New Findings What is the central question of this study? Following exercise, hypotension is often reported and syncope is more likely. It is unresolved whether the postexercise hypotension associated with different exercise intensities contributes to the rate at which syncope develops. What is the main finding and its importance? The physiological events that induce presyncope are the same both before and after exercise; however, more intense exercise accelerated the development of hypocapnia, hypotension and, ultimately, syncope. These data indicate that higher intensity exercise induces a postexercise hypotension that reduces cardiovascular reserve, an earlier development of hypocapnia and, ultimately, cerebral hypoperfusion. After exercise, a reduction in mean arterial pressure is often experienced and is referred to as postexercise hypotension. Whilst syncope is more likely following exercise, it is unknown whether orthostatic tolerance is impacted by any exercise intensity-mediated effect on postexercise hypotension. We examined the effect of exercise intensity on time to presyncope, induced via combined head-up tilt and lower body negative pressure following 1h of cycling at 30 and 70% of heart rate range. Healthy participants (n = 8; mean +/- SD, 28 +/- 5 years old) completed orthostatic testing to presyncope before and after exercise. Beat-to-beat middle cerebral artery blood flow velocity (MCAv), mean arterial pressure and cerebral oxygenation (measured by near-infrared spectroscopy) were recorded continuously throughout orthostatic testing. During exercise, heart rates were 95 +/- 6 and 147 +/- 5beatsmin(-1) for 30 and 70% heart rate range, respectively, with average power outputs of 103 +/- 22 and 221 +/- 45W, respectively. Time to presyncope occurred 32% sooner after the 70% heart rate range trial (952 +/- 484 versus 1418 +/- 435s; P = 0.004). Both before and after exercise, presyncope occurred at the same reduction in MCAv (grouped mean, -30 +/- 11cms(-1)), mean arterial pressure (-18 +/- 13mmHg), total oxygenation index (-6 +/- 2%) and partial pressure of end-tidal CO2 (-16 +/- 8mmHg; all P >0.1). At presyncope following exercise, the MCAv response was related more to the change in partial pressure of end-tidal CO2 from the baseline preceding orthostatic testing (r(2)=0.50, P=0.01) than to the hypotension (r(2)=0.12, P=0.17). Presyncope both before and after exercise occurred as a result of the same physiological perturbations, albeit greatly accelerated following more intense exercise.

• 出版日期2015-8-1