Digestive system
Microscopic anatomy of pancreas, liver,
overview of GIT embryology
LIVER (HEPAR)
• Liver parenchyma – biggest gland in
human body
• C.t. capsule
• Nutritive and functional blood supply
• Endocrine and exocrine function
• Uniform histology of all four major
anatomic lobules and segments:
- Hepatocytes and other cell
types
- C.t. stroma
- Blood and lymphatic vessels
- Sinusoids
- Innervation
- C.t. capsule
- Serosa
CAPSULA FIBROSA HEPATIS
− Serous mesothelium
− C.t. – collagen and elastic fibers
− 70-100m
− Porta hepatis
CAPSULA FIBROSA HEPATIS
Porta hepatis
VASCULARISATION
FUNCTION
• capillary stream of stomach and intestine
• vena portae
• interlobular veins
• circumlobular venules
NUTRITIVE
• aorta
• arteria hepatica
• segmental arteries
• interlobular arteries
• circumlobular arteriols
• hepatic sinusoids
• venae centrales hepatis
• venae sublobulares
• venae hepaticae
• vena cava inferior
70% 30% IVC
V. hepatica d. m. s.
Porta hepatis
VASKULARIZACE
Gartner, Hiatt: Color Textbook of Histology (2001)
MICROSCOPIC SEGMENTATION OF LIVER
MICROSCOPIC SEGMENTATION OF LIVER
• Three possible definitions
• Histological – lobulus venae centralis
• Metabolic – liver acinus
− metabolic zone 1 – 3
− oxygenation of hepatocytes
• Functional (physiological historical) unit
– lobulus venae interlobularis
(portal acinus)
wiki
Liver acinus
metabolic divergence dependent
on arterio-venous gradients
Zone I (periportal) Zone III (perivenous)
oxidative processes glycogen synthesis
beta-oxidation of fatty acids glycolysis
catabolism of aminoacids lipogenesis
gluconeogenesis ketogenesis
production of urea production of glutamine
synthesis of cholesterol synthesis of bile acids
glycogenolysis biotransformation
production of bile
CENTRAL VEIN LOBULUS
Lobulus venae centralis
− Classical morphological unit
− Polygonal cells (hexagonal), 0.7 x 2mm
− Central vein
− Radial cords of hepatocytes
− Liver sinusoids
− Portal triad, portobilliary region
CENTRAL VEIN LOBULUS
Lobulus venae centralis
Contact of 3-4 neighboring lobuli
• Interlobular artery (a. interlobularis)
• Interlobular vein (v. interlobularis)
• Interlobular bile duct (d. bilifer interlobularis)
• Lymphatic vessels
• Innervation – nervus vagus
Loose interstitial c.t.
CENTRAL VEIN LOBULUS
Portal triad
Ham: Textbook of Histology
PORTAL TRIAD
CENTRAL VEIN
• Hepatocytes arranged to cords, width 1-2
cells, often anastomoses
• Sinusoids
– 9-15m
– Anastomosing network of flat endothelial
cells
– Basal membrane absent - no diffusion
barrier
– Fenestrations - 100nm, diaphragm absent
– Intercellular space
– Perisinusoidal (Dissé) apace
– Reticular fibers, perisinusoidal fibroblasts
– Dispersed Kupfer cells (monocytemacrophage
system)
– Perisinusoidal cells of Ito
• Vena centralis – thin-walled vessel,
draining blood from sinusoids
HEPATOCYTES AND LIVER SINUSOIDS
• Space of Disse
– Connection of space of Disse and sinusoidal
lumen by fenestrated endothelium
– Hepatocytes in direct contact with plasma
(microvilli)
– Cells of Ito
LOBULUS VENAE CENTRALIS
Hepatocytes and liver sinusoids
INNER SURFACE OF LIVER SINUSOID – SEM
KUPFFER CELLS
• Liver macrophages
• Mononuclear phagocyte system
• Phagocytosis of particles, damaged
erythrocytes and pathogens
CELLS OF ITO
• Star-shape (stellate, perisinusoidal) cells
• Lipid droplets
• Deposition of vitamin A
• fine reticular c.t.
• Antigen presenting cells (lipid antigens)
HEPATOCYTES
• Polygonal cells of liver parenchyma
• 20x30m
• Irregular trabecules between sinusoids
• Usually one central nucleus. Bi- and multinuclear
cells common (20%)
• Nucleoli
• Lysosomes
• Glycogen
• Functional surfaces:
– Bile pole - secretory– membranes of
neighboring hepatocytes form bile capillary
– Blood pole - absorptive - sinusoidal –
microvilli oriented to space of Dissé
– Membranes with intercellular junctions
BILIARY AND BLOOD POLE OF HEPATOCYTE
ULTRASTRUCTURE OF HEPATOCYTES
Long mitochondria with flat or tubular cristae
Apparent RER, SER and Golgi
Glycogen, lipid droplets, lysosomes,
peroxisomes
Erythrocyte
Tight junction
Bile
capillary
Kupfer cells
Cells of Ito
Nucleus
Space of
Dissé
From plasma:
Glucose, aminoacids, bile acids
Blood proteins (serum albumin, fibrinogen, prothrombin, complement, transferrin, etc.)
Space of
Dissé
INTRAHEPATIC AND EXTRAHEPATIC BILE
DUCTS
Bile capillaries (billiary canaliculli)
- intercellular space between hepatocytes
- 1-2m
- no true wall, formed by membranes of hepatocytes
- intercellular junctions
Canals of Herring
- simple squamous epithelium
Interlobular bile ducts
- cholangiocytes
- cubic or low columnar epithelium + c.t.
Lobar bile ducts
- ductus hepaticus dexter et sinister
- high simple columnar epithelium
Ductus hepaticus, ductus cysticus, ductus
choledochus
- mucosa
- fibromuscular layer
INTRAHEPATIC
EXTRAHEPATIC
INTRAHEPATIC BILE DUCTS
http://alexandria.healthlibrary.ca/documents/notes/bom/unit_4/unit%204%202005/L-
39%202008%20%20histology%20of%20the%20pancreas.xml
INTRAHEPATIC BILE DUCTS
INTRAHEPATIC BILE DUCTS
TEM/SEM
Central vein
Circulobular
venule
Portal
arteriole
Interlobular
bile ducts
Cannal of
Herring
Bile capillary
HEPATOCYTESCHOLANGIOCYTES
Mucosa
- lateral folds
- simple columnar epithelium (cholangiocytes)
- mucinous glands in c.t., goblet cells
Fibromuscular layer
- dense network of collagen and elastic fibers
- leiomyocytes
EXTRAHEPATIC BILE DUCTS
d. hepaticus communis + d. cysticus  d. choledochus
papilla duodeni major
m. sphincter ampullae hepatoduodenalis (sphincter of Oddi)
Bile modification
GALL BLADDER (VESICA FELLEA)
- Wall 1-2mm
- Mucous coat
- Muscle layer
- Serosa/adventitia
Mucous coat
- mucosal folds
- 20-50m simple columnar epithelium with microvilli
- intercellular junctions
- lamina propria mucosae - loose collagen c.t. with mucinous
tuboalveolar glands
- lamina muscularis mucosae absent
Muscular layer (Muscularis propria)
- 3D network of smooth muscle cells,
- elastic fibers
Large layer of subserous c.t. (l. propria serosae)
GALL BLADDER (VESICA FELLEA)
GALL BLADDER (VESICA FELLEA)
mucosa
Muscularis propria
serosa
GALL BLADDER (VESICA FELLEA)
PANCREAS
• Compound, serous, tuboalveolar gland
• Exocrine and endocrine character
– pancreatic acinus
– Islets of Langerhans
• Major duct (Wirsungi) opens to Vater papilla
as a common bile and pancreatic duct
• Dense collagen c.t. capsule
• Septs – blood cells, innervation, and
interlobular ducts
PANCREATIC ACINUS
• Pyramidal epithelial cells
• Pancreatic digestive enzymes
• intercalated ducts
• Serous acinar cells
– Polarized secretory cells
– Basophilic
– Apex – Golgi and zymogenic granules
– Microvilli
– Intercellular junctions
• Centroacinar cells
– Centrally located nucleus, squamous
character
– Continuous with intercalated ducts
PANCREATIC ACINUS
PANCREATIC ACINUS
• Centroacinar cells
• Intercalated ducts
– simple squamous epithelium + basal membrane
• Intralobular and interlobular ducts
– simple cubic – low columnar epithelium
• Major pancreatic ducts
– D. pancreaticus major – Wirsungi and D. pancreaticus accessorius - Santorini
– bilayered columnar epithelium and dense collagen c.t.
– intramural mucinous tubular glands, goblet cells, EC cells
PANCREATIC DUCTS
EXOCRINE FUNCTION OF PANCREAS
• ca 1000-2000 ml daily
• alkalic pH (8.8), HCO3
- (intercalated duct epithelium)
• mucin (epithelium of large ducts)
• Hydrolases
– Trypsinogen
– Chymotrypsinogen
– Proelastases
– Carboxypeptidases
– Pancreatic lipase
– Amylases
– …
Hormonal regulation (secretin, cholecystokinin) + parasympatikus
ENDOCRINE FUNCTION OF PANCREAS
Glucagon
 Glycogen consumption in tissues and
muscles
 Increase of blood glucose
Insulin
 Increase of membrane
permeability for glucose
 Glucose oxidation in tissues
 Decrease of blood glucose
 Synthesis of glucan in muscles
and liver
Somatostatin
 Inhibition of GIT hormones
Pancreatic polypeptide
 Autoregulation of pancreatic
secretion
ISLETS OF LANGERHANS
• Clusters of pale cells
• ca 1,5  106
• Thin c.t. capsule
• Cords of epithelial cells
• Sinusoids
• General characteristics of APUD cells
• A, B, D, PP cells
A cells: 20%, glucagon
B cells: 60-70%, insulin
D cells: minor, somatostatin
PP cells: minor, pancreatic polypeptide
ISLETS OF LANGERHANS
DEVELOPMENT OF GIT
EMBRYONIC DEVELOPMENT 2TH TO 3RD WEEK
EMBRYONIC DEVELOPMENT 3RD TO 4TH WEEK
4TH AND 5TH WEEK OF EMBRYONIC DEVELOPMENT
DEVELOPMENT OF PRIMITIVE GUT
– cephalocaudal and lateral folding in 4th
week
– primitive gut from buccopharyngeal
membrane to cloacal membrane
Three regions of primitive gut
• foregut
• midgut
• hindgut
- region of foregut caudal of respiratory diverticulum
- tracheoesophageal septum
- rapid elongation: 7th week - final relative length
- rapid proliferation of endoderm (epithelium and glands) that obliterates lumen –
recanalization about 8th week
- connective tissue and muscle tissue – mesenchyme of caudal pharyngeal arches and
splanchnic mesenchyme
- innervation by branches of n. vagus (caudal pharyngeal arches)
DEVELOPMENT OF ESOPHAGUS
8th week
ABNORMALITIES IN DEVELOPMENT OF ESOPHAGUS
Autor
Peter Anderson
DEVELOPMENT OF STOMACH
- fusiform dilatation of the foregut
- different growth rates in various regions  greater and lesser curvature
- rotation 90°C clockwise around longitudinal and anteroposterior axis
- definitive location and shape - 2nd month i.u.
8th week
STOMACH ROTATION
• 90°
ventral lesser curvature  right
dorsal greater curvature  left
left side  ventrally
right side  dorsally
cranial part  left caudally
caudal part  right cranially
 definitive anatomical position of
left and right nervus vagus
WEEK cca 4th 5th
EMBRYO SIZE 3 mm 5 mm
DEVELOPMENT OF INTESTINE
- midgut – primary intestinal loop
- rotation during development
- physiological umbilical herniation
8th week
WEEK: late 8th
EMBRYO SIZE 35 mm
INTESTINAL ROTATION
INTESTINAL ROTATION AND ROTATION OF
MESENTERIES
INTESTINAL ROTATION AND UMBILICAL HERNIA
• 8th week
• Normal reposition in 10th week
Abnormalities:
• Inomplete closure of umbilicus
• Including omentum majus and small intestine, skin and connective tissue
• Develops after birth, spontaneous reposition possible (X gastroschisis)
ABNORMAL INTESTINAL ROTATION
ILEUM DEVELOPMENT AND ABNORMALITIES
VOLVULUS
• malrotation of midgut and left colon (obstruction of a. mesenterica sup. and
duodenum)
• reversed rotation (obstruction of colon)
• abnormal ahesion of caecum to liver (subhepatic caecu) - abnormal position of
appendix
• caecum mobile
ANUS DEVELOPMENT AND ITS ABNORMALITIES
ANUS DEVELOPMENT AND ITS ABNORMALITIES
DIVERTICULUM MECKELI
• often phenomenon
(2-4%)
• clinicaly relevant
• vitelline cysts
volvulus of diverticle
EMBRYONIC DEVELOPMENT OF LIVER
• Diverticulum of embryonic duodenum - liver
diverticulum
• Pars hepatica (parenchyma + ductus hepaticus)
and pars cystica (ductus cysticus + gall bladder)
form d. choledochus
• Rapidly proliferating cells penetrate septum
transversum (mesodermal plate between
pericardial cavity and yolk sac) and growth into
ventral mesentery
• liver cords – parenchyma
• Interactions between cells of liver cords and vv.
omphalomesentericae induce development liver
sinusoids
• C.t. , Kupffer and hematopoietic cells – from
mesoderm of septum transversum
• Surface mesoderm differentiate into visceral
peritoneum
•10th week
- 10% of body volume
- hematopoiesis
• 12th week
- bile production
• 6th week of development
• two endodermal diverticles
• dorsal and ventral duodenal diverticle
(= pancreas dorsale et ventrale)
• after rotation of duodenal loop both
diverticula fuse
• ducts persist (ventral - major and
dorsal - accessorius)
• ductal system develops first, secretory
acini follow
• cells that are not part of ductal
structures differentiate into Islets of
Langerhans
• since 4th month in utero - secretory
activity
EMBRYONIC DEVELOPMENT OF PANCREAS
EMBRYONIC DEVELOPMENT OF PANCREAS
- Microscopic anatomy of liver: endocrine and exocrine function of liver,
vascularization, liver lobulus and its definition, liver cells, ultrastructure and
function of hepatocytes, organization of intra- and extra-hepatic passages
- Microscopic anatomy of pancreas: endocrine and exocrine function,
pancreatic acinus and its ducts, ultrastructure and function of acinar cells,
Islets of Langerhans and their structure, cell types of Islet of Langerhans
and their function
- Embryonic development and morphogenesis of digestive tube, liver and
pancreas, primitive gut and its derivatives, esophagus, stomach, intestine.
Flexion of embryo and rotation, liver and pancreatic diverticulum,
differentiation of individual cell types.
Summary of GIT II
Thank you for attention
Petr Vaňhara, PhD
Ústav histologie a embryologie LF MU
pvanhara@med.muni.cz
http://www.med.muni.cz/histology