Modulation of the myogenic mechanism: concordant effects of NO synthesis inhibition and O<sub>2</sub><sup>−</sup> dismutation on renal autoregulation in the time and frequency domains

Moss, Nicholas; Gentle, Tayler K.; Arendshorst, William J.

doi:10.1152/ajprenal.00461.2015

Cited by 7 publications

(20 citation statements)

References 95 publications

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“…As in the MAP = 100 mm Hg case, increasing R NO slightly increases flow, while decreasing R NO decreases network flow at the simulated pressures. The time response for the change in total blood flow with MAP is also faster in the absence of NO, which is consistent with recent experimental mouse renal studies showing the effects of NOS inhibition …”

Section: Discussionsupporting

confidence: 90%

A dynamic computational network model for the role of nitric oxide and the myogenic response in microvascular flow regulation

et al. 2018

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Section: Discussionsupporting

confidence: 90%

A dynamic computational network model for the role of nitric oxide and the myogenic response in microvascular flow regulation

et al. 2018

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“…A second peak, located in 30–60 mHz, is also present in most of the experimental transfer functions. This peak is attributed to the operation of TGF and is missing from preparation in which TGF is inhibited by either ureteral obstruction (e.g., Daniels et al 1990; Moss et al 2016), administration of furosemide (e.g., Shi et al 2006; Just et al 1998; Ajikobi et al 1996), or induced hydronephrosis (e.g., Cupples and Loutzenhiser 1998). Similarly, such peak is present in every model that includes an active TGF and is missing from all models in which TGF is inhibited.…”

Section: Discussionmentioning

confidence: 99%

Transfer Function Analysis of Dynamic Blood Flow Control in the Rat Kidney

Sgouralis¹,

Maroulas²

2016

Bull Math Biol

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Renal blood flow is regulated by the myogenic response (MR) and tubuloglomerular feedback (TGF). Both mechanisms function to buffer not only steady pressure perturbations but also transient ones. In this study, we develop two models of renal autoregulation—a comprehensive model and a simplified model—and use them to analyze the individual contributions of MR and TGF in buffering transient pressure perturbations. Both models represent a single nephron of a rat kidney together with the associated vasculature. The comprehensive model includes detailed representation of the vascular properties and cellular processes. In contrast, the simplified model represents a minimal set of key processes. To assess the degree to which fluctuations in renal perfusion pressure at different frequencies are attenuated, we derive a transfer function for each model. The transfer functions of both models predict resonance at 45 and 180 mHz, which are associated with TGF and MR, respectively, effective autoregulation below ~100 mHz, and amplification of pressure perturbations above ~200 mHz. The predictions are in good agreement with experimental findings.

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“…Other known mediators of septic renal microcirculatory dysfunction include reactive oxygen species (ROS) and endothelin-1. Studies have yielded conflicting results, with ROS shown to enhance the myogenic response [ 67 ] and regulate TGF [ 68 ], but also to abolish autoregulation in juxtamedullary afferent arterioles [ 69 ]. Conversely, renal hypoxanthine/xanthine oxidase-generated superoxide production in rats did not affect autoregulation of RBF [ 70 ].…”

Section: Renal Autoregulation In Critical Illnessmentioning

confidence: 99%

Renal autoregulation and blood pressure management in circulatory shock

Post

Vincent

2018

Crit Care

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The importance of personalized blood pressure management is well recognized. Because renal pressure–flow relationships may vary among patients, understanding how renal autoregulation may influence blood pressure control is essential. However, much remains uncertain regarding the determinants of renal autoregulation in circulatory shock, including the influence of comorbidities and the effects of vasopressor treatment. We review published studies on renal autoregulation relevant to the management of acutely ill patients with shock. We delineate the main signaling pathways of renal autoregulation, discuss how it can be assessed, and describe the renal autoregulatory alterations associated with chronic disease and with shock.

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Modulation of the myogenic mechanism: concordant effects of NO synthesis inhibition and O₂⁻ dismutation on renal autoregulation in the time and frequency domains

Cited by 7 publications

References 95 publications

A dynamic computational network model for the role of nitric oxide and the myogenic response in microvascular flow regulation

A dynamic computational network model for the role of nitric oxide and the myogenic response in microvascular flow regulation

Transfer Function Analysis of Dynamic Blood Flow Control in the Rat Kidney

Renal autoregulation and blood pressure management in circulatory shock

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Modulation of the myogenic mechanism: concordant effects of NO synthesis inhibition and O2− dismutation on renal autoregulation in the time and frequency domains

Cited by 7 publications

References 95 publications

A dynamic computational network model for the role of nitric oxide and the myogenic response in microvascular flow regulation

A dynamic computational network model for the role of nitric oxide and the myogenic response in microvascular flow regulation

Transfer Function Analysis of Dynamic Blood Flow Control in the Rat Kidney

Renal autoregulation and blood pressure management in circulatory shock

Contact Info

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Modulation of the myogenic mechanism: concordant effects of NO synthesis inhibition and O₂⁻ dismutation on renal autoregulation in the time and frequency domains