Pflügers Archiv

, Volume 380, Issue 1, pp 53–58 | Cite as

The effects of blood osmolality changes on cat carotid body chemoreceptors in vivo

  • Roberto Gallego
  • Carlos Belmonte
Heart, Circulation, Respiration and Blood; Environmental and Exercise Physiology

Abstract

The possibility that carotid chemoreceptors respond to changes in plasma osmolality was investigated in the cat, perfusing the carotid artery with blood made hyper- or hypo-osmotic and recording chemoreceptor activity from carotid nerve fibers. Blood made hyperosmotic with sucrose or NaCl reduced the chemoreceptor discharge, while hypoosmotic blood increased chemoreceptor activity. The minimal osmolality variation necessary to obtain a detectable frequency change was 3–8% of the control. Frequency changes of 30% of the control were obtained with a 20% variation in osmolality. The frequency variations produced by the osmotic changes lasted as long as the infusion was maintained (up to 15 min). In some instances a rebound was observed when iso-osmotic saline was perfused again. A transient change in frequency and a clear rebound were obtained when blood made hyperosmotic with glycerol was perfused. These effects probably reflect a rapid change in intracellular osmolality due to the free passage of glycerol across cellular membranes.

The modifications in chemoreceptor activity consecutive to osmolality variations are the opposite of those observed in isolated and superfused carotid bodies. As it is known that osmolality values affect the smooth muscle of the blood vessels, we conclude that our results are mainly produced by changes in carotid body blood flow due to a direct effect of hyper- and hypo-osmotic solutions on vascular muscle tone. Chemoreceptor excitation during a decrease in blood osmolality may contribute reflexly to the increased vascular resistance observed during acute osmolality reductions in man.

Key words

Osmolality Carotid body Chemoreceptors Carotid nerve Osmotic pressure 

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Copyright information

© Springer-Verlag 1979

Authors and Affiliations

  • Roberto Gallego
    • 1
  • Carlos Belmonte
    • 1
  1. 1.Department of PhysiologyUniversity of Utah College of MedicineSalt Lake CityUSA

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