The Bohr Effect Is Not a Likely Promoter of Renal Preglomerular Oxygen Shunting
نویسندگان
چکیده
The aim of this study was to evaluate whether possible preglomerular arterial-to-venous oxygen shunting is affected by the interaction between renal preglomerular carbon dioxide and oxygen transport. We hypothesized that a reverse (venous-to-arterial) shunting of carbon dioxide will increase partial pressure of carbon dioxide and decrease pH in the arteries and thereby lead to increased oxygen offloading and consequent oxygen shunting. To test this hypothesis, we employed a segment-wise three-dimensional computational model of coupled renal oxygen and carbon dioxide transport, wherein coupling is achieved by shifting the oxygen-hemoglobin dissociation curve in dependence of local changes in partial pressure of carbon dioxide and pH. The model suggests that primarily due to the high buffering capacity of blood, there is only marginally increased acidity in the preglomerular vasculature compared to systemic arterial blood caused by carbon dioxide shunting. Furthermore, effects of carbon dioxide transport do not promote but rather impair preglomerular oxygen shunting, as the increase in acidity is higher in the veins compared to that in the arteries. We conclude that while substantial arterial-to-venous oxygen shunting might take place in the postglomerular vasculature, the net amount of oxygen shunted at the preglomerular vasculature appears to be marginal.
منابع مشابه
Renal oxygenation: preglomerular vasculature is an unlikely contributor to renal oxygen shunting.
The primary aim of this study was to assess the plausibility of preglomerular arterial-to-venous oxygen shunting in the kidney. To this end, we have developed a segment-wise three-dimensional computational model that takes into account transport processes in arteries, veins, cortical tissue, and capillaries. Our model suggests that the amount of preglomerular oxygen shunting is negligible. Cons...
متن کاملCALL FOR PAPERS Renal Hypoxia Renal oxygenation: preglomerular vasculature is an unlikely contributor to renal oxygen shunting
Olgac U, Kurtcuoglu V. Renal oxygenation: preglomerular vasculature is an unlikely contributor to renal oxygen shunting. Am J Physiol Renal Physiol 308: F671–F688, 2015. First published December 10, 2014; doi:10.1152/ajprenal.00551.2014.—The primary aim of this study was to assess the plausibility of preglomerular arterial-tovenous oxygen shunting in the kidney. To this end, we have developed a...
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To understand how geometric factors affect arterial-to-venous (AV) oxygen shunting, a mathematical model of diffusive oxygen transport in the renal cortex was developed. Preglomerular vascular geometry was investigated using light microscopy (providing vein shape, AV separation, and capillary density near arteries) and published micro-computed tomography (CT) data (providing vessel size and AV ...
متن کاملLetter to the editor: "The plausibility of arterial-to-venous oxygen shunting in the kidney: it all depends on radial geometry".
TO THE EDITOR: we read with great interest the recent paper by Olgac and Kurtcuoglu (5) entitled “Renal oxygenation: preglomerular vasculature is an unlikely contributor to renal oxygen shunting.” We commend the authors on their careful approach to the problem of oxygen transport in the renal cortex. The authors’ model simulations support an important contribution of oxygen delivery to tissue f...
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