This site is intended for healthcare professionals

Go to /sign-in page

You can view 5 more pages before signing in

Thermoregulatory vasodilatation

Last reviewed dd mmm yyyy. Last edited dd mmm yyyy

Authoring team

Cutaneous vasodilatation is one means by which body temperature can be reduced. More blood and its associated heat is transferred from the body core to the periphery of the skin. More blood per unit time through the skin is proportional to more heat loss per unit time from its surface via radiation, conduction and convection.

It is produced by two influences, both acting to reduce precapillary vascular resistance:

  • diminshed neural signals from the hypothalamus descending via sympathetic efferent fibres to synapse with alpha-1-adrenoceptors on arteriolar smooth muscle
  • local factors e.g. heat, humidity and hypoxia acting on smooth muscle

Thus, blood flow is shunted from deep to more superficial plexuses within the skin. In tandem, the autonomic nervous system may also decrease the volume of blood passing through alternative vascular beds to the skin e.g. the gut, so shunting blood at a more central level.

Finally, a greater volume of blood per unit time through the skin also reduces the efficiency of counter-current exchange mechanisms between arterioles and venules. This results in less heat conservation.


Create an account to add page annotations

Add information to this page that would be handy to have on hand during a consultation, such as a web address or phone number. This information will always be displayed when you visit this page

The content herein is provided for informational purposes and does not replace the need to apply professional clinical judgement when diagnosing or treating any medical condition. A licensed medical practitioner should be consulted for diagnosis and treatment of any and all medical conditions.

Connect

Copyright 2024 Oxbridge Solutions Limited, a subsidiary of OmniaMed Communications Limited. All rights reserved. Any distribution or duplication of the information contained herein is strictly prohibited. Oxbridge Solutions receives funding from advertising but maintains editorial independence.