Brachial artery responses to acute hypercapnia: The roles of shear stress and adrenergic tone

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Brachial artery responses to acute hypercapnia: The roles of shear stress and adrenergic tone. / Carr, Jay M J R; Ainslie, Philip N; Howe, Connor A; Gibbons, Travis D; Tymko, Michael M; Steele, Andrew R; Hoiland, Ryan L; Vizcardo-Galindo, Gustavo A; Patrician, Alex; Brown, Courtney V; Caldwell, Hannah Grace; Tremblay, Joshua C.

In: Experimental Physiology, Vol. 107, No. 12, 2022, p. 1440-1453.

Research output: Contribution to journalJournal articleResearchpeer-review

Harvard

Carr, JMJR, Ainslie, PN, Howe, CA, Gibbons, TD, Tymko, MM, Steele, AR, Hoiland, RL, Vizcardo-Galindo, GA, Patrician, A, Brown, CV, Caldwell, HG & Tremblay, JC 2022, 'Brachial artery responses to acute hypercapnia: The roles of shear stress and adrenergic tone', Experimental Physiology, vol. 107, no. 12, pp. 1440-1453. https://doi.org/10.1113/EP090690

APA

Carr, J. M. J. R., Ainslie, P. N., Howe, C. A., Gibbons, T. D., Tymko, M. M., Steele, A. R., Hoiland, R. L., Vizcardo-Galindo, G. A., Patrician, A., Brown, C. V., Caldwell, H. G., & Tremblay, J. C. (2022). Brachial artery responses to acute hypercapnia: The roles of shear stress and adrenergic tone. Experimental Physiology, 107(12), 1440-1453. https://doi.org/10.1113/EP090690

Vancouver

Carr JMJR, Ainslie PN, Howe CA, Gibbons TD, Tymko MM, Steele AR et al. Brachial artery responses to acute hypercapnia: The roles of shear stress and adrenergic tone. Experimental Physiology. 2022;107(12):1440-1453. https://doi.org/10.1113/EP090690

Author

Carr, Jay M J R ; Ainslie, Philip N ; Howe, Connor A ; Gibbons, Travis D ; Tymko, Michael M ; Steele, Andrew R ; Hoiland, Ryan L ; Vizcardo-Galindo, Gustavo A ; Patrician, Alex ; Brown, Courtney V ; Caldwell, Hannah Grace ; Tremblay, Joshua C. / Brachial artery responses to acute hypercapnia: The roles of shear stress and adrenergic tone. In: Experimental Physiology. 2022 ; Vol. 107, No. 12. pp. 1440-1453.

Bibtex

@article{afcc23f70aa94adc8f221fd6efd7bd33,
title = "Brachial artery responses to acute hypercapnia: The roles of shear stress and adrenergic tone",
abstract = "We aimed to assess the shear stress dependency of brachial artery (BA) responses to hypercapnia, and the α₁-adrenergic restraint of these responses. We hypothesized that elevated shear stress during hypercapnia would cause BA vasodilatation, but where shear stress was prohibited (via arterial compression), the BA would not vasodilate (study 1); and, in the absence of α₁-adrenergic activity, blood flow, shear stress and BA vasodilatation would increase (study 2). In study 1, 14 healthy adults (7/7 male/female, 27 ± 4 years) underwent bilateral BA duplex ultrasound during hypercapnia (partial pressure of end-tidal carbon dioxide, +10.2 ± 0.3 mmHg above baseline, 12 min) via dynamic end-tidal forcing, and shear stress was reduced in one BA using manual compression (compression vs. control arm). Neither diameter nor blood flow was different between baseline and the last minute of hypercapnia (P = 0.423, P = 0.363, respectively) in either arm. The change values from baseline to the last minute, in diameter (%; P = 0.201), flow (ml/min; P = 0.234) and conductance (ml/min/mmHg; P = 0.503) were not different between arms. In study 2, 12 healthy adults (9/3 male/female, 26 ± 4 years) underwent the same design with and without α₁-adrenergic receptor blockade (prazosin; 0.05 mg/kg) in a placebo-controlled, double-blind and randomized design. BA flow, conductance and shear rate increased during hypercapnia in the prazosin control arm (interaction, P < 0.001), but in neither arm during placebo. Even in the absence of α₁-adrenergic restraint, downstream vasodilatation in the microvasculature during hypercapnia is insufficient to cause shear-mediated vasodilatation in the BA.",
keywords = "Faculty of Science, Autonomic control, Blood flow, Carbon dioxide, Vascular function",
author = "Carr, {Jay M J R} and Ainslie, {Philip N} and Howe, {Connor A} and Gibbons, {Travis D} and Tymko, {Michael M} and Steele, {Andrew R} and Hoiland, {Ryan L} and Vizcardo-Galindo, {Gustavo A} and Alex Patrician and Brown, {Courtney V} and Caldwell, {Hannah Grace} and Tremblay, {Joshua C}",
note = "{\textcopyright} 2022 The Authors. Experimental Physiology {\textcopyright} 2022 The Physiological Society.",
year = "2022",
doi = "10.1113/EP090690",
language = "English",
volume = "107",
pages = "1440--1453",
journal = "Experimental Physiology",
issn = "0958-0670",
publisher = "Wiley-Blackwell",
number = "12",

}

RIS

TY - JOUR

T1 - Brachial artery responses to acute hypercapnia: The roles of shear stress and adrenergic tone

AU - Carr, Jay M J R

AU - Ainslie, Philip N

AU - Howe, Connor A

AU - Gibbons, Travis D

AU - Tymko, Michael M

AU - Steele, Andrew R

AU - Hoiland, Ryan L

AU - Vizcardo-Galindo, Gustavo A

AU - Patrician, Alex

AU - Brown, Courtney V

AU - Caldwell, Hannah Grace

AU - Tremblay, Joshua C

N1 - © 2022 The Authors. Experimental Physiology © 2022 The Physiological Society.

PY - 2022

Y1 - 2022

N2 - We aimed to assess the shear stress dependency of brachial artery (BA) responses to hypercapnia, and the α₁-adrenergic restraint of these responses. We hypothesized that elevated shear stress during hypercapnia would cause BA vasodilatation, but where shear stress was prohibited (via arterial compression), the BA would not vasodilate (study 1); and, in the absence of α₁-adrenergic activity, blood flow, shear stress and BA vasodilatation would increase (study 2). In study 1, 14 healthy adults (7/7 male/female, 27 ± 4 years) underwent bilateral BA duplex ultrasound during hypercapnia (partial pressure of end-tidal carbon dioxide, +10.2 ± 0.3 mmHg above baseline, 12 min) via dynamic end-tidal forcing, and shear stress was reduced in one BA using manual compression (compression vs. control arm). Neither diameter nor blood flow was different between baseline and the last minute of hypercapnia (P = 0.423, P = 0.363, respectively) in either arm. The change values from baseline to the last minute, in diameter (%; P = 0.201), flow (ml/min; P = 0.234) and conductance (ml/min/mmHg; P = 0.503) were not different between arms. In study 2, 12 healthy adults (9/3 male/female, 26 ± 4 years) underwent the same design with and without α₁-adrenergic receptor blockade (prazosin; 0.05 mg/kg) in a placebo-controlled, double-blind and randomized design. BA flow, conductance and shear rate increased during hypercapnia in the prazosin control arm (interaction, P < 0.001), but in neither arm during placebo. Even in the absence of α₁-adrenergic restraint, downstream vasodilatation in the microvasculature during hypercapnia is insufficient to cause shear-mediated vasodilatation in the BA.

AB - We aimed to assess the shear stress dependency of brachial artery (BA) responses to hypercapnia, and the α₁-adrenergic restraint of these responses. We hypothesized that elevated shear stress during hypercapnia would cause BA vasodilatation, but where shear stress was prohibited (via arterial compression), the BA would not vasodilate (study 1); and, in the absence of α₁-adrenergic activity, blood flow, shear stress and BA vasodilatation would increase (study 2). In study 1, 14 healthy adults (7/7 male/female, 27 ± 4 years) underwent bilateral BA duplex ultrasound during hypercapnia (partial pressure of end-tidal carbon dioxide, +10.2 ± 0.3 mmHg above baseline, 12 min) via dynamic end-tidal forcing, and shear stress was reduced in one BA using manual compression (compression vs. control arm). Neither diameter nor blood flow was different between baseline and the last minute of hypercapnia (P = 0.423, P = 0.363, respectively) in either arm. The change values from baseline to the last minute, in diameter (%; P = 0.201), flow (ml/min; P = 0.234) and conductance (ml/min/mmHg; P = 0.503) were not different between arms. In study 2, 12 healthy adults (9/3 male/female, 26 ± 4 years) underwent the same design with and without α₁-adrenergic receptor blockade (prazosin; 0.05 mg/kg) in a placebo-controlled, double-blind and randomized design. BA flow, conductance and shear rate increased during hypercapnia in the prazosin control arm (interaction, P < 0.001), but in neither arm during placebo. Even in the absence of α₁-adrenergic restraint, downstream vasodilatation in the microvasculature during hypercapnia is insufficient to cause shear-mediated vasodilatation in the BA.

KW - Faculty of Science

KW - Autonomic control

KW - Blood flow

KW - Carbon dioxide

KW - Vascular function

U2 - 10.1113/EP090690

DO - 10.1113/EP090690

M3 - Journal article

C2 - 36114662

VL - 107

SP - 1440

EP - 1453

JO - Experimental Physiology

JF - Experimental Physiology

SN - 0958-0670

IS - 12

ER -

ID: 324233133