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EXCRETORY EXCRETORY PRODUCTS AND THEIR PRODUCTS AND THEIR
ELIMINATIONELIMINATION
MADE BYMADE BY
S RATH PGT BIOS RATH PGT BIO
K V III BBSRK V III BBSR
http://students-learn.blogspot.com
DEFINITION
It is a process of waste removal in the form of ammonia, urea or uric acid produced during metabolic activities.
PROCESS OF EXCRETION
AMMONOTELISM UREOTELISM URICOTELISM
ORGANISMS
AMMONOTELICAmphibia Bony fishes
Aquatic insects
UREOTELICMammals
Marine fishesLand amphibians
URICOTELICReptile
Bird, land snails&
Insects
AMMONIA-THE WASTE
Highly toxicReadily soluble in waterExcreted by diffusion across
body surface or through gill surface.
AMMONIA-THE WASTE
Released as ammonium ionsKidney has no significant role
in its removal.E.g. bony fishes, aquatic
amphibians and aquatic insects
UREA-THE WASTE
Ammonia produced in liver is converted into urea
Less toxic waste than ammonia, so needs less water for its removal.
The waste is released into blood and excreted out by kidneys
Some amount of urea is retained in kidney matrix to maintain osmolarity.
E.g. mammals, marine fish, terrestrial amphibians
URIC ACID-THE WASTE
Less toxic than urea.Less soluble in water, so
animals conserve water with minimum water loss.
Waste is released in the form of paste or pellet.
Reptiles, birds, land snail, land insects
EXCRETORY ORGANS PLATYHELMINTHES (PLANIRIA)-
Protonephridia or flame cells ANNELIDA (EARTH WORM)-
Nephridia INSECTS-
Malpighian Tubules PRAWN-
Antennal Gland Or Green Glands VERTEBRATES- Kidney
HUMAN EXCRETORY ORGANS
A pair of kidney A pair of ureters Urinary bladder Urethra
L.S OF KIDNEYL.S OF KIDNEY
1.1. HILUMHILUM
2.2. RENAL PELVISRENAL PELVIS
3.3. CALYCESCALYCES
4.4. RENALCAPSULERENALCAPSULE
5.5. CORTEXCORTEX
6.6. MEDULLAMEDULLA
7.7. MEDULLARY PYRAMIDSMEDULLARY PYRAMIDS
8.8. RENAL COLUMN OR RENAL COLUMN OR COLUMNS OF BERTINICOLUMNS OF BERTINI
9.9. RENAL ARTERYRENAL ARTERY
10.10. RENAL VEINRENAL VEIN
11.11. URETERURETER
STRUCTURE OF STRUCTURE OF NEPHRONNEPHRON
1.1. Bowman’s capsuleBowman’s capsule
2.2. GlomerulusGlomerulus
3.3. Malpighian bodyMalpighian body
4.4. PCTPCT
5.5. Henel’s loop-Henel’s loop-ascending limb & ascending limb & descending limbdescending limb
6.6. DCTDCT
7.7. Collecting ductCollecting duct
8.8. Afferent arterioleAfferent arteriole
9.9. Efferent arterioleEfferent arteriole
PARTS OF NEPHRONPARTS OF NEPHRON
Nephron
Glomerulus Renal tubule
Henle’s loop Distal tubuleProximal tubule
Bowman’s capsule
Proximal convoluted tubule
Descending limb
Ascending limb
Distal convoluted tubule
Collecting duct
TYPES OF NEPHRONTYPES OF NEPHRON
CORTICALCORTICALJUXTA
MEDULLARYJUXTA
MEDULLARY
CORTICALCORTICAL JUXTA JUXTA MEDULLARYMEDULLARY
Glomeruli are in the Glomeruli are in the outer cortex.outer cortex.
Glomeruli are close Glomeruli are close to inner margin of the to inner margin of the cortex.cortex.
Short loops of henle.Short loops of henle. Long loops of henleLong loops of henle
Henle’s loops extend Henle’s loops extend only to a short only to a short distance in the distance in the medulla.medulla.
Henle’s loops are Henle’s loops are found deeper in the found deeper in the medulla.medulla.
Vasa rectae are Vasa rectae are absent.absent.
Vasa rectae are Vasa rectae are presentpresent
They are more They are more common (85%)common (85%)
They are less They are less common (15%)common (15%)
URINE FORMATION
GLOMERULARFILTRATION
REABSORPTIONTUBULAR
SECRETION
GLOMERULAR FILTRATION
A protein free fluid is filtered from the blood of glomerular capillaries into the lumens of bowman’s capsule.
The filtration is caused by the blood pressure in the glomerular capillaries.
Filtration occurs through three layers which form filtration membrane. They are endothelium of Glomerulus, epithelium of bowman’s capsule & basement membrane between the two layers.
The epithelial cells (podocytes) of bowman’s capsule are arranged in an intricate manner to leave some filtration slits through which blood is filtered finely.
GLOMERULAR FILTRATION
The glomerular filtration rate (GFR) is about 125ml/minute or 180L/day.
JGA is a specialised cellular apparatus located where dct passes close to bowman’s capsule between afferent and efferent arteriole. A fall in GFR activates the cells of the JGA to release renin which through a series of reactions, brings the GFR back to normal.
REABSORPTION
Nearly 90% of the filtrate is reabsorbed by epithelial cell lining of renal tubule.
Glucose, amino acids, Na+, Ca+
+,K+ are reabsorbed actively.Other substances like Cl- are
absorbed passively.
TUBULAR SECRETION
It is the process in which certain substance or ions like K+ and ammonia are directly secreted into the lumen of nephron.
This step is important because it helps to maintain ionic balance and pH of the body fluids.
ROLE OF DIFFERENT SEGMENTS OF NEPHRON
Malpighian body- ultrafiltration of blood from glomerular capillaries to lumen of Bowman’s capsule.
PCT- reabsorption of 70- 80% of electrolytes & water. Maintain pH and ionic balance of body fluids, by selective secretion of H+, NH4
+, K+ into the filtrate and by absorbing HCO3 ions.
ROLE OF DIFFERENT SEGMENTS OF NEPHRON
Henle’s loop- maintain high osmolarity of medullary interstitial fluid. Descending limb makes filtrate hypertonic and ascending limb makes filtrate hypotonic.
DCT- Reabsorption of Na+ and water, reabsorbs HCO3
-, secretes NH3, H+, K+ into filtrate. Maintains pH and sodium and potassium balance in blood.
Collecting duct- Reabsorption of water, transport of small amount of urea into interstitial fluid, maintain pH and ionic balance of body fluids.
MECHANISM-URINE CONC.
COUNTER CURRENT MECHANISM
Loop of henle and vasa rectae responsible for concentrating urine by a mechanism called counter-current system.
The flow of filtrate in two loops of henle is in opposite direction & forms a counter-current system.
The flow of blood in opposite direction in vasa rectae forms a counter-current system.
COUNTER CURRENT MECHANISM
The two factors responsible for increasing the osmolarity towards the medullary interstitium are (i) the proximity between the loop of henle and vasa rectae (ii) the counter current system in them.
The osmolarity in cortex is about 300mos/l and medulla 1200 mos/l, this gradient is maintained by NaCl & urea.
Interstitial gradient of NaCl is maintained by loop of henle.
COUNTER CURRENT MECHANISM
Concentration of NaCl increases in descending due to loss of water.
In ascending limb the salt passes actively and passively into interstitium making filtrate dilute.
Urea diffuse out from collecting duct reenters the ascending limb by diffusion.
The remaining urea is excreted in the urine.
In collecting duct water moves out by osmosis and urine becomes concentrated.
REGULATION OF
KIDNEY FUNCTION
BY HYPOTHALAMUS BY JGA
BY ATRIAL WALL
OF HEART
REGULATION OF KIDNEY FUNCTION BY HYPOTHALAMUS
Change in osmolarity and volume of blood & osmoreceptors are stimulated.
Stimulation of hypothalamus to release ADH from pituitary.
ADH signals DCT and collecting duct to reabsorb water from filtrate.
This increases blood volume which switch off osmoreceptors
REGULATION OF KIDNEY FUNCTION BY JGA
Glomerular blood flow/volume or pressure decreases.
JGA releases renin which converts angiotensinogen in the blood into angiotensin I and then angiotensin II.
Angiotensin II is a powerful vasoconstrictor and increases the glomerular blood pressure and maintains the glomerular filtration rate.
REGULATION OF KIDNEY FUNCTION BY JGA
Angiotensin II also activates the adrenal cortex to release aldosterone. Aldosterone stimulates the reabsorption of Na+ and water from PCT.
This leads to an increase in the blood volume and pressure and brings back the GFR to normal.
REGULATION OF KIDNEY FUNCTION BY ATRIAL WALL
An increase in the blood flow (volume) and pressure to the atria of the heart causes the release of Atrial Natriuretic Factor (ANF).
ANF causes vasodilatation and decreases the blood pressure.
Thus ANF functions antagonistically to the renin- angiotensin mechanism by inhibiting the release of renin.
URINARY SYSTEMDISORDERS
URINARY SYSTEMDISORDERS
UREMIAUREMIA RENAL CALCULIRENAL CALCULIGLOMERULO-NEPHRITIS
GLOMERULO-NEPHRITIS
