Poh Kian-Keong, Ton-Nu Thanh-Thao, Neilan Tomas G, Tournoux Francois B, Picard Michael H, Wood Malissa J
Cardiac Ultrasound Laboratory, Division of Cardiology, Department of Medicine, Massachusetts General Hospital, Harvard Medical School, Boston, MA 02115-2696, USA.
Int J Cardiol. 2008 Jun 6;126(3):346-51. doi: 10.1016/j.ijcard.2007.04.051. Epub 2007 Jun 28.
Physiological cardiac adaptations to exercise training resulting in the 'athlete's heart' are well known. Most of these studies, however, were included either those who exercise to exhaustion, non-elite athletes or those who participate primarily in sports requiring extensive weight training. Studies utilizing conventional and tissue Doppler echocardiographic studies in highly competitive elite athletes whose training includes both aerobic and weight training are limited.
Compared to non-athletes, the atrial and left ventricular (LV) volumes at rest were larger in elite athletes. There was enhanced LV diastolic function as manifested by higher early annular (septal and lateral) tissue Doppler velocities (E'): 12.7+/-2.3 vs 11.3+/-1.1 cm/s and 17.4+/-4.7 vs 14.4+/-1.2 cm/s, P=0.025 and 0.020 respectively. Evidence of right ventricular (RV) remodeling included larger basal RV dimensions (38+/-5 vs 32+/-4 mm, P=0.001), attenuated RV systolic function at rest (RV area change 35+/-13% in athletes vs 47+/-11% in controls, P=0.006) and lower RV systolic strain rate (SSR) 1.9+/-0.5 vs 2.9+/-1.1/s, P<0.001). However, there was better right ventricular (RV) diastolic function at rest, E': 13.5+/-3.6 vs 11.1+/-1.5 cm/s (P=0.016). Following exercise, the athletes exhibited augmentation of RV systolic function with increased RV fractional area change (increasing to 43+/-10%, P=0.007) and SSR (2.5+/-1.2/s post-exercise, P=0.038).
Participation by world-class speedskaters in a vigorous training regimen results in cardiovascular anatomic and physiologic adaptations. These changes, including cardiac chamber dilatation, enhanced ventricular diastolic function and attenuated resting RV systolic function, are likely adaptive and allow for more efficient energy use at rest and a robust response to demands of exercise.
生理上心脏对运动训练的适应性变化会导致“运动员心脏”,这是众所周知的。然而,大多数此类研究纳入的对象要么是运动至力竭者、非精英运动员,要么是主要参与需要大量重量训练的运动项目的人。在高度竞争的精英运动员中,利用传统和组织多普勒超声心动图研究其同时包含有氧训练和重量训练的情况有限。
1)确定参与耐力有氧训练和重量训练项目的精英运动员存在的基线心血管结构和生理适应性变化,并将他们与年龄相仿的久坐不动的对照组进行比较。研究对象包括24名参加2006年奥运会的速滑运动员和15名久坐不动的年轻受试者。2)评估短时间剧烈运动后可能出现的心脏结构和生理变化。在运动员以比赛速度进行3000米冲刺后,重复进行基线超声心动图检查。
与非运动员相比,精英运动员静息时的心房和左心室(LV)容积更大。左心室舒张功能增强,表现为更高的早期环状(室间隔和侧壁)组织多普勒速度(E'):分别为12.7±2.3 vs 11.3±1.1厘米/秒和17.4±4.7 vs 14.4±1.2厘米/秒,P分别为0.025和0.020。右心室(RV)重塑的证据包括更大的右心室基底尺寸(38±5 vs 32±4毫米,P = 0.001)、静息时右心室收缩功能减弱(运动员右心室面积变化为35±13%,对照组为47±11%,P = 0.006)以及更低的右心室收缩应变率(SSR)1.9±0.5 vs 2.9±1.1/秒,P < 0.001)。然而,静息时右心室舒张功能更好,E'为13.5±3.6 vs 11.1±1.5厘米/秒(P = 0.016)。运动后,运动员右心室收缩功能增强右心室面积变化分数增加(增至43±10%,P = 0.007)和SSR增加(运动后为2.5±1.2/秒,P = 0.038)。
世界级速滑运动员参与高强度训练方案会导致心血管解剖和生理适应性变化。这些变化,包括心腔扩张、心室舒张功能增强和静息时右心室收缩功能减弱,可能具有适应性,能在静息时更高效地利用能量,并对运动需求做出有力反应。
