Aortic stiffness and distensibility in top-level athletes.

Although cardiac adaptation to different sports has been extensively described, the potential relationship of training with aortic root (AR) elastic properties and diameters in top-level athletes remains not fully investigated. The aims of this study were to compare AR morphology and stiffness between highly trained athletes and sedentary subjects and to assess the independent determinants of AR stiffness and distensibility in athletes. Four hundred ten elite athletes (220 endurance-trained athletes [ATE] and 190 strength-trained athletes [ATS]; 290 men; mean age, 28.3 ± 13.6 years; age range, 18-40 years) and 240 healthy controls underwent standardized comprehensive transthoracic echocardiography, including Doppler studies. End-diastolic AR diameters were measured at four locations: the aortic annulus, the sinuses of Valsalva, the sinotubular junction, and the maximal diameter of the proximal ascending aorta. The aortic distensibility index was calculated as 2 × (systolic proximal ascending aortic diameter - diastolic proximal ascending aortic diameter)/(diastolic proximal ascending aortic diameter) × (pulse pressure) (cm(-2)·dyn(-1)·10(-6)). AR stiffness index was defined as (systolic blood pressure/diastolic blood pressure)/(systolic proximal ascending aortic diameter - diastolic proximal ascending aortic diameter)/diastolic proximal ascending aortic diameter. Analysis of variance was performed to evaluate differences among groups. Left ventricular (LV) mass index did not significantly differ between the two groups of athletes but was lower in controls. ATS showed higher body surface area, sum of wall thickness (septum plus LV posterior wall), and circumferential end-systolic stress, while LV stroke volume and LV end-diastolic volume were greater in ATE. AR diameters at all levels and AR stiffness were significantly greater in ATS than in ATE and controls, while AR distensibility was significantly higher in ATE. However, AR dilatation was observed only in four male power athletes (1%). By multivariate analyses, in the overall population of athletes, age, LV stroke volume, endurance training, and duration of training were the only independent determinant of higher AR distensibility. On the other hand, age, circumferential end-systolic stress, strength training, and duration of training were independently associated with AR stiffness in ATS. AR diameters and stiffness were significantly greater in strength-trained athletes, while aortic distensibility was higher in endurance athletes compared with age- and sex-matched healthy controls.

D'Andrea A ，Cocchia R ，Riegler L ，Salerno G ，Scarafile R ，Citro R ，Vriz O ，Limongelli G ，Di Salvo G ，Caso P ，Bossone E ，Calabrò R ，Russo MG ... -  《-》

Aortic root dimensions in elite athletes.

Although cardiac adaptation to different sports has been extensively described, the potential effect of top-level training on the aortic root dimension remains not investigated fully. To explore the full range of aortic root diameters in athletes, 615 elite athletes (370 endurance-trained athletes and 245 strength-trained athletes; 410 men; mean age 28.4 +/- 10.2 years, range 18 to 40) underwent transthoracic echocardiography. The end-diastolic aortic diameters were measured at 4 locations: (1) the aortic annulus, (2) the sinuses of Valsalva, (3) the sinotubular junction, and (4) the maximum diameter of the proximal ascending aorta. Ascending aorta dilation at the sinuses of Valsalva was defined as a diameter greater than the upper limit of the 95% confidence interval of the overall distribution. The left ventricular (LV) mass index and ejection fraction did not significantly differ between the 2 groups. However, the strength-trained athletes had an increased body surface area, sum of wall thickness (septum plus LV posterior wall), LV circumferential end-systolic stress, and relative wall thickness. In contrast, the left atrial volume index, LV stroke volume, and LV end-diastolic diameter were greater in the endurance-trained athletes. The aortic root diameter at all levels was significantly greater in the strength-trained athletes (p <0.05 for all comparisons). However, ascending aorta dilation was observed in only 6 male power athletes (1%). Mild aortic regurgitation was observed in 21 athletes (3.4%). On multivariate analyses, in the overall population of athletes, the body surface area (p <0.0001), type (p <0.001) and duration (p <0.01) of training, and LV circumferential end-systolic stress (p <0.01) were the only independent predictors of the aortic root diameter at all levels. In conclusion, the aortic root diameter was significantly greater in elite strength-trained athletes than in age- and gender-matched endurance athletes. However, significant ascending aorta dilation and aortic regurgitation proved to be uncommon.

D'Andrea A ，Cocchia R ，Riegler L ，Scarafile R ，Salerno G ，Gravino R ，Vriz O ，Citro R ，Limongelli G ，Di Salvo G ，Cuomo S ，Caso P ，Russo MG ，Calabrò R ，Bossone E ... -  《-》

Range of right heart measurements in top-level athletes: the training impact.

To explore the full range of right heart dimensions and the impact of long-term intensive training in athletes. Although echocardiography has been widely used to distinguish the athlete's heart from pathologic left ventricular (LV) hypertrophy, only few reports have described right ventricular (RV) and right atrial (RA) adaptations to extensive physical exercise. 650 top-level athletes [395 endurance- (ATE) and 255 strength-trained (ATS); 410 males (63.1%); mean age 28.4 ± 10.1; 18-40 years] and 230 healthy age- and sex-comparable controls underwent a transthoracic echocardiographic exam. Along with left heart parameters, right heart measurements included: RV end-diastolic diameters at the basal and mid-cavity level; RV base-to-apex length; RV proximal and distal outflow tract diameters; RA long and short diameters; and RA area. Tricuspid annular plane systolic excursion and RV tissue Doppler systolic peak velocity were assessed as indexes of RV systolic function. Pulmonary artery systolic pressure (PASP) was estimated from the peak tricuspid regurgitant velocity. ATS showed increased sum of wall thickness and relative wall thickness, whereas left atrial volume, LV end-diastolic volume, LV stroke volume and PASP were significantly higher in ATE. RV and RA measurements were all significantly greater in ATE than in ATS and controls. ATE also showed improved early diastolic RV function, whereas RV systolic indexes were comparable among groups. On multivariate analysis, type and duration of training (p<0.01), PASP (p<0.01) and LV stroke volume (p<0.001) were the only independent predictors of the main RV and RA dimensions in athletes. This study delineates the upper limits of RV and RA dimensions in highly-trained athletes. Right heart measurements were all significantly greater in elite endurance-trained athletes than in age- and sex-matched strength athletes and controls. This should be considered as a "physiologic phenomenon" when evaluating athletes for sports eligibility.

D'Andrea A ，Riegler L ，Golia E ，Cocchia R ，Scarafile R ，Salerno G ，Pezzullo E ，Nunziata L ，Citro R ，Cuomo S ，Caso P ，Di Salvo G ，Cittadini A ，Russo MG ，Calabrò R ，Bossone E ... -  《-》

Biventricular myocardial adaptation to different training protocols in competitive master athletes.

D'Andrea A ，Caso P ，Scarafile R ，Salerno G ，De Corato G ，Mita C ，Di Salvo G ，Allocca F ，Colonna D ，Caprile M ，Ascione L ，Cuomo S ，Calabrò R ... -  《-》

Comprehensive assessment of biventricular function and aortic stiffness in athletes with different forms of training by three-dimensional echocardiography and strain imaging.

Vitarelli A ，Capotosto L ，Placanica G ，Caranci F ，Pergolini M ，Zardo F ，Martino F ，De Chiara S ，Vitarelli M ... -  《-》