The production of maximally concentrated urine is made possible by the renal countercurrent multiplication system, which generates and maintains a hypertonic inner medulla, comprised of cortico- medullary gradients of NaCl and urea. Many features of the multiplication system remain to be elucidated, in particular the role of the medullary microcirculation. By modulating blood flow, vasa recta (i.e., the blood vessels in the renal medulla) can have a major effect on sodium and water homeostasis as well as on the long-term control of arterial blood pressure; their role in hypertension and congestive heart failure is thus highly relevant. Changes in renal medullary hemodynamics are also directly involved in pressure natriuresis. The overall goal of this research is to develop a comprehensive mathematical model of the renal medullary microcirculatory function in order to predict the efficiency of countercurrent exchange of water, small solutes, and macromolecules by the vasa recta.
The specific aims of this project are the following. 1. To investigate the specific role of water channels (AQP-1) and urea transporters in descending vasa recta, incorporating data obtained on wildtype mice, AQP-1 deficient mice and AQP-1 deficient mice in which the AQP-1 gene has been replaced by means of an adenovirus. 2. To determine the mechanisms that control interstitial albumin concentration. The effects of albumin concentration polarization at the vessel walls will be determined as a first step. 3. To model the transport of oxygen in the renal medulla and to examine the effects of changes in blood flow rate and tubular consumption on oxygen tension. Medullary hypoxia is a consequence of the need for countercurrent exchange; however, too little oxygen can cause medullary hypoxic injury. 4. To examine how secretion of the vasoactive hormone nitric oxide into the vascular exchanger affects medullary blood flow and interstitial osmolality, and to investigate the relationship between the reduced medullary hematocrit, medullary hypoxia and the effectiveness of NO in the medulla.

Agency
National Institute of Health (NIH)
Institute
National Institute of Diabetes and Digestive and Kidney Diseases (NIDDK)
Type
Research Project (R01)
Project #
5R01DK053775-05
Application #
6635091
Study Section
General Medicine B Study Section (GMB)
Program Officer
Ketchum, Christian J
Project Start
1999-07-15
Project End
2004-06-30
Budget Start
2003-07-01
Budget End
2004-06-30
Support Year
5
Fiscal Year
2003
Total Cost
$114,467
Indirect Cost
Name
Tufts University
Department
Engineering (All Types)
Type
Schools of Engineering
DUNS #
073134835
City
Medford
State
MA
Country
United States
Zip Code
02155
Sgouralis, Ioannis; Layton, Anita T (2012) Autoregulation and conduction of vasomotor responses in a mathematical model of the rat afferent arteriole. Am J Physiol Renal Physiol 303:F229-39
Edwards, Aurelie; Cao, Chunhua; Pallone, Thomas L (2011) Cellular mechanisms underlying nitric oxide-induced vasodilation of descending vasa recta. Am J Physiol Renal Physiol 300:F441-56
Edwards, Aurelie; Layton, Anita T (2011) Modulation of outer medullary NaCl transport and oxygenation by nitric oxide and superoxide. Am J Physiol Renal Physiol 301:F979-96
Edwards, Aurélie (2010) A possible catalytic role for NH4+ in Na+ reabsorption across the thick ascending limb. Am J Physiol Renal Physiol 298:F510-1
Edwards, Aurelie; Layton, Anita T (2010) Nitric oxide and superoxide transport in a cross section of the rat outer medulla. I. Effects of low medullary oxygen tension. Am J Physiol Renal Physiol 299:F616-33
Loreto, Milagros; Layton, Anita T (2010) An optimization study of a mathematical model of the urine concentrating mechanism of the rat kidney. Math Biosci 223:66-78
Cao, Chunhua; Edwards, Aurélie; Sendeski, Mauricio et al. (2010) Intrinsic nitric oxide and superoxide production regulates descending vasa recta contraction. Am J Physiol Renal Physiol 299:F1056-64
Chen, Jing; Edwards, Aurelie; Layton, Anita T (2010) Effects of pH and medullary blood flow on oxygen transport and sodium reabsorption in the rat outer medulla. Am J Physiol Renal Physiol 298:F1369-83
Layton, Anita T; Edwards, Aurelie (2010) Tubuloglomerular feedback signal transduction in a short loop of henle. Bull Math Biol 72:34-62
Edwards, Aurelie (2010) Modeling transport in the kidney: investigating function and dysfunction. Am J Physiol Renal Physiol 298:F475-84

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