Female physiology is regulated after puberty by the menstrual cycle, whose hormonal fluctuations create a multitude of effects on several systems, including the cardiovascular one. The use of hormone therapy (HT) is quite common in female athletes, and data on cardiovascular effects in this population are lacking. We sought to investigate the effects of HT in highly trained athletes to assess any difference associated with HT on cardiac remodeling, exercise capacity, and clinical correlates. We studied 380 female elite athletes (mean age 25.5 ± 4.8) competing in endurance and mixed sports; 67 athletes (18%) were in chronic HT therapy. All athletes underwent baseline electrocardiography, exercise electrocardiography stress test, transthoracic echocardiogram, and complete blood tests, including lipid profile and inflammation indexes. The echocardiographic study showed a characteristic left ventricular (LV) remodeling, defined by lower LV mass index (86.2 vs 92.5 g/m2, p <0.006), end-diastolic LV diameter (28.3 vs 29.4 mm/m2, p <0.004), and end-diastolic LV volume (61.82 vs 67.09 ml/m2, p <0.010) compared with controls, without changes in systolic function and diastolic relaxation/filling indexes. A lower burden of ventricular arrhythmias on exercise was observed in HT athletes (1.5% vs 8.6% in those without therapy, p = 0.040). Linear regression analysis showed that HT had an independent effect on LV end-diastolic diameter indexed (p = 0.014), LV end-diastolic volume indexed (p = 0.030), and LV mass indexed (p = 0.020). In conclusion, chronic treatment with HT in female athletes is associated with less cardiac remodeling, including a lower LV cavity, volume, and mass, with preserved systolic and diastolic function, and decreased burden of exercise-induced ventricular arrhythmias. HT, therefore, appears to be responsible for a more economic but equally efficient cardiac adaptation to intensive athletic conditioning.
Keywords: athlete's heart; athletes; estrogen; female; hormone therapy; sport cardiology.
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