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Related Experiment Video

Updated: Jun 1, 2026

Oxygenation-sensitive Cardiac MRI with Vasoactive Breathing Maneuvers for the Non-invasive Assessment of Coronary Microvascular Dysfunction
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An association between vasomotion and oxygen extraction.

Clare E Thorn1, Hayley Kyte, Dick W Slaff

  • 1Diabetes and Vascular Medicine, Institute of Biomedical and Clinical Sciences, Peninsula College of Medicine and Dentistry, University of Exeter, National Institute for Health Research Peninsula Clinical Research Facility, Exeter, United Kingdom. clare.thorn@pms.ac.uk

American Journal of Physiology. Heart and Circulatory Physiology
|May 24, 2011
PubMed
Summary

Vasomotion, or spontaneous vascular tone oscillations, may improve tissue oxygenation. This study found that red blood cells might sense local hypoxia and trigger vasodilation, enhancing blood flow.

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Area of Science:

  • Physiology
  • Biomedical Engineering

Background:

  • Vasomotion, characterized by local oscillations in vascular tone, is a physiological phenomenon with an unclear functional role.
  • It is hypothesized that vasomotion may play a beneficial role in tissue oxygenation.
  • Cutaneous microcirculation dynamics can be investigated using optical reflectance spectroscopy and laser Doppler fluximetry.

Purpose of the Study:

  • To investigate the mechanisms of vasomotion in the cutaneous microcirculation.
  • To explore the relationship between vasomotion, tissue oxygenation, and blood flow regulation.
  • To determine if red blood cells act as sensors for local tissue hypoxia.

Main Methods:

  • Simultaneous measurement of oxyhemoglobin ([HbO(2)]), deoxyhemoglobin ([Hb]), and mean blood saturation (S(mb)O(2)) using optical reflectance spectroscopy.
  • Laser Doppler fluximetry was employed to measure blood flux.
  • Fourier analysis was used to identify periodic fluctuations in S(mb)O(2) in the dorsal forearm skin of healthy males.

Main Results:

  • Periodic fluctuations in S(mb)O(2) were observed in 19 out of 24 subjects, particularly at skin temperatures above 29.3°C.
  • A minimum S(mb)O(2) threshold preceded a surge in flux and a rise in S(mb)O(2), suggesting upstream vasodilation in response to downstream hypoxia.
  • Obese subjects exhibited a significantly longer S(mb)O(2) half-life, indicating slower oxygen extraction compared to normal-weight subjects.

Conclusions:

  • The findings support the hypothesis that red blood cells, through hemoglobin oxygenation status, can sense local tissue hypoxia.
  • This sensing mechanism may initiate hypoxic vasodilation, leading to improved local tissue perfusion.
  • Vasomotion appears to be a critical regulatory mechanism for maintaining adequate tissue oxygenation.