Urinary system
Aleš Hampl
November 2020
• 1. Regulating blood volume and pressure
• 2. Regulating plasma concentrations of sodium, potassium, chloride and
other ions
• 3. Stabilising blood pH
• 4. Conserving nutrients
• 5. Detoxifying poisons (with the liver)
Functions of urinary system
Components of urinary system
Kidneys
Paired
bean-shaped
retropertioneal
11 x 4-5 x 2-3 cm
Stroma
•Capsule
dense fibroelastic connective tissue
myofibroblast layer
•Interstitial stroma
loose fibroelastic connective tissue
Parenchyma
•Nephrons
•Collecting ducts
•Vascular components
Urethers
Urinary bladder
Urethra
Urinary tract
Dense fibroelastic
connective tissue
Myofibroblast
layer
Kidneys capsule
Overall organization of kidney
LateralMedial
Hilum – portal for renal vessels, nerves and urether
Renal sinus – cavity deep to hilum occupied by renal pelvis and vessels
Renal pelvis – expansion of ureter, extension to major and minor calyces
Renal parenchyma – medulla + cortex
Renal collumn
Extension of cortex
into medulla
•Cortex
•Medulla
Renal pyramid
10 to 18 per kidney
Lobe
Cortical arch
Lobullar structure of the kidney
Renal collumn
Extension of cortex
into medulla
•Cortex
•Medulla
Renal pyramid
10 to 18 per kidney
Pyramid
Renal
papila
Base
Area cribrosa
Minor calyx
DB-ducts of Bellini
Kidney medulla
Kidney cortex
Renal corpuscles
Cortical labyrinth
(convoluted tubules)
Cortical rays
(continuation of collecting
ducts from renal pyramids)
Uriniferous tubule = The functional unit of the kidney
Ducts of Bellini
Area cribrosa
Minor calyx
Cortex
Medulla
Nephron
Collectingduct
1 to 1.4 milllions
of nephrons
in one kidney
Nephrons X Collecting ducts
Different embryological origin
renal corpuscle
Nephron
Cortical nephrons
85% of nephrons
Juxtamedullary nephrons
15% of nephrons
About 40 mm long
Nephron
Nephron – Renal corpuscle 1
Glomerulus – tuft of capillaries
Bowman`s capsule - invaginated dilatation of proximal tubule
Masson stain
200-250mm
side of the corpuscle
where the PCT exits.
side of the corpuscle
where the afferent
arterioles and efferent
arterioles enter
and exit, respectively
Vascular
pole
Urinary
pole
Nephron – Renal corpuscle 2
Bowman’s space
Nephron – Glomerulus 1
Endothelial cell
Endothelial cell
Endothelial
cell pores
Foot processes
of podocyte
Foot processes
of podocyte
Mesangial cell
Capillary
Capillary
Capillary
Basal lamina
Endothelial cell + Basal lamina + Podocytes + Mesangial cells
Mesangial cells
- Contractile - receptors for angiotensin II
- Give structural support to the
glomerulus, synthesize ECM
- Endocytose and dispose of normal and
pathologic molecules trapped
by the glomerular basement membrane
- Produce chemical mediators such as
cytokines and prostaglandins
Lamina Rara – contain fibronectin (bind them to cells) – physical barrier
Lamina Densa – meshwork of Type IV collagen and laminin in a matrix
contg (-) charged heparan sulfate that restricts passage of cationic
molecules – charge barrier
Nephron – Glomerulus 2
Nephron – Glomerulus 3
Capillary lumen
Endothelial cell
Fenestra
Podocyte
Foot processes
of podocyte
Basal lamina
Fenestra: 70 – 90 nm
Lamina rara externa
Lamina densa
Lamina rara interna
Filtration slit with 6 nm
filtration diaphragm
Fenestrum
(about 80 nm)
20-40 nm
Nephron – Glomerulus – Podocyte 1
Nephron – Glomerulus – Podocyte 2
Fenestrum
Podocytes
Filtration slit with 6 nm
filtration diaphragm
Primary processes
X
Secondary processes
Nephron – Glomerulus – Podocyte 3
SEM of Podocyte covering
of glomerular capillaries
„Octopus-like cell“
Nephron – Glomerulus – Podocyte
Nephron – Tubular section 1
Proximal convoluted tubulus
Henle`s loop
•Thick descending limb
•Thin limb
•Thick ascending limb
Distal convoluted tubulus
Proximal convoluted tubulus + Thick descending limb of HL
= 14 mm in length
PCT
PCT
PCT
PCT
PCT
60 mm
PCT
Nephron – Tubular section 2
Reabsorption
¾ of sodium, Cl, K, H2O,
amino acids, proteins
Microvili = Brush border
Proximal convoluted tubuli
Thin descending limb of HL + Thin ascending limb of HL
= 9-10 mm in length
HL
HL
15-20 mm
HL
Nephron – Tubular section 3
Reabsorption
H2O
Thick ascending limb of HL + Distal convoluted tubulus
9-10 mm in length + 4-5 mm in length
DCT
DCT
30-40 mm
Nephron – Tubular section 4
Reabsorption
Na, K, Cl
Impermeable for water
Proximal and distal convoluted tubuli
P
P PD
D
Cortex
Proximal X Distal convoluted tubuli (7:1)
Nephron – Tubular section –
Juxtaglomerular apparatus 1
Macula densa
Monitors osmotic concentration
in the fluid in the nephron and
secretes local hormones that alter
JG cell secretion.
Juxtaglomerular cells
Monitor blood pressure in the afferent
arteriole and secrete renin. Renin
converts angiotensinogen in blood
plasma to angiotensin I which is
converted to angiotensin II in the
lungs. Angiotensin II causes
arteriole constriction throughout
the body, raising blood pressure.
Extraglomerular mesangial cells
(Lacis cells)
Macula densa
Modified DCT in proximity of vascular pole of renal corpuscle
Nephron – Tubular section –
Juxtaglomerular apparatus 2
Juxtaglomerular cells
Collecting ducts
Cortical + Medullary + Papillary = 20 mm in length
• Conserve body fluids
• Reacts to ADH (antidiuretic hormone) of the
posterior pituitary gland
• ADH increases the permeability of the collecting
tubules and distal tubules to water so more is
reabsorbed
• This decreases the total volume of urine
• Alcohol inhibits the release of ADH, so less water
is reabsorbed producing copious amounts of dilute
urine (can cause dehydration)
200 -300 mm
Collecting
Collecting
Proximal
Long section of Collecting and proximal tubuli
Blood circulation
Renal vein
Abdominal aorta
Renal artery
Vena cava inferior
Subdivision into 5 arteries
(segmented blood supply)
Segmental arteries
Renal artery
Arcuate artery
Arcuate vein
Cortical radiate artery
Cortical radiate vein
Blood circulation
Blood circulation – Afferent + Efferent arterioles
Blood circulation – Peritubular capilaries
Peritubular capilaries
arise from efferent
arterioles of cortical
nephrons
•low-pressure, porous capillaries
•absorb solutes
•their endothelia manufacture
erythropoietin (?)
Vasa recta
•arose from efferent arterioles of juxtamedullary
nephron
•thin walled looping vessels
•10-25 mm long
•part of the kidney’s urine-concentrating mechanism
Blood circulation – Vasa recta
VR
VR
VR
Excretory passages
•Calyces (minor + major)
•Pelvis
•Ureters
•Urinary bladder
•Urethra
General organizational pattern
(calyces, pelvis, urethers, bladder)
•Mucosa
Luminal sheet epithelium (transitional)
Basal lamina
Lamina propria/submucosa (connective tissue)
•Lamina muscularis (smooth muscle)
•Lamina adventitia or serosa
Renal calyces + pelvis
• Minimal lamina propria (submucosa)
• Thin tunica muscularis
• Tunica adventitia – blends with adipose
tissue in the renal sinus
Ureters
(25-30 cm long)
•Carry urine from renal pelvis to the
urinary bladder
•Same wall layers as pelvis
•Ureter wall thickens and the muscle
cells change from a helical to longitudinal
array near the bladder
•Urine moves by active peristaltic motion
Epithelium
(3-5 layers)
Circular m.
(outer)
Longitudinal m.
(inner)
Propria
(fibroelastic)
Adventitia
Lumen
3 – 5 mm
Urinary bladder
Thick muscularis - near the opening into the
urethra → they form an involuntary internal
sphincter.
Epithelium
Lamina
propria
Lamina
adventitia
Smooth
muscle
Epithelium
Basal membrane
Lamina
propria
longitudinal+circular+longitudinal
thin + thick + thin
Urinary bladder
Emptied
Distended with urine
External urinary sphincter
Female urethra
(4-5 cm in length)
Transitional epithelium
•Transitional + stratified squamous nonkeratinizing ep.
•Folded mucosa (due to fibroelastic propria)
•Two-layered muscularis
•Glands of Littre
Spongy - penile
Near the tip of penis – fossa navicularis
Stratified squamous epithelium (nonkeratinizing)
A) Tunica albuginea
C) Corpus spongiosum (erectile)
Arrows) Glands of Littre
Prostatic urethra - transitional ep., opennings of prostate gland
Membranous urethra – stratified collumnar ep., through the urogenital
diaphragm
Spongy (penile) urethra – stratified collumnar + squamous ep.
Male urethra
(15-20 cm in length)
Dialysis x Kidney transplant x Kidney regeneration ?
Thank you for your attention !
Questions and comments at:
ahampl@med.muni.cz