responses which were prevented by cimetidine. These findings suggest that on ventricular muscle of dogs there exists a small fraction of H₂-receptors mediating positive inotropic effects which, however, were masked on intact animals by negative inotropic responses due to a pronounced fall in blood pressure.     

Relationship between maximal oxygen uptake on different ergometers, lean arm volume and strength in paraplegic subjects

The present experiment was designed to study the importance of strength and muscle mass as factors limiting maximal oxygen uptake (V˙O_{2 max} ) in wheelchair subjects. Thirteen paraplegic subjects [mean age 29.8 (8.7) years] were studied during continuous incremental exercises until exhaustion on an arm-cranking ergometer (AC), a wheelchair ergometer (WE) and motor-driven treadmill (TM). Lean arm volume (LAV) was estimated using an anthropometric method based upon the measurement of various circumferences of the arm and forearm. Maximal strength (MVF) was measured while pushing on the rim of the wheelchair for three positions of the hand on the rim (?30°, 0° and +30°). The results indicate that paraplegic subjects reached a similar V˙O_{2 max} [1.23 (0.34) l?·?min^?1, 1.25 (0.38) l?·?min^?1, 1.22?(0.18) l?·?min^?1 for AC, TM and WE, respectively] and V˙O_{2 max} /body mass [19.7?(5.2)?ml?·?min^?1?·?kg^?1, 19.5 (6.14) ml?·?min^?1?·?kg^?1, 19.18 (4.27) ml?·?min^?1?·?kg^?1 for AC, TM and WE, respectively on the three ergometers. Maximal heart rate f _{c max} during the last minute of AC (173 (17) beats?·?min^?1], TM [168 (14) beats?·?min^?1], and WE [165 (16) beats?·?min^?1], were correlated, but f _{c max} was significantly higher for AC than for TM (P<0.03). There were significant correlations between MVF and LAV (P<0.001) and between the MVF data obtained at different angles of the hand on the rim [311.9 (90.1) N, 313.2 (81.2) N, 257.1 (71) N, at ?30°, 0° and +30°, respectively]. There was no correlation between V˙O_{2 max} and LAV or MVF. The relatively low values of f _{c max} suggest that V˙O_{2 max} was, at least in part, limited by local aerobic factors instead of central cardiovascular factors. On the other hand, the lack of a significant correlation between V˙O_{2 max} and MVF or muscle mass was not in favour of muscle strength being the main factor limiting V˙O_{2 max} in our subjects.     

Occurrence of electromyographic and ventilatory thresholds in professional road cyclists

The temporal relationship between the electromyographic (EMG) and ventilatory thresholds was investigated during incremental exercise performed by eight professional road cyclists. The exercise, performed on a cycloergometer, started at 100 W with successive increments of 26 W·min^–1 until exhaustion. Gas exchange and the root mean square value of EMG (RMS) from eight lower limb muscles were examined throughout the exercise period. Professional cyclists achieved a maximal oxygen consumption, i.e. O_2max, of 5.4 (0.5) l·min^–1 [74.6 (2.5) ml·min^–1·kg^–1, range: 67.8–82.4 ml·min^–1·kg^–1] and a maximum power (W_max) of 475 (30) W (range: 438–516 W). Our results showed at least the occurrence of a first EMG threshold (EMG_Th1) in 50% (gastrocnemius lateralis) of the subjects and a second EMG threshold (EMG_Th2) in 63% (gastrocnemius medialis). EMG_Th1 occurred significantly before the first ventilatory threshold (VT₁), i.e. at 52 (2)% and 62 (9)% of W_max, respectively. Inversely, no significant difference was observed between the occurrence of EMG_Th2 and the second ventilatory threshold (VT₂), i.e. at 86 (1)% and 89 (7)% of W_max, respectively. These results suggest that the use of EMG may be a useful non-invasive method for detecting the second ventilatory threshold in most of the muscles involved in cycling exercise.     

Body dimensions,exercise capacity and physical activity level of adolescent Nandi boys in western Kenya

The aim of this study was to characterize untrained Nandi boys (mean age 16.6 years) from a town (n = 11) and from a rural area (n = 19) in western Kenya (altitude ?2000 m.a.s.l.) in regard to their body dimensions, oxygen uptake and physical activity level. The town boys had a mean maximal oxygen uptake (VO_2max) of 50 (range: 45–60) mL?kg^?1?min^?1, whereas the village boys reached a value of 55 (37?63)?mL?kg^?1?min^?1 (?p<0.01) in VO_2max. The running economy, determined as the oxygen cost at a given running speed, was 221?mL?kg^?1?km^?1 (597?mL?kg^?0.75?km^?1) for town as well as for village boys. The body mass index (BMI) was very low for town as well as for village boys (18.6 vs 18.4?kg?m^?2). The daily mean time spent working in the field during secondary school and doing sports were significantly higher in village boys compared to town boys (working in the field: 44.2 (0–128) vs 1.3 (0–11)?min, p<0.01; sports: 32.0 (11–72) vs 12.8 (0–35)?min, p<0.01, respectively). A positive correlation between the daily time spent doing sports and VO_2max was found when pooling the data from the town and the village boys (R = 0.55, p<0.01). It is concluded that the body dimensions of adolescent Nandi town and village boys corresponds well with findings in Kenyan elite runners. They are very slender with relatively long legs. In addition, the VO_2max of the village boys was higher than that of the town boys, which is probably due to a higher physical activity level of the village boys during secondary school.     

Skeletal muscle buffering capacity and endurance performance after high-intensity interval training by well-trained cyclists

Skeletal muscle buffering capacity (βm), enzyme activities and exercise performance were measured before and after 4 weeks of high-intensity, sub maximal?interval training (HIT) undertaken by six well-trained competitive cyclists [mean maximal oxygen consumption ( O_2max)?=?66.2 ml?·?kg^?1?·?min^?1]. HIT replaced a portion of habitual endurance training and consisted of six sessions, each of six to eight repetitions of 5 min duration at 80% of peak sustained power output (PPO) separated by 1 min of recovery. βm increased from 206.6 (17.9) to 240.4 (34.1) μmol H⁺?·?g muscle dw^?1?·?pH^?1 after HIT (P?=?0.05). PPO, time to fatigue at 150% PPO (TF₁₅₀) and 40-km cycle time trial performance (TT₄₀) all significantly improved after HIT (P?40 performance before HIT (r?=??0.82, P?40 was close to significance (r?=??0.74). βm did not correlate with TF₁₅₀. These results indicate that βm may be an important determinant of relatively short-duration (相似文献   

Changes in performance,maximal oxygen uptake and maximal accumulated oxygen deficit after 5, 10 and 15 days of live high:train low altitude exposure

Nineteen well-trained cyclists (14 males and 5 females, mean initial V˙O_2max 62.3 ml kg^–1 min^–1) completed a multistage cycle ergometer test to determine maximal mean power output in 4 min (MMPO_4min), maximal oxygen uptake (V˙O_2max) and maximal accumulated oxygen deficit (MAOD). The athletes were divided into three groups, each of which completed 5, 10 or 15 days of both a control condition (C) and live high:train low altitude exposure (LHTL). The C groups lived and trained at the ambient altitude of 610 m. The LHTL groups spent 8–10 h night^–1 in normobaric hypoxia at a simulated altitude of 2,650 m, and trained at the ambient altitude of 610 m. The changes to MMPO_4min, V˙O_2max and MAOD in response to LHTL altitude exposure were not significantly different for the 5-, 10- and 15-day treatment periods. For the pooled data from all three treatment periods, there were significant increases in MMPO_4min [mean (SD) 5.15 (0.83) W kg^–1 vs 5.34 (0.78) W kg^–1] and MAOD [50.1 (14.2) ml kg^–1 vs 54.9 (13.1) ml kg^–1] in the LHTL athletes between pre- and post-altitude exposure. There were no significant changes in MMPO_4min [5.09 (0.76) W kg^–1 vs 5.16 (0.86) W kg^–1] or MAOD [50.5 (14.1) ml kg^–1 vs 49.1 (13.0) ml kg^–1] in the C athletes over the corresponding period. There were significant increases in V˙O_2max in the athletes during both the LHTL [63.2 (9.0) ml kg^–1 min^–1 vs 64.1 (9.0) ml kg^–1 min^–1] and C [62.0 (8.6) ml kg^–1 min^–1 vs 63.4 (9.2) ml kg^–1 min^–1] conditions. In these athletes, there was no difference in the impact of 5, 10 or 15 days of LHTL on the increases observed in MMPO_4min, V˙O_2max or MAOD; and LHTL increased MMPO_4min and MAOD more than training at low altitude alone. Electronic Publication     

Neuromuscular characteristics and fatigue in endurance and sprint athletes during a new anaerobic power test

The purpose of this study was to investigate neuromuscular and energy performance characteristics of anaerobic power and capacity and the development of fatigue. Ten endurance and ten sprint athletes performed a new maximal anaerobic running power test (MARP), which consisted ofn x 20-s runs on a treadmill with 100-s recovery between the runs. Blood lactate concentration [la^–]_b was measured after each run to determine submaximal and maximal indices of anaerobic power (P _3mmol·1 ^–1,P_5mmol·1 ^–1,P_10mmol·1 ^–1andP _max) which was expressed as the oxygen demand of the runs according to the American College of Sports Medicine equation: the oxygen uptake (ml·kg^–1·min^–1)=0.2·velocity (m·min^–1) +0.9·slope of treadmill (frac)·velocity (m·min^–1)+3.5. The height of rise of the centre of gravity of the counter movement jumps before (CMJ_rest) and during (CMJ) the MARP test, as well as the time of force production (t _F) and electromyographic (EMG) activity of the leg muscles of CMJ performed after each run were used to describe the neuromuscular performance characteristics. The maximal oxygen uptake ( _max), anaerobic and aerobic thresholds were determined in the _max test, which consisted ofn x 3-min runs on the treadmill. In the MARP-testP _max did not differ significantly between the endurance [116 (SD 6) ml·kg^–1·min^–1] and sprint [120 (SD 4) ml·kg^–1·min^–1] groups, even though CMJ_rest and peak [la^–]_b were significantly higher and _max was significantly lower in the sprint group than in the endurance group and CMJ_rest height correlated withP _max (r=0.50,P<0.05). The endurance athletes had significantly higher mean values ofP _3mmol·1 ^–1andP _5mmol·1 ^–1[89 (SD 7) vs 76 (SD 8) ml·kg^–1·min^–,P<0.001 and 101 (SD 5) vs 90 (SD 8) ml·kg^–1·min^–1,P<0.01. Significant positive correlations were observed between theP _3mmol·l ^–1and _max, anaerobic and aerobic thresholds. In the sprint group CMJ and the averaged integrated iEMG decreased andt _F increased significantly during the MARP test, while no significant changes occurred in the endurance group. The present findings would suggest thatP _max reflected in the main the lactacid power and capacity and to a smaller extent alactacid power and capacity. The duration of the MARP test and the large number of CMJ may have induced considerable energy and neuromuscular fatigue in the sprint athletes preventing them from producing their highest alactacidP _max at the end of the MARP test. Due to lower submaximal [la^–]_b (anaerobic sprinting economy) the endurance athletes were able to reach almost the sameP _max as the sprint athletes.     

Effects of acute expansion of plasma volume on cardiovascular and thermal function during prolonged exercise

To investigate the hypothesis that an increase in plasma volume (PV) is obligatory in reducing the cardiovascular drift that is associated with prolonged exercise following training, a plasma expander (Macrodex) was used to acutely elevate PV. Eight untrained volunteers [maximal oxygen consumption; V˙O_{2 max} 45.2 (2.2)?ml?·?kg^?1?·?min^?1, mean (SE)] cycled for 2?h [at 46 (4)% V˙O_{2 max} ] in ambient conditions either with no PV expansion (CON) or following PV expansions of either 14% (LOW) or 21% (HIGH). During CON, heart rate (HR) increased (P<0.05) from 147 (2.4)?beats?·?min^?1 to 173 (3.6)?beats?·?min^?1 from 15 to 120?min of exercise. Both LOW and HIGH conditions depressed (P<0.05) HR, an effect that was manifested following 15?min of exercise. In contrast, stroke volume (SV) was elevated following PV expansion, with values (ml) of 89.6 (6.8), 97.8 (5.9) and 104 (4.6) noted by 15?min of exercise for CON, LOW and HIGH conditions, respectively. Acute PV expansion, regardless of magnitude, also resulted in elevations in cardiac output (Q˙ _c). These differences between conditions persisted throughout the exercise, as did the elevation in Q˙ _c that was noted with LOW and HIGH conditions. No difference between Q˙ _c, HR or SV was found between LOW and HIGH. In addition, neither LOW nor HIGH conditions altered the change in rectal temperature that was observed during exercise. These results demonstrate that, at least for moderate exercise performed in ambient conditions, PV expansion serves only to alter cardiac function (Q˙ _c, HR, SV) early in exercise, and not to attenuate the drift that occurs as the exercise is prolonged.     

Effect of intense interval workouts on running economy using three recovery durations

The purposes of this study were to determine whether running economy (RE) is adversely affected following intense interval bouts of 10?×?400-m running, and whether there is an interaction effect between RE and recovery duration during the workouts. Twelve highly trained male endurance athletes [maximal oxygen consumption; V˙O_{2 max} =72.5 (4.3) ml·kg^?1·min^?1; mean (SD)] performed three interval running workouts of 10?×?400 m with a minimum of 4 days between runs. Recovery duration between the repetitions was randomly assigned at 60, 120 or 180 s. The velocity for each 400-m run was determined from a treadmill V˙O_{2 max} test. The average running velocity was 357.9 (9.0) m?·?min^?1. Following the workout, the rating of perceived exertion (RPE) increased significantly (P??1. Changes in RE from pre- to post-workout, as well as heart rate (HR) and respiratory exchange ratio (R) were similar for the three recovery conditions. When averaged across conditions, oxygen consumption (V˙O₂) increased significantly (P??1?·?min^?1 at 200?m?·?min^?1, and from 53.1 to 54.5?ml?·?kg^?1?·?min^?1 at 268 m?·?min^?1, respectively). HR increased (from 124 to 138, and from 151 to 157 beats?·?min^?1 respectively) and R decreased (from 0.90 to 0.78, and from 0.93 to 0.89, respectively) at 200 and 268 m?·?min^?1, respectively (P?V˙O₂, HR and R were independent of the recovery duration between the repetitions.     

Influence of body mass on maximal oxygen uptake: effect of sample size

Basal metabolic rate is scaled to body mass to the power of 0.73, and we evaluated whether a similar scaling applies when the O₂ transport capacity of the body is challenged during maximal exercise (i.e. at maximal O₂ uptake, V˙O _2max). The allometric relationship between V˙O _2max and body mass (y=a · x ^b, where y is V˙O _2max and x is body mass) was developed for 967 athletes representing 25 different sports, with up to 157 participants in each sport. With an increasing number of observations, the exponent approached 0.73, while for ventilation the exponent was only 0.55. By using the 0.73 exponent for V˙O _2max, the highest value [mean (SD)] for the males was obtained for the runners and cyclists [234 (16) ml · kg^−0.73 · min⁻¹], and for the females the highest value was found for the runners [189 (14) ml · kg^−0.73 · min⁻¹]. For the females, aerobic power was about 80% of the value achieved by the males. Scaling may help both in understanding variation in aerobic power and in defining the physiological limitations of work capacity. Accepted: 3 November 2000     

The inotropic effect of atrial natriuretic factor in the anesthetized rabbit

This study was designed to investigate whether atrial natriuretic factor (ANF) administered over the physiological, pathological and pharmacological range has a negative inotropic action on the heart. Anesthetized rabbits were infused with increasing doses of ANF (0.05, 0.25 and 0.5g kg^–1min^–1), while measuring hemodynamic variables including the maximum rate of change of left ventricular pressure (dP/dt _max) as an index of inotropic state. Plasma levels of immunoreactive ANF (iANF) were measured to relate the hemodynamic changes to actual plasma levels of the peptide. Administration of ANF was associated with decreases in blood pressure, left ventricular pressure and dP/dt _max so that after 0.5 g kg^–1 min^–1 infusion, these variables had decreased by 21±2 mmHg, 21±5.3 mmHg and 925±175 mmHg/s, respectively (P<0.01). There were no significant changes in right atrial pressure, left ventricular end-diastolic pressure or heart rate. Since dP/dt _max can be influenced by changing hemodynamic variables and baroreflex changes, a second group of rabbits was studied in which afterload and heart rate were held artificially constant. Again, in this group of rabbits, infusions of ANF led to decreasing inotropic state, so that at the highest infusion rate, a 14% decrease in dP/dt _max was observed (P<0.05). By comparison, hydralazine, a drug which causes active vasodilatation but no direct inotropic action, significantly (P<0.01) decreased blood pressure, left ventricular pressure and dP/dt _max when infused at a rate of 10 g kg^–1 min^–1. However, in animals in which afterload was controlled, hydralazine did not affect any of the variables measured. The results indicate that ANF does have a negative inotropic action in the anesthetized rabbit.     

Aerobic and anaerobic energy during a 2-km race simulation in female rowers

The maximal aerobic power (V˙O_2max) and maximal anaerobic capacity (AOD_max) of 16 female rowers were compared to their peak aerobic power (V˙O_2peak) and peak anaerobic capacity (AOD_peak, respectively) during a simulated 2-km race on a rowing ergometer. Each subject completed three tests, which included a 2-min maximal effort bout to determine the AOD_max, a series of four, 4-min submaximal stages with subsequent progression to V˙O_2max and a simulated 2-km race. Aerobic power was determined using an open-circuit system, and the accumulated oxygen deficit method was used to calculate anaerobic capacities from recorded mechanical power on a rowing ergometer. The average V˙O_2peak (3.58?l?·?min^?1), which usually occurred during the last minute of the race simulation, was not significantly different (P?>?0.05) from the V˙O_2max (3.55?l?· min^?1). In addition, the rowers' AOD_max (3.40?l) was not significantly different (P?>?0.05) from their AOD_peak (3.50?l). The average time taken for the rowers to complete the 2-km race simulation was 7.5?min, and the anaerobic system (AOD_peak) accounted for 12% of the rowers' total energy production during the race.     

Cardiovascular response to static handgrip in trained and untrained men

Summary The influence of aerobic capacity on the cardiovascular response to handgrip exercise, in relation to the muscle mass involved in the effort, was tested in 8 trained men (T) and 17 untrained men (U). The subjects performed handgrip exercises with the right-hand (RH), left-hand (LH) and both hands simultaneously (RLH) at an intensity of 25% of maximal voluntary contraction force. Maximal aerobic capacity was 4.3 l·min^–1 in T and 3.21·min^–1 in U (P<0.01). The endurance time for handgrip was longer in T than in U by 29% (P<0.05) for RH, 38% (P<0.001) for LH and 24% (P<0.001) for RLH. Heart rate (f _c) was significantly lower in T than in U before handgrip exercise, and showed smaller increases (P<0.01) at the point of exhaustion: 89 vs 106 beats·min^–1 for RH, 93 vs 100 beats·min^–1 for LH and 92 vs 108 beats·min^–1 for RLH. Stroke volume (SV) at rest was greater in T than in U and decreased significantly (P<0.05) during handgrip exercise in both groups of subjects. At the point of exhaustion SV was still greater in T than in U: 75 vs 57 ml for RH, 76 vs 54 ml for LH and 76 vs 56 ml for RLH. During the last seconds of handgrip exercise, the left ventricular ejection time was longer in T than in U. Increases in cardiac output (Q _c) and systolic blood pressure did not differ substantially between T and U, nor between the handgrip exercise tests. It was concluded that handgrip exercise caused similar increases inQ _c in both T and U but in T the increased level ofQ _c was an effect of greater SV and lowerf _c than in U. Doubling the muscle mass did not alter the cardiovascular response to handgrip exercise in either T or U.