Defining the Resistance to Oxygen Transfer in Tissue Hypoxia

Overview

Journal Experientia

Specialty Science

Date 1990 Dec 1

PMID 2253719

Citations 4

Authors

D P Jones

T Y Aw

A H Sillau

Affiliations

Soon will be listed here.

Abstract

Studies of O2 supply in freshly isolated adult mammalian cells provide new insight into the factors that limit mitochondrial oxygenation in vivo. Of particular importance, mitochondria are present at high densities and often in apparent clusters, both of which contribute to local O2 gradients under hypoxic conditions. Current evidence indicates that the mitochondrial distribution is a component of the differentiated phenotype of adult mammalian cells and that specific motors and anchoring mechanisms are present to allow redistribution in response to developmental, physiological and pathological challenges. To compare the importance of resistance to O2 transfer under different conditions and at different sites along the supply path in vivo, a simple mathematical expression of relative resistance to O2 supply is introduced. Under various pathophysiological conditions, this resistance increases in specific regions of the pulmonary, circulatory or cellular supply path and results in O2 deficiency in the mitochondria. Regardless of cause, the relative resistance increases dramatically in the vicinity of mitochondrial clusters during hypoxia.

Citing Articles

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Structure-function correlations in erythropoietin formation and oxygen sensing in the kidney.

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PMID: 1753679 DOI: 10.1007/BF01649319.

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