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Results for: 'proximal covoluted tubule'
Glomerular filtrate rate: pressures that affect GFR, NFP & GFR and blood composition
By: HWC, Views: 8217
• The glomerular filtration rate is the amount of filtrate formed per minute within the renal corpuscle. • Once the filtrate is formed it moves down the tubule. • The production and movement of filtrate depends on three pressures: I. Glomerular blood hydrostatic pressure (GBHP) is ...
Regulation of GFR: autoregulation via tubuloglomerular feedback, neural & hormonal regulation
By: HWC, Views: 8917
• When blood pressure is above normal, rapid filtrate flow reduces ion retention so filtrate in tubule has more Na+, C1-, and water. • It is believed that vasoconstricting chemicals from the juxtaglomerular cells are released when the macula densa cells detect higher water and ion levels in ...
Regulation of GFR: autoregulation via myogenic mechanism Myogenic mechanism
By: HWC, Views: 9212
• GFR can be regulated by adjusting: • Blood flow in and out of the glomerular capillaries. • Surface area of glomerular capillaries. • There are three main ways to make these adjustments: • Renal autoregulation. • Nervous regulation. • Renal autoregulation occurs when...
Carbohydrate Metabolism: Introduction to renal processes and filtrate formation and composition
By: HWC, Views: 7923
• At the nephron, the three process responsible for the formation of urine include: • Glomerular filtration. • Tubular reabsorption. • Tubular secretion. • During filtration, a filtrate is formed within the renal tubule. • Reabsorption is the conserving of water and many s...
Regulation of GFR: three methods, autoregulation & autoregulation via myogenic mechanism
By: HWC, Views: 8179
• GFR can be regulated by adjusting: • Blood flow in and out of the glomerular capillaries. • Surface area of glomerular capillaries. • There are three main ways to make these adjustments: • Renal autoregulation. • Nervous regulation. • Hormonal regulation. • Ren...
By: HWC, Views: 8448
▪ The primary cause of the medullary osmotic gradient is the active transport of solutes. • In the ascending limb of the loop, active transport of Na+ ions drives passive reabsorption of Cl- ions. • Addition of these ions to the interstitial fluid of the medulla increases its osmolarity...
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