2 Phys - Introduction to the kidney✅.pdf

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Introduction to the kidney
Course Renal system

Lecturer Prof David Henshall
Overview

Functions of the kidney
Body fluid composition
The nephron
Simple overview of urine formation
The kidney is a key organ in homeostasis
Kidney structure
Bean shaped organs located on
either side of the spine under the
ribcage

Filter blood removing waste and
water to make urine.

Urine travels down the ureter and
gets stored the bladder
 Kidney structure

Kidneys: Bilateral retroperitoneal organs

Blood supply: Renal artery and vein

Filtrate forms in Bowman’s capsule in the Cortex

Urine flows from collecting ducts into calyces.
 Primary function of the kidneys

1. Regulate the volume and composition of the extracellular fluid (ECF).

Kidneys regulate volume and composition of the plasma which then results in regulation of volume
and composition of the entire ECF

2. Eliminate potentially toxic metabolic wastes and foreign compounds
 Functions of the kidneys cont.

Maintain water balance in body

Maintaining proper plasma volume
Regulation of blood pressure

Maintain osmolarity (solute concentration) of body fluids
primarily by regulating water balance
 Functions of the kidneys cont.

Regulating quantity and concentration of extracellular fluid ions
Na+, K+, Cl-, Ca2+, PO43-

Maintaining acid-base balance
pH
 Functions of the kidneys cont.

Excreting waste products of metabolism
– Urea (from metabolism of amino acids)
– Uric acid (from metabolism of nucleic acids)

Excreting foreign compounds
– Drugs, food additives

Other
–Converting vitamin D to active form (by proximal tubule cells)
Regulation of Ca /bone
2+

– Producing erythropoietin (cells in interstitium of cortex/outer medulla)
Hormone stimulates red blood cell production
 Renal control of body fluid composition

Water accounts for 60% of body mass 2/3
is intracellular, 1/3 extracellular

Extracellular fluid is the fluid outside cells

It consists of:
The plasma which surrounds the
blood cells
The interstitial fluid which surrounds
the cells of all other tissues
There is free exchange of water and solutes, except proteins, between
plasma and interstitial fluid (across capillary walls)
Distribution of fluid depends on hydrostatic and osmotic forces

Intracellular fluid

Changes in composition will
affect cell physiology!
Body fluid composition
 Determinants of plasma and ECF osmolarity
Plasma osmolarity determined mainly by NaCl content relative to the
water content of the blood (salt accounts for major ionic/osmotic content of plasma)

A decrease in water content, by
increasing the NaCl concentration,
increases osmolarity

An increase in water content, by
lowering the NaCl concentration,
lowers osmolarity

Kidneys maintain water balance in
order to maintain plasma/ECF 1 mmol free ions = 1 mosmol
osmolarity constant
The osmolarity of plasma and ECF is normally
maintained constant at 283 ± 11 mosmol/l.

This in turn maintains the osmolarity of cell fluid
Qu: Is there a tendency for the content of the ECF (and therefore
the blood), to change?

Food contains salts and water → continuing tendency for levels of
salt and water to rise
Exercise (sweating)
Other causes: vomiting, diarrhoea…

Kidneys offset this effect by excreting salt and water in amounts
appropriate to intake
 Functional unit of the kidney - nephron

The nephron is the functional
unit of the kidney.
Approx. 1 - 1.2 million nephrons
in each kidney.
Each nephron consists of two
parts.
Two sub-parts of the nephron

The renal corpuscle
tuft of capillaries (glomerulus)
Bowman’s capsule

Tubular system
fluid filled tube formed by single
layer of epithelial cells
Vascular supply
Nephron structure – more detail
 Tubular components of the nephron and
their functions

Bowman’s Capsule – collects glomerular filtrate
Proximal Convoluted Tubule (PCT) – absorption and secretion of
selected substances occurs here
Loop of Henle – establishes an osmotic gradient in the renal medulla
(ascending and descending loops have different channels/functions)
Distal Convoluted Tubule (DCT) – controlled reabsorption of Na+ and
water, secretion of K+ and H+
Collecting Duct – takes fluid (urine) into the renal pelvis
What is the functional unit of the kidney?
a. Glomerulus
b. Bowman’s capsule
c. Nephron
d. Collecting duct
Basic processes performed by the nephron
1) Filtration of blood
2) Tubular reabsorption
3) Tubular secretion
 Simple overview of urine formation
Filtration of blood to
form Salt and water
Reabsorption of content of filtrate
tubular filtrate
most of the adjusted to match
(mainly salt &
filtrate back intake
water)
into blood
Blood leaving in
Efferent arteriole

Blood entering in
afferent arteriole

Secretion from
blood, of certain
substances,
into filtrate
 Renal blood flow (RBF) and blood supply to nephron

First process in nephron is ultrafiltration of the plasma in the
glomerulus. This step is dependent on generation of strong hydrostatic
pressure in nephron

Kidney requires abundant blood supply

Blood supply to the two kidneys is via the renal arteries

Blood flow to the kidneys is ~1.2 L/min.
very high: 1/5 of cardiac output*

*normalized for tissue weight this is 7 fold higher than the brain!
 Blood supply of the nephron
Renal artery subdivides to form many afferent
arterioles which each supply a nephron

Glomerular capillaries recombine to leave
Bowmans Capsule as efferent arterioles.

Efferent arterioles give rise to peritubular
capillaries which invest the tubular system
of each nephron.

These then recombine to form venules and
the renal vein
Function of Peritubular Capillaries

1. Nutritive

2. Reabsorptive

3. Secretive
 1. Glomerular filtration

Plasma from the blood entering glomerulus is filtered out (~20%)
into Bowman’s capsule

Filtrate then flows through tubular system where substances of
value are reabsorbed to peritubular plasma
What passes through the filtration barrier to form the
tubular filtrate?

All components of plasma, except cells and proteins, pass
(a small amount of protein does pass but is immediately reabsorbed – a normal sample of urine
should have no protein).

So, useful substances as well as waste pass through
Volume of tubular filtrate formed

Approx. 180 litres of filtrate forms per day - entire ECF
“treated” ~10 times per day

Approx. 1.5 litres of urine are excreted

Therefore, approx. 178.5 litres of filtrate must be reabsorbed
(returned to the blood) per day
2. Tubular reabsorption

Tubular reabsorption is tremendous, highly selective & variable

Tubules have high reabsorptive capacity for substances needed

Little/no reabsorptive capacity for useless/harmful substances (which stay in
filtrate)

99 % filtered is subsequently reabsorbed
99% of H20, 100% glucose, 99.5% salt
 Tubular reabsorption
Can be active (energy requiring) or passive

Active: one or more steps in transepithelial transport requires energy (ATP)
expenditure

Active: glucose, amino acids, Na+
Movement during one or more steps against a gradient

Passive: water, chloride ion
occurs down electrochemical or osmotic gradient
Tubular reabsorption involves transepithelial transport
Steps of trans-epithelial transport
1) Substance leaves tubular fluid
2) Passes through cytosol of tubular cell
3) Crosses basolateral membrane
4) Diffuses through interstitial space
5) Penetrates capillary wall to enter blood plasma

Tubular epithelial cell
Capillary wall
Peri-tubular capillary
Basolateral
membrane
Tubular lumen
*Tight junctions between tubular
cells prevent substances
moving in-between cells →
materials must pass through
cells
plasma
Interstitial fluid
 Example: Na+ reabsorption*

Tubule cell
Tubular lumen

diffusion
Na+
diffusion
K+ ATP Na+
K+
plasma
Interstitial fluid

*dealt with in full in a later lecture
 Reabsorption is substance and location specific

Proximal tubule
Na+ 67% H20 65%

Loop of Henle
Na+ 25% H20 15%

Distal tubule and collecting tubules
Na+ 8% H20 20%
3. Tubular secretion

Also involves transepithelial transport
Transfer of substances from peritubular capillaries
into tubular lumen
H+, potassium, organic ions
Drugs, food additives environmental pollutants
Urine excreted
Urine is final “product” of nephron’s work. Approx. 1ml/min formed

Comprises:
H20
Urea (formed in liver as end product of protein metabolism)
Creatinine (waste product of muscles)
Ions (Na+, K+)
Phenol

Slightly acidic (pH approx. 6.0)
Osmolarity varies according to water levels (from 50 – 1200 mOsm)
Learning outcomes
Explain the main functions of the kidneys.

Describe the basic tubular and vascular system of the nephron.

Explain the three major processes performed by the nephron to produce
urine.

Describe body fluid composition.

Define the normal volume and composition of urine.
 Reading suggestions

“Medical Sciences” by Niash (Ch 14)

“Human Physiology” by Sherwood (Ch 14, 15)

https://www.youtube.com/watch?v=FN3MFhYPWWo