Lecture 19 PDF - Kidney Function

Summary

This lecture provides an overview of kidney function, including the anatomy of the urinary system and the processes of filtration, reabsorption, and secretion. It emphasizes the key roles of the kidneys in maintaining fluid and electrolyte balance, as well as their role in hormone production and waste excretion.

Full Transcript

About This Chapter
19.1

Functions of the Kidneys

19.2

Anatomy of the Urinary System

19.3

Overview of Kidney Function

19.4

Filtration

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19.1 Functions of the Kidneys
When ECF volume decreases, blood pressure too

1. Regulation of extracellular fluid volume and blood pressure
2. Regulation of osmolarity

to maintain it to 290 mOsM
balancing dietary intake with urinary loss

is the major ion involved in regulation of ECF volume and osmolarity
3. Maintenance of ion balance Sodium
Potassium and calcium concentration closely regulated too
If ECF too acidic, kidneys remove H+ and converse HCO3- (buffer)

4. Homeostatic regulation of pH If too alkaline, opposite

5. Excretion of wastes like creatinine, urea, urobilinogen (yellow color), saccharin, benzoate
cytokine regulating RBC synthesis
6. Production of hormones Erythropoietine:
Renin: regulates production of hormones involved in sodium balance and blood pressure
homeostasis
Renal enzymes: conversion of vitamin D3 into a hormone that regulates CA2+ balance

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Figure 19.1(a-b) Anatomy summary
(a) Urinary system,
(b) Structure of the Kidney

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Figure 19.1(c-d) Anatomy summary

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Figure 19.1(e-f,h) Anatomy summary

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Figure 19.1(g-h) Anatomy summary

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19.2 Overview of Kidney function
•

Kidneys filter, reabsorb, and secrete

•

Filtration
– Fluid from blood into the lumen of the nephron
– Occurs at renal corpuscle
– Filtered plasma is called filtrate – excreted unless reabsorbed

•

Reabsorption
– Materials in the filtrate are passed back into the blood
– Occurs with peritubular capillaries

•

Secretion
– Material from blood into lumen of tubule
selective process that usually uses membrane proteins
– Occurs with peritubular capillaries more
to move molecules across the tubule epithelium
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The Nephron Modifies Fluid Volume and
Osmolarity
•

Filtrate is almost identical plasma at the renal corpuscle
–

•

About 70% of filtrate is reabsorbed by the proximal tubules
–
–

•

More solute is reabsorbed than water, diluted
18 L/day remains, 100 mOsm

Distal tubule and collecting duct
–
–

•

Solutes and water
54 L/day remains, 300 mOsm

Filtrate in the loop of Henle
–
–

•

180 L/day, 300 mOsm

Some reabsorption and secretion
1.5 L/day remains, 100 – 1200 mOsm depending on hydration state

Amount excreted = amount filtered – amount reabsorbed +
amount secreted
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Figure 19.2 Nephron Function (1 of 2)

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Figure 19.2 Nephron Function (2 of 2)

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Figure 19.3 Solute movement through the
nephron

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19.4 Filtration
•

Filtration fraction
– % renal flow that filters into the tubule

•

The renal corpuscle contains filtration barriers

•

Filtration occurs in the renal corpuscle
– Glomerular capillary endothelium
pores that allow most components of plasma to filter through
▪ Fenestrated capillaries large
endothelium
▪ Glycocalyx lattice-like layer of glycoproteins lining luminal surface of capillary and pores
acellular layer of extracellular matrix that separates capillary endothelium from
of Bowman’s capsule
– Basement membrane epithelium
negatively charged glycoproteins, collagen, and other proteins —> exclude
most plasma proteins from fluid that filters through it
– Epithelium of Bowman’s capsule
▪ Podocytes specialized cells that surround each glomerular capillary
foot processes wrap around glomerural capillaries and
long cytoplasmic
with one another, leaving narrow filtration slits
extensions that
– Foot processes and filtration slits interlace
closed by a slit diaphragm
extend from the main
body cell
lie between and around glomerular capillaries, creating a support structure for tuft of capillaries,
filtration by altering surface area of filtration slits + secrete cytokines associated with
▪ Mesangial cellsinfluence
immune and inflammatory processes
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Figure 19.4 The filtration fraction

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Figure 19.5(a-b) The renal corpuscle

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Figure 19.5(c-d) The renal corpuscle

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Capillary Pressure Causes Filtration (1 of 2)
• Three pressures influence glomerular filtration
1. Capillary blood pressure (PH)

▪ Hydrostatic pressure ( ~ 55 mm Hg)

forces fluid through leaky endothelium
capillary blood pressure = 55 mm Hg and favours filtration

Bowman’s capsule
▪ Favors filtration into
Pressure decreases as blood moves through capillaries, it remains higher than
opposing pressures

glomerular capillaries higher than that of the fluid in
2. Capillary colloid osmotic pressure (π) inside
Bowman’s capsule

pressure gradient

▪ Due to proteins in plasma
▪ ~ 30 mm Hg
▪ Opposes filtration (pulls fluid back to plasma) favors fluid movement back into capillaries

3. Capsule fluid pressure (Pfluid)

▪ Hydrostatic pressure inside Bowman’s capsule ( ~ 15 mm Hg)
▪ Opposes filtration

fluid filtering out of capillaries must displace fluid already in capsule lumen

• Net pressure = PH – π – Pfluid = 10 mm Hg into Bowman’s capsule
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Capillary Pressure Causes Filtration (2 of 2)
•

Glomerular Filtration Rate (GFR) – volume of fluid filtered per unit time
–

Influenced by
▪

Net filtration pressure
–

▪

Renal blood flow and blood pressure

Filtration coefficient
–

Surface areas of glomerular capillaries available for filtration

–

Permeability of filtration slits

•

GFR is relatively constant

•

GFR is controlled primarily by regulating blood flow through the renal arterioles
–

Increased resistance in afferent arteriole, decreases GFR

–

Increased resistance in efferent arteriole, increases GFR

–

Decreased resistance in afferent arteriole, increases GFR

–

Decreased resistance in efferent arteriole, decreases GFR
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Figure 19.6(a) Glomerular Filtration Rate

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Figure 19.6(b) Glomerular Filtration Rate

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Figure 19.6(c-e) Glomerular Filtration
Rate

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GFR Is Subject to Autoregulation
a decrease in GFR helps body conserve blood volume
Vasoconstriction, after depolarization, increases resistance to flow, so blood flow through
arteriole diminishes, which decrease filtration pressure in glomerulus
Since vasodilation is not as effective as vasoconstriction bc afferent arteriole fairly
relaxed, when blood pressure < 80 mm Hg, GFR decreases

•

Myogenic response
– Intrinsic ability of vascular smooth muscle to respond to
pressure changes
– Similar to autoregulation in other systemic arterioles with depolarization and Ca2+

•

Tubuloglomerular feedback
– Paracrine control local pathway in which fluid flow through tubule influences GFR
tubule and
When NaCl delivery past the macula
– Juxtaglomerular apparatus where
arteriolar walls are
dense increases as a result of
together
increased GFR, the macula dense cells
paracrine message to
▪ Macula densa cells detect NaCl in the filtrate send
neighbouring afferent arteriole
The afferent arteriole constricts,
increasing resistance and decreasing
▪ Granular cells secrete enzyme renin
GFR

•

Hormones and autonomic neurons also influence GFR
– By changing resistance in arterioles
– By altering the filtration coefficient
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Figure 19.7(a-b) The juxtaglomerular
apparatus

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Figure 19.7(c) The juxtaglomerular
apparatus

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Key words
kidneys, ureter, urinary bladder, urethra, micturition, renal arteries,
renal veins, cortex, medulla, nephron, juxtamedullary nephron, cortical
nephron, afferent arteriole, glomerulus, efferent arteriole, peritubular
capillaries, vasa recta, Bowman’s capsule, renal corpuscle, proximal
tubule, loop of Henle, descending limb, ascending limb, distal tubule,
collecting duct, renal pelvis, urine, juxtaglomerular apparatus, filtration,
filtrate, excretion, reabsorption, secretion, filtration barriers, glomerular
capillaries, fenestrated capillaries, podocytes, foot processes, filtration
slits, mesangial cells, hydrostatic pressure (PH), colloid osmotic
pressure (π), fluid pressure (Pfluid),glomerular filtration rate (GFR),
myogenic response, tubuloglomerular feedback, macula densa,
granular cells.

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