Evidence for temperature-mediated regional increases in cerebral blood flow during exercise

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Evidence for temperature-mediated regional increases in cerebral blood flow during exercise. / Caldwell, Hannah G; Coombs, Geoff B; Howe, Connor A et al.
Yn: Journal of Physiology, Cyfrol 598, Rhif 8, 04.2020, t. 1459-1473.

Allbwn ymchwil: Cyfraniad at gyfnodolynErthygladolygiad gan gymheiriaid

HarvardHarvard

Caldwell, HG, Coombs, GB, Howe, CA, Hoiland, RL, Patrician, A, Lucas, SJE & Ainslie, PN 2020, 'Evidence for temperature-mediated regional increases in cerebral blood flow during exercise', Journal of Physiology, cyfrol. 598, rhif 8, tt. 1459-1473. https://doi.org/10.1113/JP278827

APA

Caldwell, H. G., Coombs, G. B., Howe, C. A., Hoiland, R. L., Patrician, A., Lucas, S. J. E., & Ainslie, P. N. (2020). Evidence for temperature-mediated regional increases in cerebral blood flow during exercise. Journal of Physiology, 598(8), 1459-1473. https://doi.org/10.1113/JP278827

CBE

Caldwell HG, Coombs GB, Howe CA, Hoiland RL, Patrician A, Lucas SJE, Ainslie PN. 2020. Evidence for temperature-mediated regional increases in cerebral blood flow during exercise. Journal of Physiology. 598(8):1459-1473. https://doi.org/10.1113/JP278827

MLA

VancouverVancouver

Caldwell HG, Coombs GB, Howe CA, Hoiland RL, Patrician A, Lucas SJE et al. Evidence for temperature-mediated regional increases in cerebral blood flow during exercise. Journal of Physiology. 2020 Ebr;598(8):1459-1473. doi: 10.1113/JP278827

Author

Caldwell, Hannah G ; Coombs, Geoff B ; Howe, Connor A et al. / Evidence for temperature-mediated regional increases in cerebral blood flow during exercise. Yn: Journal of Physiology. 2020 ; Cyfrol 598, Rhif 8. tt. 1459-1473.

RIS

TY - JOUR

T1 - Evidence for temperature-mediated regional increases in cerebral blood flow during exercise

AU - Caldwell, Hannah G

AU - Coombs, Geoff B

AU - Howe, Connor A

AU - Hoiland, Ryan L

AU - Patrician, Alexander

AU - Lucas, Samuel J E

AU - Ainslie, Philip N

N1 - © 2020 The Authors. The Journal of Physiology © 2020 The Physiological Society.

PY - 2020/4

Y1 - 2020/4

N2 - Aerobic exercise elicits increases in cerebral blood flow (CBF), as well as core body temperature; however, the isolated influence of temperature on CBF regulation during exercise has not been investigated The present study assessed CBF regulation and neurovascular coupling during submaximal cycling exercise and temperature-matched passive heat stress during isocapnia (i.e. end-tidal PCO2 was held constant) Submaximal cycling exercise and temperature-matched passive heat stress provoked ∼16% increases in vertebral artery blood flow, independent of changes in end-tidal PCO2 and blood pressure External carotid artery blood flow increased by ∼43% during both exercise and passive heat stress, with no change in internal carotid artery blood flow Neurovascular coupling (i.e. the relationship between local increases in cerebral metabolism and appropriately matched increases in regional cerebral blood flow) is preserved during both exercise and temperature-matched passive heat stress ABSTRACT: Acute moderate-intensity exercise increases core temperature (Tc ; +0.7-0.8°C); however, such exercise increases cerebral blood flow (CBF; +10-20%) mediated via small elevations in arterial PCO2 and metabolism. The present study aimed to isolate the role of Tc from PCO2 on CBF regulation during submaximal exercise. Healthy adults (n = 11; 10 males/one female; 26 ± 4 years) participated in two interventions each separated by ≥48 h: (i) 60 min of semi-recumbent cycling (EX; 50% workload max) and (ii) 75 min of passive heat stress (HS; 49°C water-perfused suit) to match the exercise-induced increases in Tc (EX: Δ0.75 ± 0.33°C vs. HS: Δ0.77 ± 0.33°C, P = 0.855). Blood flow (Q) in the internal and external carotid arteries (ICA and ECA, respectively) and vertebral artery (VA) (Duplex ultrasound) was measured. End-tidal PCO2 and PO2 were effectively clamped to resting values within each condition. The QICA was unchanged with EX and HS interventions (P = 0.665), consistent with the unchanged end-tidal PCO2 (P = 0.327); whereas, QVA was higher throughout both EX and HS (EX: Δ16 ± 21% vs. HS: Δ16 ± 23%, time effect: P = 0.006) with no between condition differences (P = 0.785). These increases in QVA contributed to higher global CBF throughout both EX and HS (EX: Δ12 ± 20% vs. HS: Δ14 ± 14%, time effect: P = 0.029; condition effect: P = 0.869). The QECA increased throughout both EX and HS (EX: Δ42 ± 58% vs. HS: Δ53 ± 28%, time effect: P < 0.001; condition effect: P = 0.628). Including blood pressure as a covariate did not alter these CBF findings (all P > 0.05). Overall, these data provide new evidence for temperature-mediated elevations in posterior CBF during exercise that are independent of changes in PCO2 and blood pressure.

AB - Aerobic exercise elicits increases in cerebral blood flow (CBF), as well as core body temperature; however, the isolated influence of temperature on CBF regulation during exercise has not been investigated The present study assessed CBF regulation and neurovascular coupling during submaximal cycling exercise and temperature-matched passive heat stress during isocapnia (i.e. end-tidal PCO2 was held constant) Submaximal cycling exercise and temperature-matched passive heat stress provoked ∼16% increases in vertebral artery blood flow, independent of changes in end-tidal PCO2 and blood pressure External carotid artery blood flow increased by ∼43% during both exercise and passive heat stress, with no change in internal carotid artery blood flow Neurovascular coupling (i.e. the relationship between local increases in cerebral metabolism and appropriately matched increases in regional cerebral blood flow) is preserved during both exercise and temperature-matched passive heat stress ABSTRACT: Acute moderate-intensity exercise increases core temperature (Tc ; +0.7-0.8°C); however, such exercise increases cerebral blood flow (CBF; +10-20%) mediated via small elevations in arterial PCO2 and metabolism. The present study aimed to isolate the role of Tc from PCO2 on CBF regulation during submaximal exercise. Healthy adults (n = 11; 10 males/one female; 26 ± 4 years) participated in two interventions each separated by ≥48 h: (i) 60 min of semi-recumbent cycling (EX; 50% workload max) and (ii) 75 min of passive heat stress (HS; 49°C water-perfused suit) to match the exercise-induced increases in Tc (EX: Δ0.75 ± 0.33°C vs. HS: Δ0.77 ± 0.33°C, P = 0.855). Blood flow (Q) in the internal and external carotid arteries (ICA and ECA, respectively) and vertebral artery (VA) (Duplex ultrasound) was measured. End-tidal PCO2 and PO2 were effectively clamped to resting values within each condition. The QICA was unchanged with EX and HS interventions (P = 0.665), consistent with the unchanged end-tidal PCO2 (P = 0.327); whereas, QVA was higher throughout both EX and HS (EX: Δ16 ± 21% vs. HS: Δ16 ± 23%, time effect: P = 0.006) with no between condition differences (P = 0.785). These increases in QVA contributed to higher global CBF throughout both EX and HS (EX: Δ12 ± 20% vs. HS: Δ14 ± 14%, time effect: P = 0.029; condition effect: P = 0.869). The QECA increased throughout both EX and HS (EX: Δ42 ± 58% vs. HS: Δ53 ± 28%, time effect: P < 0.001; condition effect: P = 0.628). Including blood pressure as a covariate did not alter these CBF findings (all P > 0.05). Overall, these data provide new evidence for temperature-mediated elevations in posterior CBF during exercise that are independent of changes in PCO2 and blood pressure.

KW - Adult

KW - Blood Flow Velocity

KW - Carbon Dioxide

KW - Cerebrovascular Circulation

KW - Exercise

KW - Female

KW - Humans

KW - Male

KW - Regional Blood Flow

KW - Temperature

U2 - 10.1113/JP278827

DO - 10.1113/JP278827

M3 - Article

C2 - 31912506

VL - 598

SP - 1459

EP - 1473

JO - Journal of Physiology

JF - Journal of Physiology

SN - 0022-3751

IS - 8

ER -