Download Embryology and Histology of Kidney - Kamineni Institute Of Medical

Embryology and Histology of
Kidney
Dr Gayatri
Assistant professor
Department of anatomy
Kamineni Institute of Medical Sciences
Narketpally
KIDNEYS
 Early
development and evolution of the kidney
 Intermediate
 Pronephros
mesoderm
 Mesonephros
 Metanephros
 Ascent
and abnormalities
INTERMEDIATE MESODERM
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Mesoderm appears in the 3 week embryo
 Paraxial = somites
 Intermediate
 Lateral plate
 Two layers separated by the Coelome
Intermediate mesoderm gives rise to ?Paired
Glands? (Kidneys, Adrenals and Gonads)
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Intermediate mesoderm
extends cranio caudally on
each side of primitive dorsal
aorta & project into dorsal
wall of coloemic cavity.
In cervical & upper thoraicsegmented-nephrotome
Rest of IMM is
unsegmented- nephrogenic
cord.
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Three slightly overlapping kidney systems are formed in a
cranial to caudal sequence during intrauterine life in humans:
the pronephros, mesonephros, and metanephros.
-Pronephros is rudimentary and nonfunctional;
-Mesonephros may function for a short time during the early
fetal period
-Metanephros forms the permanent kidney
Pronephros
Pronephros
 Appear during 4th week ,in cervical
&upper thoracic region as solid 7-10
segements,arranged horizontallypronephric tubule.
 Acquire lumen-nephrocele ,opens
medially into coelom,dorsal wall
evaginates & grows to join with
successive tubules ? pronephric duct
 These groups form vestigial excretory
units, that regress before more caudal
ones are formed.
 By the end of the fourth week,all
indications of the pronephric system
have disappeared except pronephric
duct.
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Mesonephros
Appearence is associated with regression of pronephric
system-4th week .
About 70-80 mesonephric tubules develop in lower
thoracic & lumbar region-horizontally,
Lateral end opens-mesonephric duct/Wolffian
duct,medial end forms dilated blind end indented to form
internal glomerus.
Proximal mesonephric tubules & duct disappear -5th
week.
At 8th week-26 tubules & single duct persist
Mesonephric ridge
Metanephros
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Appear last in lumbosacral region & persist as
permanent kidney
Consist : Collecting part- Ureteric bud
Excretory part- Metanephric blastema
Collecting part- Initially ureteric bud grows from
dorsomedial aspect of caudal part of mesonephric
duct.
Later-bud grows dorsally & headwards, its distal
end dilates & invade the caudal part mesonephric
tissue, while doing this so bud shifts to dorsolateral.
Dilated end of ureteric bud is surrouneded by
mesonephric tissue [cap]-metanephric blastema.
Bud divide cranial & caudal parts ? major calcyxsubdivides-13 generations.
Dichotoms branching- chondroitin sulphate
proteoglycan & glycosaminoglycan.
2,3,4th order generation ? minor calyx
5th onwards ? collecting tubules
Dilated end ? pelvis of ureter.
Stalk of bud ? ureter.
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Excretory part- develops from metanephric blastema,
Initally 1st order branch of bud? capped by metanephric blastema[solid mass of
bilaminar cells],further subdivisions- cells separate from main mass & from
clusters of cells on each side of tubule? later form hollow renal vesicle[nephron].
One end of vesicle abuts collecting tubules & other end is dilated and invaginated
by internal glomerular plexus.
Each vesicle is S-shape curve b/w two fixed ends, middle segment extends
towards future medulla as loop of Henle & associated part form PCT & DCT.
Finally partition b/w blind end disappear ? metanephric kidney start functioning.
Figure 14.6 Development of a metanephric excretory unit. Arrows, the place where the excretory unit
(blue) establishes an open communication with the collecting system (yellow), allowing flow of urine
from the glomerulus into the collecting ducts.
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MOLECULAR REGULATION OF KIDNEY
DEVELOPMENT
Epithelium of ureteric bud interacts with the mesenchyme of metanephric
blastema.
Mesenchyme of mesonephros-WT1-induction of ureteric bud
WT1-regulate the production of GDNF &HGF- help in growth, proliferation &
division of ureteric bud.
FGF-2 & BMP-7 ? growth factors block the apoptosis & stimulate the proliferation
in metanephric mesenchyme while maintaining the production of WT1.
WNT4 & Pax2- produced by ureteric bud cause mesenchyme to epithelialize for
excretory tubule differentation.
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Ascent of kidney
In the 6th week the kidneys begin to ascend from the sacral region to their position
in the upper abdomen.
 Initially kidney are present in :Pelvis /sacral? supplied by median sacral artery.
Iliac fossa ? supplied by common & internal iliac artery.
Finally undersurface of diaphragm where it ascent is arreseted by suprarenal gland &
supplied by inferior suprarenal artery ? later becomes renal artery
 As the kidney ascends it receives new segmental arteries from the aorta and loses
those vessels below (?climbing a ladder?). Thus sometimes there is more than one
renal artery.
Factors for ascent of kidney
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Diminutation of fetal curvatures.
Continous lengthing of ureteric bud.
Better nutrition.
Decreased pelvic cavity for
accommodation.
Increased abdominal cavity.
Sometimes one kidney fails to
ascend => pelvic kidney
Sometimes the left and right
kidneys become attached in the
pelvis then the horseshoe kidney
can?t ascend above the inferior
mesenteric artery(1:400)
Anamolies of kidney
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According to number - Agenesis of one kidney.
Multiple kidney.
According to position ? pelvic kidney
Fused kidney.
According to sizeLobulated kidney.
According to shape- Horseshoe kidney.
Disc kidney.
Polycystic kidney-failure of fusion of collecting & excretory part.
Histology of kidney
Types of nephron
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Cortex- renal corpuscle
proximal convolated tubule
distal convoluted tubule
collecting tubule
&papillary duct.
Medulla- loop of Henle with
ascending & desending loop.
Renal corpuscles - Glomerulus,Bowmans capsule
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Proximal convoluted tubule &
Distal convoluted tubule-active
transport of ion.
PCT- 75% of glomerular filtrate.
DCT- ADH ? absorption of water &
salt.
Collecting duct
Collecting duct ? cuboidal/tall coloumnar
cells,microvilli,cell outline clear,large lumen.
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Medulla-loop of Henle ? passive transport of ion.
Descending limb; thick- cont.. PCT
thin-low cuboidal cell.
 Loop of Henle- simple squamous epithelium.
 Ascending limb;thin-simple squamous epithelium
thick-cont..DCT.
Loop Of Henle - absorb 15% of water,
create hypotonic environment &
concentration of urine.
Maintain counter current mechanism.
Urine ? PCT-Hypotonic
Loop of Henle- Isotonic
DCT- Hypertonic
Juxtra glomerular apparatus ? vascular pole,4
cells,maintain blood pressure by secreting Renin
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Juxtra glomerular cells-large & round.
Macula densa cells-coloumnar & crowed.
Mesangial cells ? correspond pericyte.
Intersitial cells
Histology of kidney
Renal medulla
Renal medulla
Collecting ducts
Renal tubule
Glomerulus
 Urinary
pole
 Vascular
pole
Renal corpuscle
Renal corpuscle
Kidney (panoramic view)
Nephron
Introduction
Ascent of the
Kidneys
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In the 6th week the kidneys begin to ascend from the sacral region to their
position in the upper abdomen.
The metanephric ducts elongate and become the ureters.
As the kidney ascends it receives new segmental arteries from the aorta and
loses those vessels below (?climbing a ladder?). Thus sometimes there is
more than one renal artery.
Sometimes one kidney fails to ascend => pelvic kidney
Sometimes the left and right kidneys become attached in the pelvis then the
horseshoe kidney can?t ascend above the inferior mesenteric artery(1:400)
Ontogeny Recapitulates
Phylogeny Ernst Haeckel 1860?
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Ontogeny is the development of the individual
Phylogeny is the evolution of the species
So this is the idea that during development an
organism (or an organ) goes through the same
stages as during their evolution.
Consider the Frog
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It development retraces the evolution of vertebrates
from fish to reptiles
This idea should be
From the tadpole stage
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Water breathing with tail and no limbs (like a fish)
Rudimentary limbs
Reduction of tail
Development of lungs ? breathes air
Fully developed limbs, loss of tail moves onto land
To the fully developed frog
considered as a ?Parable?
It is not necessarily true
but it is a useful idea.
Pronephros
the first kidney
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A cavity, like the coelom
develops inside the
intermediate mesoderm
Balls of bloods vessels from
the aorta bulge into the space
? The Glomerulus.
The glomerulus allows excess
water to leave the blood while
salts and macromolecules are
retained.
This kind of kidney is found
in primitive fish (eg Lampreys)
and in the embryos of most
vertebrates
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Initially the water filters into the
coelom
Later, part of the cavity inside the
intermediate mesoderm links up with
similar parts in adjacent segments to
form a duct.
Pronephros ? in humans
 Appears
at Day 21
 In segmented
intermediate
mesoderm in the
cervical region
 It degenerates by
day 24
 It is never functional
in humans
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Mesonephros ? middle kidney
When some primitive fish returned
to the sea they had the reverse
osmotic problem, water tended to
diffuse out of their blood.
They developed the mesonephric
kidney located in the thoracic
region.
The mesonephros had a smaller
glomerulus but a larger system of
tubules so that the filtration part
Many bony fish and some amphibians
was reduced and the reabsorbing
have a mesonephric kidney.
part was increased.
This was an important preadaption The tubules all connect with the
to life on the land where drying out mesonephric (Wolfian) duct.
is a constant problem.
Mesonephros - in humans
 The
Mesonephros first appears
early in week 4
 In thoracic and lumbar
segments of intermediate
mesoderm.
 Urine is produced and drains
along the mesonephric
(Wolfian) duct to the
cloaca/bladder
 In week 5 the thoracic
segments regress but the
mesonephric kidney continues
functioning until week 10
Fate of the Mesonephric (Wolfian) ducts
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The development of the metanephric
kidney accompanied the changes in
the reproductive system.
The gonads of primitive vertebrates
release their eggs and sperm into the
coelom, from there they pass via small
pores into the cloaca.
In higher vertebrates the eggs are still
released into the coelom, but the
cloacal pores have become specialised
tubes which open adjacent to the
ovary.
In the embryo, this egg collecting tube
(paramesonephric duct) lies parallel to
the mesonephric duct.
Male and Female genital ducts
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Initially both sexes have both mesonephric and paramesonephric
ducts
In females
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Eggs are still released into the coelom (peritoneal cavity) but are gathered up in
the uterine tubes.
The two paramesonephric ducts become the uterine tubes.
Distally the paramesonephric ducts fuse together to form the uterus and vagina.
The mesonephric duct degenerates completely.
In higher vertebrates sperm is never released into the coelom but
reaches the outside by passing through some derivative of the urinary
system. In birds, reptiles and mammals the testis develops a
connection with the mesonephric duct (at the time that the mesonephros is degenerating).
In males
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The mesonephric duct becomes the ductus deferens, seminal vesicle and parts of
the prostate gland.
The paramesonephric duct degenerates completely.
Metanephros ? definitive kidney
 The
metanephros or definitive
kidney of higher vertebrates,
begins when the metanephric
ducts (ureteric buds) sprout
from the distal end of the
mesonephric duct at about 5
weeks.
 The ureteric buds induce
intermediate mesoderm in the
sacral region to form a
metanephric blastema which
forms the glomeruli and
tubules of the nephrons.
Evolution of the Kidneys: Metanephros
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The ureteric buds bifurcate again and again to
form the calyces and collecting duct system of the
definitive kidney.
The kidneys begin producing urine by week 12,
and it adds to the volume of the amniotic fluid.
The fetus drinks this fluid in utero.
The fetal kidneys are not responsible for
excretion as the placenta serves this function
Metanephros:
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The third urinary organ, the metanephros, or permanent
kidney, appears in the fifth week.
Its excretory units develop from metanephric mesoderm(Fig.
14.4) in the same manner as in the mesonephric system.
The development of the duct system differs from that of the other
kidney systems.
Collecting System. Collecting ducts of the permanent kidney
develop from the ureteric bud, an outgrowth of the
mesonephric duct close to its entrance to the cloaca (Fig.
14.4).
The bud penetrates the metanephric tissue, which is molded over
its distal end as a cap (Fig. 14.4). Subsequently the bud dilates,
forming the primitive renal pelvis, and splits into cranial and
caudal portions, the future major calyces (Fig. 14.5, A and B).
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Excretory System.
Each newly formed collecting tubule is covered at its distal end by a metanephric
tissue cap (Fig. 14.6A).
Under the inductive influence of the tubule, cells of the tissue cap form small vesicles,
the renal vesicles, which in turn give rise to small S-shaped tubules (Fig. 14.6, B and C ).
Capillaries grow into the pocket at one end of the S and differentiate into glomeruli.
These tubules, together with their glomeruli, form nephrons, or excretory units.
The proximal end of each nephron forms Bowman?s capsule, which is deeply indented
by a glomerulus (Fig. 14.6, C and D).
The distal end forms an open connection with one of the collecting tubules, establishing a
passageway from Bowman?s capsule to the collecting unit.
Continuous lengthening of the excretory tubule results in formation of the proximal
convoluted tubule, loop of Henle, and distal convoluted tubule (Fig. 14.6, E and F ).
Hence, the kidney develops from two sources: (a) metanephric mesoderm, which
provides excretory units; and (b) the ureteric bud, which gives rise to the collecting
system.
Nephrons are formed until birth, at which time there are approximately 1 million in each
kidney.
Urine production begins early in gestation, soon after differentiation of the glomerular
capillaries, which start to form by the10th week. At birth the kidneys have a lobulated
appearance, but the lobulation disappears during infancy as a result of further growth of
the nephrons,although there is no increase in their number.
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Position of kidneys
Kidneys lie on the psoas muscle beside
the vertebral bodies.
The diaphragm and 11th and 12th ribs lie
behind the upper half of each kidney.
Therefore they move with breathing
Left is higher than right (liver)
Upper poles T12
Hilum is at L1/2
Lower poles at L3
Upper poles are more medial (psoas).
In the hilum:
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Renal vein is the most anterior.
Followed by renal artery & pelvis/ureter
Note that the left renal vein is longer .
It crosses the aorta
Is crossed by the SMA
Receives left gonadal vein
Anterior relations
 Right
 Adrenal
 Liver
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bare area
Hepatorenal pouch
 Duodenum
 Pancreas
 Right
colic
flexure
 Jenunum
Left
Adrenal
Stomach
Spleen
Pancreas
Descending
Colon
Jenunum
Lecture summary
 Early
development and
evolution
 Pronephros
 Mesonephros
 Metanephros
 Ascent
and
abnormalities
 Position
and relations
 Lobes and segments
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Orientation and surroundings
The medial border of each kidney is anterior to the lateral border
(psoas). Thus the coronal plane of the kidney is at 30 degrees to
the coronal plane of the body.
Layers
surrounding the
kidney
Outside
the renal
capsule is perirenal fat
Then
is the renal fascia
which also surrounds the
adrenals
This
is embedded in
extraperitoneal fat
(pararenal fat)
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Renal Lobes and their papillae/calyces
There are 14 lobes originally
Each lobe corresponds with a renal pyramid
(plus its cap of cortex), and empties via its
papilla, into a minor calyx
Lobes fuse so that there are between 14 and 6,
usually 8 (26%)
Most fusion happens at the upper and lower
poles so that those papillae are compound.
Simple papillae have valve-like slits where the
ducts open ? Non-refluxing
Compound papillae allow reflux
Vescicouretal reflux occurs in children and if
the urine can enter the parenchyma of the
kidney it causes infection and damage
5 Segments of the Kidney
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Each segment is the area supplied one branch of the renal artery. (end arteries)
The front of the kidneys has four segments: apical, upper anterior, middle
anterior, lower
The back of the kidney has the posterior segment and the posterior aspects
of the apical and lower.
Easy way to remember: like your hand holding a glass four fingers in front
and the thumb behind.
The
posterior branch of the
artery branches off first and
passes over the renal pelvis to
reach the posterior aspect. The
four anterior branches continue in
the plane between the vein and
renal pelvis.