bp(HM:"Renal Blood Flow, limited")
By contrast, no or limited increases in renal blood flow are observed during acute hemodilution (15, 42), leading to earlier and more severe renal tissue hypoxia (5, 38), and an increase in the magnitude of hypoxia signaling responses, including stabilization of the transcription factor hypoxia- inducible factor- (HIF-) (42, 43). PubMed:29351418
The absent or relatively small increase in renal blood flow likely contributed to the occurrence of renal tissue hypoxia in both models. PubMed:29351418
The renal blood flow response to anemia is proportionally much smaller than the increase observed in cerebral blood flow (50–100%). This relative difference in organ blood flow likely explains why the kidney becomes profoundly hypoxic, whereas brain oxygenation is largely preserved during anemia (12, 32, 42). PubMed:29351418
Our data provided clear evidence of renal tissue hypoxia, which was in part due to a lack of increase in renal blood flow. PubMed:29351418
By contrast, no or limited increases in renal blood flow are observed during acute hemodilution (15, 42), leading to earlier and more severe renal tissue hypoxia (5, 38), and an increase in the magnitude of hypoxia signaling responses, including stabilization of the transcription factor hypoxia- inducible factor- (HIF-) (42, 43). PubMed:29351418
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If you find BEL Commons useful in your work, please consider citing: Hoyt, C. T., Domingo-Fernández, D., & Hofmann-Apitius, M. (2018). BEL Commons: an environment for exploration and analysis of networks encoded in Biological Expression Language. Database, 2018(3), 1–11.