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Regulation of Water Balance
Vivek Bhalla, MD
Division of Nephrology
Stanford University School of Medicine
September 14th, 2015
Learning Objectives (3)
1. A rise in tonicity does what?
– Stimulates ADH, thirst
2. How is the kidney primed to concentrate urine?
– Countercurrent multiplication
– Countercurrent exchange
3. How that concentrating mechanism is utilized to
maintain water balance?
– What does ADH do to the kidney?
“Big Picture”
Hypothalamus
“Big Picture”
Hypothalamus
Hypothalamus
•Paraventricular
Neurons
•Supraoptic Nuclei
ADH Release
Kidney Anatomy
Hyperosmotic Medulla
•Tubular Lumen
•Tubular epithelial Cells
•Interstitium
•Endothelial cells – vasa recta
•Blood within the vasa recta
Kidney Anatomy
•Tubular Lumen
•Tubular epithelial Cells
•Interstitium
•Endothelial cells – vasa recta
•Blood within the vasa recta
Kidney Anatomy
Hyperosmotic Medulla
How is this
gradient
established?
Hyperosmotic Medulla
Counter Current Multiplication
Counter Current Multiplication
Countercurrent Multiplication
Countercurrent Exchange
ABC-
Artery
Vein
Collecting Duct
Countercurrent Exchange
Too Much or Too Little ADH
% of
water
remaining
In the
lumen
Relative to
the original
glomerular
filtrate
Aquaporins – Water Channels
Aquaporins – Water Channels
Urinary Concentration
Take Home Points (3)
1. ADH release and thirst are regulated by tonicity
2. Countercurrent multiplication and exchange ready the
medulla for ADH-dependent water reabsorption
3. ADH stimulates Aquaporin 2 insertion in the luminal
(apical) membrane along the collecting duct