11 Renal1 Kidney function I.pdf

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IMED3112: Integrated Medical Systems 2
Renal Physiology Lecture 1
Kidney Function 1
Rob White
Physiology
[email protected]

Lecture Outcomes
• Outline the functions of the kidney in maintaining
homeostasis
• Describe the nephron’s role in filtration, reabsorption and
secretion
• Describe the physiological control of renal blood flow and
glomerular filtration
• Describe the regulation of tubular filtrate modification
Read: Guyton & Hall Chapters 26 -29

What have my kidneys done for me lately?
•

Regulation of:
–
–
–

•

Excretion of:
–
–
–

•

body fluid osmolarity and volume
blood pressure
Electrolyte/acid-base balance

metabolic products - urea, uric acid, creatinine, bilirubin
foreign substances (pesticides, chemicals etc.)
excess substance (water, etc)

Endocrine function et al.:
–
–
–

EPO, renin, vitamin D activation
Excretion of hormones (clearance)
Gluconeogenesis

Urinary system

The Nephron

Nephrons

• Renal corpuscle (glomerulus and Bowman’s capsule)
and both convoluted tubules in cortex, loop of Henle
extend into medulla
• Multiple nephrons empty into single collecting duct
• 2 types:
– Cortical nephrons – 80% of nephrons

• Renal corpuscle in outer portion of cortex and short loops of
Henle extend only into outer region of medulla

– Juxtamedullary nephrons – other 20%

• Renal corpuscle deep in cortex and long loops of Henle
extend deep into medulla
• Peritubular capillaries and vasa recta
• Ascending limb has defined thick and thin regions
• Enable kidney to secrete very dilute or very concentrated
urine

Nephrons and blood vessel structure
Cortical nephrons

Juxtamedullary nephrons

Nephron: vascular component
Glomerulus:
ball-like tuft of glomerular
capillaries  filter blood plasma.
Renal artery:
Afferent arteriole
•Supplies the glomerulus capillaries.
Efferent arteriole
• Drains glomerulus
•Forms (subdivides) the peritubular
capillaries (which later rejoin to form
venules & renal vein).

Nephron: tubular component
Distal
. tubule
Proximal
tubule
Efferent arteriole
Afferent arteriole
Cortex
Medulla

Juxtaglomerular
region
Bowman’s capsule

Cups glomerulus & collects
filtered fluid, which passes into
tubule

Collecting duct
Loop of Henle
U shaped loop that dips into renal
medulla

Input from up to 8 distal
tubules. Drains into the renal
pelvis.

Functions of the Nephron
Reabsorption

Secretion
Excretion

Filtration

Urine Formation
Blood in
Filtration
GFR
Peritubular space

Filtrate
Crude  refined
Reabsorption
(osmosis)
Secretion

Blood out
Urine out

Overview of renal physiology
1. Glomerular filtration
– Water + most solutes in plasma filter out of glomerular
capillaries into Bowman’s capsule  renal tubule
2. Tubular reabsorption
– As filtered fluid moves along tubule and through collecting
duct, about 99% of water and many useful solutes
reabsorbed  peritubular space  returned to blood
3. Tubular secretion
– Material is secreted into tubular fluid (such as wastes,
drugs, and excess ions) – removes substances from blood
• Solutes in tubular fluid  renal pelvis  excreted (urine)
Solute excretion = glomerular filtration + secretion - reabsorption

Filtration and Reabsorption of Some
Compounds

Nephron Function

Renal Blood Flow
2 Functions
• Provides blood to be
filtered
• Reclaims reabsorbed
substances

Blood supply of the kidneys
• Immense blood supply
– <0.5% of body mass, receive 2025% of cardiac output at rest
– ~95% to cortex
– Renal art  segmental, interlobar,
arcuate, interlobular arts
–  afferent arteriole (1 per
nephron)  glomerulus
–  Efferent arteriole (1 per
nephron)  peritubular
capillaries (vasa recta) 
peritubular venule  renal vein

2 capillary beds in series
1. Glomerular
High hydrostatic pressure
(~55 mmHg)
2. Peritubular
Low hydrostatic pressure
(~13 mmHg)

Vasa Recta

Pglom.cap. vs Pperitub.cap.
Starling’s Law: NFP = (CHP + IFOP) – (PCOP + IFHP)
•

Net filtration pressure (NFP) balance of 2 pressures

1. Pressures that promote filtration
2.

–
–
–
–

Capillary hydrostatic pressure (CHP)
Interstitial fluid osmotic pressure (IFOP)

Pressures that promote reabsorption

Plasma colloid osmotic pressure (PCOP)
Interstitial fluid hydrostatic pressure (IFHP)

• Glomerular capillary:

– CHP > PCOP, drives filtration

• Peritubular capillary:

– PCOP > CHP, net reabsorption from peritubular space.

Not just P, PCOP increases
• Glomerular filtration
concentrates proteins in
capillaries  increase
PCOP
• Thus low P, high PCOP
create a strong absorptive
environment in
peritubular
capillaries/vasa recta

Glomerular filtration
Fluids move across the glomerular
capillary in response to net
glomerular hydrostatic pressure
 glomerular filtrate (plasma-like)

• Prevents filtration of large things

– Cells, platelets
– Protein complexes
– Large/medium-sized (>50kDa) proteins

• GFR

– Depends on

• Permeability of membrane
• surface area of membrane
• filtration pressure

3 barriers to cross

Glomerular capillary
wall (pores between
endothelial cells).
Basement
membrane
- mix of collagen
(structural) &
glycoproteins
(repel plasma
proteins).
Podocytes: filtration
slits between cellular
foot processes.

Filtration slit
Pedicel
Fenestration (pore) of glomerular
1 endothelial cell: prevents filtration of
blood cells but allows all components
of blood plasma to pass through
2

3

Basal lamina of glomerulus:
prevents filtration of larger proteins
Slit membrane between pedicels:
prevents filtration of medium-sized
proteins

Podocyte of visceral
layer of glomerular
(Bowman’s) capsule

Factors that determining glomerular filterability
1. Molecular weight
•

Size-exclusion

2. Charges of the molecule
•

Negative charges of the basement membrane/podocytes repel
anions

Glomerular filtration rate (GFR)
– amount of filtrate formed in all the renal
corpuscles of both kidneys each minute
– For a young healthy 70kg adult, GFR=125ml/min
or 180 L/day (36x blood volume)
– Homeostasis requires kidneys maintain a relatively
constant GFR
• Too high –too quick for reabsorption
• Too low – excessive reabsorption, some waste products
not adequately excreted - Renal hypoxia

– GFR directly related to net filtration pressure

Net filtration pressure (NFP)
• The total pressure that promotes filtration

NFP = GBHP – CHP – BCOP
GBHP: Glomerular blood hydrostatic pressure
The blood pressure of the glomerular capillaries forcing water
and solutes through filtration slits
CHP: Capsular hydrostatic pressure
the hydrostatic pressure exerted against the filtration
membrane by fluid already in the capsular space and
represents “back pressure”
BCOP: Blood colloid osmotic pressure
due to presence of proteins in blood plasma and also opposes
filtration

1 GLOMERULAR BLOOD
HYDROSTATIC PRESSURE
(GBHP) = 55 mmHg

2 CAPSULAR HYDROSTATIC
PRESSURE (CHP) = 15 mmHg
3 BLOOD COLLOID
OSMOTIC PRESSURE
(BCOP) = 30 mmHg

Afferent arteriole
(larger diameter)

Proximal convoluted tubule

Sites of
regulation
Efferent
arteriole
(smaller diameter)
Glomerular
(Bowman's)
capsule

NET FILTRATION PRESSURE (NFP)
=GBHP – CHP – BCOP
= 55 mmHg 15 mmHg 30 mmHg
= 10 mmHg
Capsular
space

Controlling filtration pressure
Renal arteriolar resistance
•
•
•
•
•
•

Efferent arteriole constriction
Reduces renal blood flow
Increases GFR
Afferent arteriole constriction
Reduces renal blood flow
Reduces GFR

Aff. art.

Eff. art.

↓ RBF/GFR
↑ RBF/GFR
↓RBF/↑GFR

Three Mechanisms regulating GFR
1. Renal autoregulation
2. Neural regulation
3. Hormonal regulation

1. Renal autoregulation
•

Kidneys themselves maintain constant renal blood flow and
GFR using
–
–

Myogenic mechanism – occurs when stretching triggers contraction
of smooth muscle cells in afferent arterioles – reduces GFR
Tubuloglomerular mechanism – macula densa provides feedback to
glomerulus, inhibits release of NO causing afferent arterioles to
constrict and decreasing GFR

Autoregulation of GFR and RBF
The kidneys are able
to maintain a fairly
constant RBF and
GFR over a large
range of arterial
pressures.
This is a local effect
intrinsic to the
kidneys
Rhoades & Tanner, 2003

If there was no autoregulation
At normal MAP (100 mmHg)
- GFR = 125 mL/min or 180 L/day
- results in 1.5 L/day of urine
production.
Increasing MAP to 125 mmHg would
-↑ GFR to 225 L/day
- urine flow = 46.5 L/day.
 Extreme FLUID and SALT LOSS!

Myogenic Autoregulation
•

Automatic regulation of RBF + GFR

•

In response to slight changes in BP

•

Control at the local level (e.g. smooth
muscle cells)
(a) ↑ MAP automatically induces
vasoconstriction of afferent
arteriole  ↓ flow  ↓ GFR and
bringing it back to normal
(b) ↓ MAP induces afferent arteriole
vasodilation  ↑ flow and GFR, and
bringing GFR back to normal levels.

Tubuloglomerular feedback
↑ GFR = ↑ amount
of solutes (NaCl)

[NaCl] sensors
↑ GFR = ↑ NaCl load,
↓ time to reabsorb it
↓ GFR = ↓ NaCl load,
↑time to reabsorb it

NaCl reabsorption
Is time dependent
– ↑time ↓[NaCl]

The Juxtaglomerular Apparatus

Sherwood,
1997

Tubuloglomerular feedback
• Juxtaglomerular apparatus - Macula densa (MD)
– a collection of densely packed epithelial cells at the TAL/DCT junction.
– Juxtaposed to its own glomerulus, between the afferent and efferent
arterioles.
– Position enables it to rapidly alter glomerular resistance in response to
changes in the flow rate through the distal nephron.

• MD monitors tubular fluid composition (an indicator of GFR).
– ↑ DCT [NaCl]  ↓ time spent in tubules  elevated GFR
– ↓ DCT [NaCl]  ↑ time spent in tubules  reduced GFR

• MD NaCl sensor: Na-K-2Cl cotransporter (NKCC2).
– Decreased NaCl stimulates the release of NO from the macula densa
 aff. art. dilation  ↑ GFR.
– ↓ DCT [NaCl]  aff. art dilation  ↑ GFR
– ↑DCT [NaCl]  aff. art. constriction  ↓ GFR

Extra-Renal Factors affecting GFR
1. Sympathetic nerves  NA
Moderate - ↓Aff./Eff. art. ↓ RBF/GFR  ↓ urine  ↑
Bvol/BP
Maximal - ↓↓↓ Aff. art. ↓↓↓ GFR
– normally minimal activity; overrides if strong
•

eg. after haemorrhage  “renal shut-down”

2. Circulating hormones
–

Atrial natriuretic peptide (ANP):
•

–

↑Aff.:↓Eff. ↑↑ GFR (noΔRBF)

Angiotensin II: **complex and variable**
•

↓Aff.:↓↓Eff.  ↓RBF: ↓/noΔ GFR (limits RBF but ‘maintains’
GFR due to greater efferent constriction) (*but massively
increases BP at the same time  ↑ ↑ ↑ perfusion pressure* =
it depends, sorry )

Angiotensin is also regulated by
Tubuloglomerular Feedback

↓ GFR  ↓[NaCl]
 renin release 
AtII

Fine tuning...
Intraglomerular mesangial cells
• Intraglomerular mesangial cells (smooth muscle-ish) regulate
intraglomerular capillary blood flow.
• MC contraction is coupled with contraction of the glomerular
capillary endothelium basement membrane  ↓ surface
area  ↓ GFR
Respond to:
• AtII, ANP, ADH
• NO
• Capillary stretch

On to
the tubules...