- Introduction
- Normal anatomy of kidney
- Nephron
- Juxtaglomerular apparatus
- Clearance
- tubular function
- Regulation of water and ion reabsorption
- Types of water reabsorption
- Mechanism of urine concentration and dilution
- Countercurrent mechanism
2. Introduction
Normal anatomy of kidney
Nephron
Juxtaglomerular apparatus
Clearance
tubular function
Regulation of water and ion reabsorption
Types of water reabsorption
Mechanism of urine concentration and dilution
Counter current mechanism
3. --Other excretory organs are:
Skin
Lungs
GI tract : i. Heavy metals
ii. Drugs
iii. Fatty substances
6. PARTS OF KIDNEY :
• Renal cortex
• Renal medulla
• Renal pyramid
• Major calyx
• Minor calyx
• Pelvis
• Ureter
• Renal artery & vein
7. Number of nephron : 1 million
Conditions when number of
nephron decreases
Parts :
a. Bowman’s capsule
b. Proximal tubule
c. Loop of henle
d. Distal tubule
e. Collecting duct
a
b
d
e c
13. After glomerular filtration ; tubular handling of filtrate
is most important step
Glomerular filtration : NONSPECIFIC process
Tubular transport : SELECTIVE process
Control of ECF & urine volume and composition
16. Tubular load : total amount of solute filtered by all the
nephrons of both kidneys per minute.
Tubular load for glucose = 125 mg/min
Transport maximum (Tm) : maximum amount of solute
that can be reabsorbed by all nephrons of both kidneys
per minute .
Tm for glucose (in normal condition ) = 320 mg/min in
females ,375 mg/min in males
average = 360 mg/min
Glucose lost in urine = tubular load of glucose – Tm for glucose
17. Difference between theoretical and practical values (eg.
for glucose)
o Theoretically : tubular load : 350 mg/min --- not
excreted in urine
o Practically : tubular load : 225 mg/min --- excreted
in urine
Reasons: 1.heterogenecity of nephrons
2. kinetic of transport
Phenomenon : “SPLAY”
18. RENAL THRESHOLD :
“Concentration of solute in the plasma at or above which the
solute first appears in urine”
Eg : renal threshold of glucose :
--180mg% in venous plasma
--200 mg% in arterial plasma
19. Most important part of nephron
It reabsorbs about 67% of filtered water,Na+ ,Cl- ,K+
and HCO3- and almost all filtered glucose and amino
acid
PCT
Convoluted
Straight
Functionally both parts are
similar with few minor
differences
21. Entry of Na+
into tubular
cells
Cotransport
Antiport
mechanism
Associated
anion
reabsorption
Glucose,amino
acids,phosphates
etc
“SECONDARY
ACTIVE
TRANSPORT”
Na+ - H+
exchanger
“Accounts for
60% of total
Na+ entry”
HCO3- & Cl-
Process of
absorption is
different
2 REASONS :
Presence of more anion-antiporter
in distal part of proximal tubule
Concentration of Cl- is very high in
this part
22. Transfer of large amount of
water helps in transfer of
ions like K+ and Ca++ that
are carried along with water
“ SOLVENT DRAG”
23.
24. Totally reabsorb in PCT
By 2 mechanism: i. “secondary active transport”
ii. Degraded by cellular enzymes in epithelial
swretetrytytiujtregfhgjcells of PCT
Urine is practically protein free!
Cl- : mainly reabsorbed along with Na+ reabsorption
Recently , separate chloride channels have been identified in
kidney tubules
These Cl- channels are linked with Ca++ channels
25. Proximal tubules secretes various organic cations and
anions ; eg. Uric acid,PAH,drugs etc.
Plasma protein bound substance : not filtered in
glomerular filtration
Physiological significance : eg of gout
26. JUXTAMEDULLARY nephrons:
Longer
less in num
LOH of this type;helps in
‘urine concentration
LOH reabsorbes : 25% of filtered NaCl and K+
30% of filtered Ca++
65% of filtered Mg++
Descending limb of LOH: “Permeable” to water
Ascending limb of LOH: “Impermeable” to water
CORTICAL nephrons:
Shorter
More in num
LOH of this type;helps in ‘urine
formation’
29. Physiologically it is close to thick
ascending LOH ; therefore it is
“RELATIVELY IMPERMEABLE TO
WATER”
Only 5% of filtered water is removed in
DCT
30. Strictly speaking; it is not a part of an individual nephron but
is considered as distal part of nephrons
Important mechanisms: K+ excretion and hormonal water
reabsorption
DCT
Principal
cells
Intercalated
cells
Reabsorbe Na+ & secrete K+
Secrete either H+ or HCO3-
K+ metabolism
Acidification of urine
33. DIABETES INSIPIDUS: Access urine formation; 2 types:
Neurogenic DI -- due to ADH deficiency
Nephrogenic DI -- failure of collecting duct to respond to hormone (due to
mutation in gene for V2 receptor
IN MEDULLARY PART
Presence of adequate ADH:
1400 mosm/kg of H2O
(97.7% of filtered water is absorbed)
Absence of ADH:
30 mosm/kg of H2O
Relatively impermeable; even in
absence of ADH : about 2% filtered
water is reabsorbed
Osmolality of interstitium is very high
Accounts for about 5% of water
reabsorption
34. Hormonal factors
Neural factors
Starling forces
Tubuloglomerular feedback
Glomerulartubulo balance
Through sympathetic innervation of kidney
Activation leads to increase reabsorption of
water & NaCl
Find the site to
mention it
35. Dopamine
GlucocorticoidsUrodilatin
ANP
ADH
Aldosterone
Angiotensin II
Acts on PCT
NaCl &water
reabsorption
Acts on PCT
NaCl &water
reabsorption
-Have mild
mineralocorticoid
activity
-Acts on PCT
- NaCl &water
reabsorption
-secreted by DCT &
CD
-Acts on collecting
duct
- NaCl &water
reabsorption
-secreted by
myocytes of atria of
heart
-Acts on collecting
duct & DCT
- NaCl &water
reabsorption
37. GFR : 180 L/day, 1.5 L of urine is excreted daily
Kidney excretes concentrated urine to prevent volume
depletion from the body, in which osmolality of urine is
an index of its concentrating and diluting capacity
Under physiological condition , urine osmolality is a
function of solvent (water) excretion
Example of desert
ADH: external factor for kidney plays an important role
in urine concentration and dilution
38. Counter current means
“flow of fluid in opposite
direction in adjacent
structure”
Requires 3 conditions :
a. two tubes, should run
parallel to each other
b. movement of fluid
c. should be close proximity
to each other and should be
selectively permeable
40. Small osmotic gradient established -
multiplied into larger gradient :
“SINGLE EFFECT”
As tubular fluid in loop enters deeper
layer of medulla; becomes more
concentrated based on increasing
gradient of osmolality along axis of
loop “AXIAL GRADIENT”
3 MAIN FACTORS :
A. The rate of fluid flow
B. Strength of single effect
C. The length of LOH
41. The tubular fluid and blood in vasa recta entering into medulla becomes
gradually hyperosmolal and fluid and blood leaving medulla becomes
gradually hyposmolal. Thus interstitial osmolality increases gradually from
outer layers to inner layers of medulla reaching about 1200 mosm/kg of
water in innermost part. This osmolal gradient transfers water from tubular
fluid of collecting duct leaving the medulla that makes urine concentrated.