Seals D R, Hagberg J M, Spina R J, Rogers M A, Schechtman K B, Ehsani A A
Section of Applied Physiology, Washington University School of Medicine, St Louis, Mo. 63110.
Circulation. 1994 Jan;89(1):198-205. doi: 10.1161/01.cir.89.1.198.
The age-associated decline in aerobic exercise capacity is partially reversible by endurance exercise training. Moderate-intensity endurance exercise training increases aerobic exercise capacity mediated, in part, by improvement of stroke volume and left ventricular performance in older men. The present study was designed to characterize the nature of cardiovascular adaptations to strenuous endurance exercise of long duration and to delineate the mechanisms underlying increased stroke volume and cardiac output in highly trained older endurance athletes.
Nine male master athletes (MA: 64 +/- 2 years old, mean +/- SEM) and 9 older sedentary healthy men (controls: 63 +/- 1 year) were studied. Left ventricular systolic function was evaluated with the use of cardiac blood pool imaging and echocardiography. Maximal O2 uptake (VO2max) was 50.4 +/- 1.7 mL.kg-1 x min-1 in the MA and 29.6 +/- 1.4 mL.kg-1 x min-1 (P = .0001) in controls. Systolic and mean blood pressures at rest and during exercise were not different in the two groups. Left ventricular systolic function at peak exercise was higher in the MA than in sedentary controls as evidenced by (1) a higher left ventricular functional reserve (delta EF: 12.4 +/- 2 versus 5.6 +/- 2.5, P = .05), (2) a large decrease in end-systolic volume during exercise (MA: 56 +/- 4 mL at rest and 42 +/- 5 mL at peak exercise, P = .007; controls: 43 +/- 2 mL at rest and 42 +/- 6 mL at peak exercise, P = .35) with no differences in systolic blood pressure, (3) a higher left ventricular fractional shortening at peak exercise (MA: 52 +/- 2.6%; controls: 45 +/- 1%, P = .046) at comparable values for end-systolic wall stress (MA: 56 +/- 12 g/cm2; controls: 53 +/- 7 g/cm2, P = .50), and (4) a greater decrease in end-systolic diameter at peak exercise in the MA than in controls (MA: -1.2 +/- 0.16 cm versus -0.57 +/- 0.13 cm, P = .014) despite no significant differences between the changes in end-systolic wall stress during exercise (MA: -15.5 +/- 7.5 g/cm2, controls: -11.0 +/- 9.0 g/cm2, P = .6). MA had a larger end-diastolic volume at rest (153 +/- 6 versus 132 +/- 4 mL, P = .009) with a normal wall thickness-to-radius ratio (0.34 +/- 0.02). Peak exercise stroke volume was higher (P = .023) in the MA (132 +/- 6 mL/min) than in the sedentary controls (111 +/- 6 mL/min). Changes in stroke volume correlated strongly with changes in ejection fraction in the MA (r = .80, P = .010) but not in sedentary controls (r = .59, P = .097). Further, changes in stroke volume from rest to exercise correlated strongly with changes in end-diastolic volume in both MA (r = .78, P = .013) and sedentary controls (r = .73, P = .026), suggestive of reliance of stroke volume on end-diastolic volume and preload. However, for a given increase in end-diastolic volume, the rise in stroke volume during exercise was significantly larger in the MA than in controls, which, in the absence of differences in mean blood pressures, indicates that enhanced left ventricular systolic function independent of preload plays an additional role in maintaining a higher stroke volume at peak exercise in the highly trained older men.
Cardiac adaptations in older endurance trained men are characterized by volume-overload left ventricular hypertrophy and enhancement of left ventricular systolic performance at peak exercise. These adaptive responses contribute to enhanced stroke volume at peak exercise in older endurance trained men.
有氧运动能力随年龄增长而下降的情况可通过耐力运动训练部分逆转。中等强度的耐力运动训练可提高有氧运动能力,这在一定程度上是通过改善老年男性的每搏输出量和左心室功能来实现的。本研究旨在描述心血管系统对长时间剧烈耐力运动的适应特性,并阐明训练有素的老年耐力运动员每搏输出量和心输出量增加的潜在机制。
研究了9名男性老年运动员(MA:64±2岁,平均值±标准误)和9名久坐不动的健康老年男性(对照组:63±1岁)。使用心血池显像和超声心动图评估左心室收缩功能。MA组的最大摄氧量(VO2max)为50.4±1.7 mL·kg-1·min-1,对照组为29.6±1.4 mL·kg-1·min-1(P = 0.0001)。两组在静息和运动时的收缩压和平均血压无差异。运动峰值时,MA组的左心室收缩功能高于久坐对照组,表现为:(1)左心室功能储备更高(射血分数变化值:12.4±2对5.6±2.5,P = 0.05);(2)运动期间收缩末期容积大幅下降(MA组:静息时56±4 mL,运动峰值时42±5 mL,P = 0.007;对照组:静息时43±2 mL,运动峰值时42±6 mL,P = 0.35),收缩压无差异;(3)运动峰值时左心室缩短分数更高(MA组:52±2.6%;对照组:45±l%,P = 0.046),收缩末期壁应力值相当(MA组:56±12 g/cm2;对照组:53±7 g/cm2,P = 0.50);(4)运动峰值时,MA组收缩末期直径的下降幅度大于对照组(MA组:-1.2±0.16 cm对-0.57±0.13 cm,P = 0.014),尽管运动期间收缩末期壁应力的变化无显著差异(MA组:-15.5±7.5 g/cm2,对照组:-11.0±9.0 g/cm2,P = 0.6)。MA组静息时舒张末期容积更大(153±6对132±4 mL,P = 0.009),壁厚与半径比正常(0.34±0.02)。MA组运动峰值时的每搏输出量更高(P = 0.023)(132±6 mL/min),高于久坐对照组(111±6 mL/min)。MA组每搏输出量的变化与射血分数的变化密切相关(r = 0.80,P = 0.010),而久坐对照组则不然(r = 0.59,P = 0.097)。此外,从静息到运动时每搏输出量的变化与舒张末期容积的变化在MA组(r = 0.78,P = 0.013)和久坐对照组(r = 0.73,P = 0.026)中均密切相关,提示每搏输出量依赖于舒张末期容积和前负荷。然而,对于给定的舒张末期容积增加,运动期间MA组每搏输出量的增加幅度显著大于对照组,在平均血压无差异的情况下,这表明在训练有素的老年男性中,独立于前负荷的左心室收缩功能增强在运动峰值时维持更高的每搏输出量方面发挥了额外作用。
老年耐力训练男性的心脏适应特征为容量超负荷性左心室肥厚以及运动峰值时左心室收缩性能增强。这些适应性反应有助于训练有素的老年耐力男性在运动峰值时增加每搏输出量。
