Regional thermal hyperemia in the human leg: evidence of the importance of thermosensitive mechanisms in the control of the peripheral circulation
Regional thermal hyperemia in the human leg: evidence of the importance of thermosensitive mechanisms in the control of the peripheral circulation
Hyperthermia is thought to increase limb blood flow through the activation of thermosensitive mechanisms within the limb vasculature, but the precise vascular locus in which hyperthermia modulates perfusion remains elusive. We tested the hypothesis that local temperature-sensitive mechanisms alter limb hemodynamics by regulating microvascular blood flow. Temperature and oxygenation profiles and leg hemodynamics of the common (CFA), superficial (SFA) and profunda (PFA) femoral arteries, and popliteal artery (POA) of the experimental and control legs were measured in healthy participants during: (1) 3 h of whole leg heating (WLH) followed by 3 h of recovery (n = 9); (2) 1 h of upper leg heating (ULH) followed by 30 min of cooling and 1 h ULH bout (n = 8); and (3) 1 h of lower leg heating (LLH) (n = 8). WLH increased experimental leg temperature by 4.2 ± 1.2ºC and blood flow in CFA, SFA, PFA, and POA by ≥3-fold, while the core temperature essentially remained stable. Upper and lower leg blood flow increased exponentially in response to leg temperature and then declined during recovery. ULH and LLH similarly increased the corresponding segmental leg temperature, blood flow, and tissue oxygenation without affecting these responses in the non-heated leg segment, or perfusion pressure and conduit artery diameter across all vessels. Findings demonstrate that whole leg hyperthermia induces profound and sustained elevations in upper and lower limb blood flow and that segmental hyperthermia matches the regional thermal hyperemia without causing thermal or hemodynamic alterations in the non-heated limb segment. These observations support the notion that heat-activated thermosensitive mechanisms in microcirculation regulate limb tissue perfusion during hyperthermia.
Esteves, Nuno Koch
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Gibson, Oliver R.
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Khir, Ashraf W.
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González‐Alonso, José
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4 August 2021
Esteves, Nuno Koch
c3310d39-48af-4724-bf88-c05400aaf6cb
Gibson, Oliver R.
ef1d3ede-1c1c-47c7-b05e-0c3fc021b725
Khir, Ashraf W.
42d09f0d-5bc5-4b7b-be7d-f4006f434029
González‐Alonso, José
df2a2938-29bc-4701-894e-3a71da30b637
Esteves, Nuno Koch, Gibson, Oliver R., Khir, Ashraf W. and González‐Alonso, José
(2021)
Regional thermal hyperemia in the human leg: evidence of the importance of thermosensitive mechanisms in the control of the peripheral circulation.
Physiological Reports, 9 (15), [e14953].
(doi:10.14814/phy2.14953).
Abstract
Hyperthermia is thought to increase limb blood flow through the activation of thermosensitive mechanisms within the limb vasculature, but the precise vascular locus in which hyperthermia modulates perfusion remains elusive. We tested the hypothesis that local temperature-sensitive mechanisms alter limb hemodynamics by regulating microvascular blood flow. Temperature and oxygenation profiles and leg hemodynamics of the common (CFA), superficial (SFA) and profunda (PFA) femoral arteries, and popliteal artery (POA) of the experimental and control legs were measured in healthy participants during: (1) 3 h of whole leg heating (WLH) followed by 3 h of recovery (n = 9); (2) 1 h of upper leg heating (ULH) followed by 30 min of cooling and 1 h ULH bout (n = 8); and (3) 1 h of lower leg heating (LLH) (n = 8). WLH increased experimental leg temperature by 4.2 ± 1.2ºC and blood flow in CFA, SFA, PFA, and POA by ≥3-fold, while the core temperature essentially remained stable. Upper and lower leg blood flow increased exponentially in response to leg temperature and then declined during recovery. ULH and LLH similarly increased the corresponding segmental leg temperature, blood flow, and tissue oxygenation without affecting these responses in the non-heated leg segment, or perfusion pressure and conduit artery diameter across all vessels. Findings demonstrate that whole leg hyperthermia induces profound and sustained elevations in upper and lower limb blood flow and that segmental hyperthermia matches the regional thermal hyperemia without causing thermal or hemodynamic alterations in the non-heated limb segment. These observations support the notion that heat-activated thermosensitive mechanisms in microcirculation regulate limb tissue perfusion during hyperthermia.
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Accepted/In Press date: 15 June 2021
Published date: 4 August 2021
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Local EPrints ID: 499422
URI: http://eprints.soton.ac.uk/id/eprint/499422
PURE UUID: 967e9a4c-f289-42d2-843e-b20af9c83fab
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Date deposited: 19 Mar 2025 17:44
Last modified: 20 Mar 2025 03:12
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Author:
Nuno Koch Esteves
Author:
Oliver R. Gibson
Author:
Ashraf W. Khir
Author:
José González‐Alonso
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