Sprint exercise in severe acute hypoxia increased middle-cerebral artery velocity by 25% compared to normoxia, maintaining similar brain O2 delivery despite lower arterial oxygen content.
Does sprint exercise in severe acute hypoxia compared to normoxia alter cerebral blood flow and brain O2 delivery in young men?
During sprint exercise, preserving brain O2 delivery is prioritized over restraining cerebral blood flow to avoid potential damage from elevated perfusion pressure.
Cerebral blood flow (CBF) is regulated to secure brain O 2 delivery while simultaneously avoiding hyperperfusion; however, both requisites may conflict during sprint exercise. To determine whether brain O 2 delivery or CBF is prioritized, young men performed sprint exercise in normoxia and hypoxia (P I O 2 = 73 mmHg). During the sprints, cardiac output increased to ∼22 L min −1 , mean arterial pressure to ∼131 mmHg and peak systolic blood pressure ranged between 200 and 304 mmHg. Middle-cerebral artery velocity (MCAv) increased to peak values (∼16%) after 7.5 s and decreased to pre-exercise values towards the end of the sprint. When the sprints in normoxia were preceded by a reduced P ET CO 2 , CBF and frontal lobe oxygenation decreased in parallel ( r = 0.93, P < 0.01). In hypoxia, MCAv was increased by 25%, due to a 26% greater vascular conductance, despite 4–6 mmHg lower PaCO 2 in hypoxia than normoxia. This vasodilation fully accounted for the 22 % lower CaO 2 in hypoxia, leading to a similar brain O 2 delivery during the sprints regardless of P I O 2 . In conclusion, when a conflict exists between preserving brain O 2 delivery or restraining CBF to avoid potential damage by an elevated perfusion pressure, the priority is given to brain O 2 delivery.
Curtelín et al. (Fri,) conducted a other in Healthy. Sprint exercise in severe acute hypoxia vs. Sprint exercise in normoxia was evaluated on Middle-cerebral artery velocity (MCAv) and brain O2 delivery. Sprint exercise in severe acute hypoxia increased middle-cerebral artery velocity by 25% compared to normoxia, maintaining similar brain O2 delivery despite lower arterial oxygen content.