Intestines Microanatomy Notes 2024-25 PDF

Summary

These notes provide a detailed microanatomy study on the intestines and anal canal. It covers the small intestine, large intestine, and anal canal with regards to their functions and structures. Learning objectives and descriptions of features are provided, supplemented with diagrams and figures.

Full Transcript

Microanatomy of the Intestines and Anal Canal
Rod D. Braun Page 1 of 33

MICROANATOMY OF THE INTESTINES AND ANAL CANAL

Learning Objectives:
1. Describe the microanatomy and function of the small intestine.
Compare and contrast the role of the stomach and the intestine in digestion.
Describe the mechanisms used by the intestine to increase surface area for digestion and absorption.
Diagram the structure of an intestinal villus, including its blood vascular and lymph vascular
patterns.
Compare and contrast villi and microvilli.
Describe the glands of the submucosa, their location along the small intestine and their function.
Describe the cell types in intestinal epithelium and be able to identify them in LM and TEM.
Describe the functional organization of the enterocyte, including the specializations of its apical
surface, junctional complex, and role of its basolateral domain.
Describe the role of the enterocyte in the digestion/intake of proteins, lipids, sugars, gastric
intrinsic factor, minerals, and water.
Describe the role of the enterocyte in the secretion of secretory IgA.
Describe the function of the secretions released by enteroendocrine cells in the intestines.
Describe the cell content of the mucosal glands (crypts of Lieberkühn) and the functions of the cells.
Describe the elements of the immune system found in the lamina propria and the epithelium as well as
their function.
Distinguish between duodenum and jejunum or ileum at LM level (H&E).
2. Describe the microanatomy and function of the large intestine and appendix.
Compare and contrast the mucosa of the colon and small intestine and distinguish at LM level (H&E).
Compare and contrast the muscularis externa of the colon and small intestine.
Compare and contrast the histological organization of the appendix to that of the colon and small
intestine.
3. Describe the microanatomy and function of the anal canal.
Describe the changes in the histological organization of the alimentary canal wall from the upper
through the lower anal canal.
Microanatomy of the Intestines and Anal Canal
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Lecture Content Outline
I. Small intestine
A. Features
B. Layers of wall
C. Cell types in epithelium
D. Cell types in intestinal glands (crypts of Lieberkühn)
E. Gut-associated lymphatic tissue (GALT)
F. Distinctive characteristics of small intestine
II. Large intestine
A. Features
B. Colon
C. Appendix
D. Rectum
III. Anal canal
A. Mucosa
B. Submucosa
C. Muscularis externa
D. Fibrosa (adventitia)
IV. Review of alimentary canal (digestive tract) wall
A. Stomach
B. Small intestines
C. Large intestines
Microanatomy of the Intestines and Anal Canal
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I. SMALL INTESTINE
A. FEATURES
1. Plays major role in both chemical digestion of food and absorption
of products of digestion (see Digestion and Absorption lecture).

2. Divisions
a. Duodenum: shortest segment, ~25 cm long

b. Jejunum: ~2.5 m long

c. Ileum: ~3.5 m long

Figure 1. Diagram illustrating the layers of the intestinal wall for different portions of the small and large intestines.
Modified from Human Histology: A Microfiche Atlas, Erlandsen & Magney (1985).
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3. Like the rest of the digestive tract (alimentary canal), its wall has
four layers (Figure 1): mucosa, submucosa, muscularis externa,
and serosa/adventitia (detailed in Section IB).

Figure 2.. Layers of the wall of the small intestine (jejunum here). Note large submucosal folds (plicae circulares, one labeled
PC) and finger-like mucosal projections, the villi (V). Muc: mucosa; SubM: submucosa; ME: muscularis externa; L: central lacteal
th
(lymphatic vessel). Serosa would be at bottom of section. Plate 60 from Ross & Pawlina, 6 ed. (2011).

4. The mucosa of the small intestine has special features that serve to
increase the surface area available for digestion and absorption
(Figure 1). Surface area is increased by:
a. Plicae circulares (valves of Kerckring)
i. Permanent submucosal folds (Figure 2).

ii. Remember: Since the submucosa folds, the
overlying mucosa also folds and increases the
epithelial surface area.

b. Villi
i. Finger-like mucosal folds that project into the
lumen (Figures 2 and 3).
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ii. These greatly increase
epithelial surface area
(Figure 3).

iii. Do not confuse these
with microvilli, which
are cytoplasmic
projections of
individual cells (see
Figure 3. SEM of cross-section through small
Section IC). intestine. Lu: lumen, Mu: mucosa, Su: submucosa,
Mu: muscularis externa, Vi: villi. From Tissues and
Organs, Kessel and Kardon (1979).

iv. Characteristic of small intestine only!

B. LAYERS OF WALL (Figures 1 and 2)
1. Mucosa (Figures 2 and 4)
a. Villi: As noted already,
the mucosa is
characterized by the
presence of villi (Figures
3 and 4).
i. Villi are covered
by a simple
columnar
epithelium
containing
primarily
enterocytes
(absorptive cells),
as well as other
Figure 4. Diagram of mucosa of small intestine. Note
simple columnar epithelium, underlying lamina propria,
cell types (see and muscularis mucosae. Modified from Figure 17.18b
th
from Ross & Pawlina, 6 ed. (2011).
Section IC).
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ii. Underlying the
epithelium of the
villi is a core of
loose connective
tissue, continuous
with the rest of
the lamina
propria (Figures
4 and 5).

b. Intestinal glands (crypts
of Lieberkühn)
i. Mucosal glands
of the intestine
are called Figure 5. LM of mucosa, including villi in small intestine
(ileum) and crypts of Lieberkühn (intestinal glands).
Muscularis mucosae at bottom. From Meyer (1970).
intestinal glands
or crypts of Lieberkühn.

ii. Simple tubular glands that open at the base
of the villi and empty into the lumen
between adjacent villi.

iii. Glands extend through the lamina propria to
the muscularis mucosae (Figures 4 and 5).

c. Lamina propria
i. Delicate connective tissue that forms the core of the
villus and surrounds the glands (Figure 5).

ii. Contains blood and lymphatic vessels (Figure 4).
Microanatomy of the Intestines and Anal Canal
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iii. Network of
fenestrated
capillaries
runs just
under the
epithelium
(Figures 4
Figure 6. Lamina propria within villus of small intestine. Note
and 6). presence of many plasma cells and a capillary just under
epithelium at lower left. From Human Histology: A Microfiche
Atlas, Erlandsen & Magney (1985).

iv. Central lacteal (lymphatic vessel): blind-ending
vessel that begins near tip of villus, runs through the
central core of the villus, and drains to a plexus in
the lamina propria and submucosa (Figures 2 and
4).

v. Lymphatic infiltration is common - may be
diffuse (Figures 5 and 6) or nodular. This is
part of the gut-associated lymphatic tissue
(GALT), which is found throughout the
entire gastrointestinal tract (see Section IE).

d. Muscularis mucosae: thin layers of smooth muscle,
deep to glands (Figure 5).

2. Submucosa (Figure 2)
a. Coarse collagenous connective tissue (dense
irregular).

b. Ganglion cells of submucosal (Meissner’s) plexus
are present.
Microanatomy of the Intestines and Anal Canal
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c. Submucosal glands
are present in
duodenum ONLY
(Figures 1 and 7).
i. Glands are
called
Brunner's
glands.
Figure 7. Longitudinal section through wall of duodenum,
showing presence of Brunner’s glands (BGl) in submucosa
(SubM) and duct (D) connecting gland to lumen. Muc: mucosa,
ii. They are ME: muscularis externa with inner circular (C) and outer
longitudinal (L) layers, V: villi, MM: muscularis mucosae, S:
th
compound serosa. Plate 59 from Ross & Pawlina, 6 ed. (2011).

branched tubular glands that produce an
alkaline mucus, which buffers the acidic
chyme entering from the pyloric stomach
and raises its pH.

iii. The ducts of Brunner’s glands empty into
the crypts of Lieberkühn.

3. Muscularis externa (Figure 7, see also Figure 2)
a. Two layers of smooth muscle: inner circular and
outer longitudinal

b. Ganglion cells of the myenteric plexus lie between
the smooth muscle cell layers.

c. Contraction of the inner circular layer of smooth
muscle leads to constriction of a ring of smooth
muscle and a decrease in diameter of that segment
of the small intestine.
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Figure 8. Cells in villus epithelium and glands (crypts of Lieberkühn) of small intestine. Modified from Human
Histology: A Microfiche Atlas, Erlandsen & Magney (1985).

d. Contraction of the outer longitudinal layer leads to a
decrease in length as well as an increase in diameter
of that segment of the small intestine.

4. Serosa or adventitia
a. Outermost layer is a serosa when the portion of the
small intestine is intraperitoneal: initial portion of
duodenum, jejunum, and ileum (Figure 7).

b. Outermost layer is an adventitia when the portion
of small intestine is retroperitoneal: rest of
duodenum.
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C. CELL TYPES IN EPITHELIUM (Figure 8)
1. Enterocytes
a. Columnar absorptive cells

b. Primary cell type covering villi

c. Replaced every 5-6 days by
undifferentiated cells in the
base of the crypt of
Lieberkühn (Figure 8).

d. Tall, regular microvilli at Figure 9. LM of epithelium of two neighboring villi. Note
pale-staining goblet cells and striated border of microvilli
apical surface of cells on enterocytes. From Human Histology: A Microfiche
Atlas, Erlandsen & Magney (1985).
greatly increase plasma
membrane surface area for
absorption.
i. In LM sections, they are
visible as the striated
border (Figure 9).

ii. In TEM sections, they
can be clearly identified
as microvilli (Figure
10).

iii. Actin microfilaments Figure 10. TEM of epithelium in villus. Note
enterocytes with microvilli on apical surface. Goblet
within the microvilli are cell is at upper right. Lamina propria is at bottom of
image. Same orientation as Figure 9.
bundled by fimbrin and villin and are linked
to the plasma membrane by myosin I and
calmodulin (see the Microanatomy of
Epithelium and Glands lecture).
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iv. Microfilaments interact with other actin and
intermediate filaments (cytokeratins) in the
terminal web and are anchored into the
junctional complex.

v. Microvilli are
covered with a
glycocalyx surface
coat that contains
different digestive
Figure 11. TEM of apical surfaces of 3 enterocytes.
Note microvilli and associated glycocalyx on apical
enzymes (Figure surfaces, as well as junctional complex between two
cells on left. From Human Histology: A Microfiche Atlas,
11). Erlandsen & Magney (1985).

d. Junctional complexes form a tight seal near
the apical margin (Figures 10 and 11).

e. Functions of enterocytes (Figure 12):
i. Uptake of ions via ion channels.

ii. Digestion and uptake of carbohydrates:
α. Plasma membrane of microvilli is
covered with a glycocalyx surface
coat, which includes enzymes, such
as oligosaccharidases and
disaccharidases, e.g., lactase and
sucrase, for terminal digestion of
carbohydrates to monosaccharides
(Figures 12 and 13).
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Figure 12. Some of the functions of enterocytes in the small intestine. MVB: microvillus border; FFA: free fatty acid; MG:
monoglyceride; 12C-FA: 12-chain fatty acid; AA: amino acid; IF: gastric intrinsic factor. Figure F11-B6 from Human
Histology: A Microfiche Atlas, Erlandsen & Magney (1985).

β. Monosaccharides
are then absorbed
by active transport
and move to the
basal membrane.
There they are
exported by other Figure 13. TEM of immunolocalization of sucrase
(black dots) in glycocalyx of enterocyte in villus.
From Human Histology: A Microfiche Atlas,
transporters into Erlandsen & Magney (1985).

the lamina propria of the villus, where they
are picked up by fenestrated capillaries.

γ. Details of carbohydrate digestion
will be provided in the Digestion
and Absorption lecture.
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iii. Uptake of peptides and amino acids:
α. Present in the glycocalyx of the
apical (microvilli) membrane is the
enzyme enterokinase, which
activates trypsinogen (from
pancreas) in the lumen of the
duodenum to form trypsin.

β. Trypsin, in turn, activates other
pancreatic proenzymes.

γ. The activated pancreatic enzymes
and peptidases within the glycocalyx
(brush-border peptidases) cleave
proteins to amino acids or very small
peptides.

δ. Most of the small peptides are
hydrolyzed to amino acids by
cytosolic peptidases, producing
amino acids that exit the enterocyte
by facilitated diffusion.

ε. In the lamina propria, the amino
acids are picked up by fenestrated
capillaries (Figure 12).

ζ. Details of protein digestion will be
provided in the Digestion and
Absorption lecture.
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iv. Digestion and uptake of lipids:
α. In the intestinal lumen, lipids are
broken down by pancreatic lipase
and other pancreatic enzymes in the
presence of bile salts to free fatty
acids, monoglycerides, and other
small lipids, which are solubilized in
micelles. The micelles are
transported to the apical membrane
of the enterocytes, where the lipids
diffuse into the cells.

β. Smooth ER resynthesizes
triglycerides (Figure 14) and
transfers them to Golgi complexes
for further processing and
incorporation into vesicles with
protein components (apoproteins).
These vesicles are called
chylomicrons (Figure 15).

Figure 14.
TEM of apical
portion of
enterocyte,
with microvilli
at top. Lipids
are stained
with osmium
(black). Note
SER filled with Figure 15.
newly TEM of
synthesized portion of
triglycerides enterocyte,
(black circles). showing
formation of
chylomicrons
in Golgi (G).
LD: lipid
droplet.
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γ. The vesicles (chylomicrons) migrate
to the lateral margin, where they are
released by exocytosis into the
intercellular space (Figure 16).

Figure 17. LM of lacteals within villi of rat small intestine after
a meal rich in fat. From Human Histology: A Microfiche Atlas,
Erlandsen & Magney (1985).
Figure 16. TEM of lateral margin between two
enterocytes, showing electron-dense chylomicrons.

δ. The chylomicrons then move toward
lymphatic vessels (lacteals) in the
center of the villus (Figures 2 and
17).

ε. Details of lipid digestion will be
provided in the Digestion and
Absorption lecture.

v. Uptake of vitamin B12:
α. Gastric intrinsic factor (IF) is
produced by parietal cells in gastric
glands in fundic stomach (see the
Microanatomy of the Esophagus
and Stomach lecture).
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β. IF forms a complex with B12 in the
intestinal lumen, and this complex
can be taken up by enterocytes in the
ileum, since they have IF receptors
(Figure 12).

γ. In the enterocyte, vitamin B12 is
liberated and transported across the
basal membrane into a fenestrated
capillary in the lamina propria of the
villus (Figure 12).

δ. Vitamin B12 is necessary for RBC
production.

ε. Details of vitamin B12 uptake will be
provided in the Digestion and
Absorption lecture.

vi. Recycling of unconjugated bile salts, which
are returned to liver hepatocytes (see the
Microanatomy of the Liver, Gallbladder,
and Pancreas lecture).

vii. Absorption of water:
α. Na+-K+ ATPase in the lateral plasma
membranes moves Na+ ions into the
intercellular spaces and water
follows.
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β. During active absorption, lateral
plications separate, enlarging the
space.

γ. Together, the small and large
intestines absorb approximately 8.5
liters of fluid daily.

δ. Most is absorbed by the epithelial
cells of the small intestine (~6.5L).
The rest is absorbed by the colon.

Figure 18. Production and release of secretory IgA (sIgA) in the small intestine. From Human Histology: A
Microfiche Atlas, Erlandsen & Magney (1985).

viii. Release of secretory IgA at the luminal surface
(Figure 18):
α. IgA is synthesized by plasma cells in the
lamina propria (Figure 6) as a dimer.
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β. IgA is taken up by receptor-mediated
endocytosis at the basal surface of
enterocytes.

γ. IgA-receptor complex is transported up
through the cell, and is then released at the
apical margin with the stabilizing portion of
the receptor still attached.

δ. This complex, called secretory IgA (sIgA),
is less easily degraded within the intestinal
lumen.

2. Goblet cells (Figures 9, 10, and
19)
a. Unicellular exocrine
glands.

b. Apical cytoplasm packed
with granules of the
glycoprotein mucinogen
(Figure 19), which is Figure 19. TEM of goblet cell among enterocytes.
From Human Histology: A Microfiche Atlas,
released to form a coat of Erlandsen & Magney (1985).

mucus.

3. Enteroendocrine cells (Figure 20)
a. Contain basal granules that are released into the underlying
lamina propria (Figure 20).

b. Make up 1% of cell population.
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c. As noted in the Microanatomy
of the Esophagus and Stomach
lecture, there are more than a
dozen types of enteroendocrine
cells throughout the digestive
tract. Some are listed in that
lecture, and the functions of
many of them will be discussed
in the Regulation of the
Alimentary Canal and
Microanatomy of the Liver,
Gallbladder, and Pancreas
Figure 20. TEM of enteroendocrine cells.
lectures. Note polarization of secretory granules near
basal surface. From Human Histology: A
Microfiche Atlas, Erlandsen & Magney (1985).

D. CELL TYPES IN INTESTINAL GLANDS (CRYPTS OF
LIEBERKÜHN) (Figure 8)
1. Immature enterocytes

2. Goblet cells (see above)

3. Enteroendocrine cells

4. Paneth cells
a. Located in the base of
the crypts of Lieberkühn
(Figures 8 and 21).

b. Contain prominent
acidophilic granules Figure 21. LM of Paneth cells in base of crypts of Lieberkühn.
Note large distinct eosinophilic (acidophilic) granules in
(Figure 21). Paneth cells. From Human Histology: A Microfiche Atlas,
Erlandsen & Magney (1985).
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c. Products of Paneth cells
i. Lysozyme: degrades bacterial surface coats.

ii. Defensins: increase membrane permeability of
parasites and bacteria.

5. Undifferentiated stem cells
a. Precursors of other
cells in the epithelium
and glands.

b. Like Paneth cells, the
undifferentiated stem Figure 22. PAS-hematoxylin-stained LM of crypts of
Lieberkühn in mouse after injection of tritiated thymidine
cells are located in the (black dots), which was incorporated by dividing,
undifferentiated cells. From Human Histology: A Microfiche
base of the crypts of Atlas, Erlandsen & Magney (1985).

Lieberkühn (Figures 22).

c. Cells undergo mitosis within the glands (Figure 22), then
migrate toward an extrusion zone at tips of villi (Figure 8).

d. Replace epithelium every 5-6 days. Paneth and
enteroendocrine cells are replaced more slowly.

E. GUT-ASSOCIATED LYMPHATIC
TISSUE (GALT)
1. Lymphatic infiltration is
common in small intestine and
may be diffuse or nodular
(Figure 23). Lymphatic tissue
will be discussed in the
Figure 23. LM of lymphatic nodules in ileum, part of gut-
Microanatomy of the associated lymphatic tissue (GALT). From Meyer (1970).
Microanatomy of the Intestines and Anal Canal
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Lymphatic System lecture later in the curriculum.
a. Diffuse lymphatic tissue: Loose collection of T and
B lymphocytes, plasma cells, and antigen
presenting cells (APCs).

b. Nodular lymphatic tissue: Localized concentrations
of B lymphocytes organized in lymphatic nodules.

2. This is part of the gut-associated lymphatic tissue (GALT),
which is found throughout the entire GI tract.

3. Lymphoid elements in connective tissue of lamina propria
and/or submucosa (Figure 23).
a. Lymphatic nodules with B
cells

b. Diffuse lymphatic tissue

4. Nodular (follicular) GALT is
covered by a specialized
epithelium (Figure 24) that
includes:
a. M (microfold) cells
i. Flattened cells
with short apical
folds of the plasma
membrane.
Figure 24. Top: LM of specialized epithelium overlying
the dome of a Peyer’s patch. From Human Histology:
A Microfiche Atlas, Erlandsen & Magney (1985).
Bottom: Schematic of specialized epitheium showing
ii. Take up antigens function of M cells. From “Vivo Pathophysiology”
(http://www.vivo.colostate.edu/hbooks/pathphys/digesti
and transport them on/smallgut/mcells.html).

to underlying lymphocytes.
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b. Dendritic cells: sample and transport antigen from the
lumen.

c. Enterocytes: assist by degrading antigens

5. Nodular form of GALT is most prominent in the ileum, where it can be
seen macroscopically as Peyer’s patches.

F. DISTINCTIVE CHARACTERISTICS
OF SMALL INTESTINE
1. Characterized by the presence of
villi, not found elsewhere.

2. Portions of small intestine
a. Duodenum: identified by
the presence of Brunner's
glands in the submucosa
(Figures 25 and 26).

b. Jejunum: no submucosal
glands Figure 25. LM of wall of duodenum. Note
Brunner’s gland in submucosa. From Meyer (1970).

c. Ileum
i. No submucosal glands (Figure 27).

ii. Tends to show an increase in the number of
goblet cells and the amount of lymphatic
infiltration, but, for the purposes of this
course, not distinguishable from jejunum.

iii. Site of Peyer's patches.
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Figure 26. Low mag LM of wall of duodenum. Note Brunner’s glands Figure 27. Low mag LM of wall of ileum. Note absence of
in submucosa. They empty into intestinal crypts. From Meyer (1970). Brunner’s glands in submucosa. From Meyer (1970).

II. LARGE INTESTINE
A. FEATURES
1. Plays major role in reabsorption of electrolytes and water and
elimination of undigested food (feces).

2. Divisions
a. Cecum, with projecting vermiform appendix

b. Colon (ascending, transverse,
descending, and
sigmoid)

c. Rectum

d. Anal canal

B. COLON
Unlike the small intestine, the colon
has no villi, only crypts of Lieberkühn
Figure 28. SEM of cross-section through large
(Figure 1). It looks like a flat surface intestine (colon). Lu: lumen, ML: muscularis externa,
TG: crypts of Lieberkühn. From Tissues and Organs,
with test tubes stuck into it (Figure 28). Kessel and Kardon (1979).
Microanatomy of the Intestines and Anal Canal
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The wall of the colon (cecum is similar) consists of the following
layers (Figures 29 and 30):
1. Mucosa (Figure 31)
a. Mucosa has a smooth surface (no villi)

Figure 29. Diagram of the wall of the colon. Note taenia coli. Modified from Figure 15-16 in Atlas of Histology
st
(Cui, 1 ed., 2011).

Figure 30. LM of wall of colon, with lumen at top. Note the
taenia coli at bottom center and the absence of villi in the Figure 31. LM of mucosa in colon. Note absence of villi
mucosa (top). From Meyer (1970). and straight crypts of Lieberkühn. From Meyer (1970).

b. Epithelium is simple columnar with following cell
types (Figure 31):
i. Enterocytes with the primary role of
reabsorption of electrolytes and water. Water
is absorbed through action of the Na+-K+
ATPase transport system (see Section I.C.1.e).

ii. Goblet cells: produce mucus
Microanatomy of the Intestines and Anal Canal
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c. Simple tubular glands (crypts of Lieberkühn, Figure
31) containing:
i. Immature enterocytes

ii. Goblet cells, which increase in number as
the rectum is approached

iii. Enteroendocrine cells
iv. Undifferentiated stem cells: surface renewal
every 5-6 days

v. Note: Paneth cells are lost from the glands
at the beginning of the cecum.

d. Lamina propria with GALT

e. Muscularis mucosae

2. Submucosa: no glands, but lymphatic tissue is usually
present (Figure 30).

3. Muscularis externa (Figure 30)
a. Continuous inner circular layer of smooth muscle

b. Outer longitudinal layer of smooth muscle is
organized into 3 distinct and separate bands, the
taeniae coli (Figures 29 and 30).

4. Serosa or adventitia (fibrosa): depends on location.
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C. APPENDIX
1. Similar to colon, except for a
smaller diameter, and the presence
of a continuous outer longitudinal
layer of smooth muscle. i.e., there
are no taenia coli (Figure 32).

2. Usually has more extensive
lymphatic infiltration, especially
more lymphatic nodules, than the
colon.
Figure 32. Transverse section of appendix. Note
numerous large lymphatic nodules. Figure 17.30
th
from Ross & Pawlina, 6 ed. (2011).
3. The appendix is covered by a
serosa.

D. RECTUM
1. Similar to the colon, but it has no taenia coli.

2. Surface epithelium is predominantly goblet cells.

3. Crypts of Lieberkühn lined predominantly by goblet cells

Continued on next page.
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Figure 33. LM of anal canal. Mucosa of upper anal canal extends from top left until angled line marking the beginning of
the lower anal canal. Lower anal canal is located between the angled and straight vertical lines. MM: muscularis
mucosae, StS: stratified squamous nonkeratinized epithelium, StS(k): stratified squamous nonkeratinized epithelium, IAS:
th
internal anal sphincter, EAS: external anal sphincter. Modified from Plate 64 (upper panel) in Ross & Pawlina, 6 ed.

III. ANAL CANAL
The anal canal is the most distal portion of the alimentary canal and is
about 4 cm long. It has the following layers:
A. Mucosa
1. Upper anal canal resembles rectum of large intestine.
a. Simple columnar epithelium

b. Simple tubular glands (crypts of Lieberkühn):
contain many goblet cells, as well as
undifferentiated cells and a few enteroendocrine
cells (Figure 33).

2. As the upper anal canal transitions into the lower anal
canal, there are three changes in the mucosa (Box A in
Figure 33, Figure 34).
a. There is a transition from simple columnar to
stratified columnar epithelium (sometimes stratified
cuboidal then stratified columnar).
Microanatomy of the Intestines and Anal Canal
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b. Crypts of
Lieberkühn are lost.

c. Muscularis
mucosae
disappears.

3. Changes in epithelium
Figure 34. LM of transition between upper and lower anal
within the lower anal canal (Box A in Figure 34). Note: 1) Transition from simple
columnar to stratified columnar epithelium; 2) Loss of crypts
of Lieberkühn; 3) Loss of muscularis mucosae Modified
canal: th
from Plate 64 (lower left panel) in Ross & Pawlina, 6 ed.
(2011).
a. Epithelium will
further transition to
stratified squamous
nonkeratinized epithelium
(Box B in Figure 33).

b. At the end of the anal canal,
there is a transition of the
stratified squamous
nonkeratinized epithelium
to the stratified squamous
keratinized epithelium of
thin skin (Box B in Figure
33, Figure 35). Figure 35. LM of transition between lower anal
canal and external thin skin (Box B in Figure 34).. Note transition from nonkeratinized to
keratinized stratified squamous epithelium.
B. Submucosa: highly vascularized with Modified from Plate 64 (lower right panel) in Ross
th
& Pawlina, 6 ed. (2011).
extensive plexus of hemorrhoidal veins.
Microanatomy of the Intestines and Anal Canal
Rod D. Braun Page 29 of 33

C. Muscularis externa (Figures 33, 36)
1. As the upper anal canal
transitions to the lower anal
canal, the inner circular layer of
smooth muscle forms the
internal anal sphincter.

2. Within the lower anal canal, the
outer longitudinal layer of
smooth muscle terminates in
adjacent connective tissue.

3. An increasing layer of skeletal
muscle forms the external anal Figure 36. LM of anal canal. Modified from Figure
17.37a in Histology: A Text and Atlas (Ross & Pawlina,
sphincter (Figure 36). th
5 ed., 2005).

D. Adventitia (Fibrosa): The anal canal is retroperitoneal, so it is
covered by an adventitia.

IV. REVIEW OF ALIMENTARY CANAL WALL (Figure 37)
A. STOMACH
1. Rugae and mammilated areas are present, but there are no
villi in the stomach!

2. Mucosal glands are simple branched tubular glands that
empty into gastric pits.

3. Three poorly defined layers of smooth muscle in
muscularis externa.
Microanatomy of the Intestines and Anal Canal
Rod D. Braun Page 30 of 33
Figure 37. Schematic
of layers of the wall
of the alimentary
canal (digestive tract,
GI tract), from the
stomach through the
large intestine
(colon). Courtesy of
Dr. Roberta G.
Pourcho.

B. SMALL INTESTINES
1. Finger-like mucosal projections into lumen are called villi
and are only present in small intestine.

2. Mucosal glands are relatively short simple tubular glands
that open at the base of the villi (crypts of Lieberkühn).

3. Submucosal glands are only present in duodenum
(Brunner’s glands).
a. Villi + submucosal glands = duodenum.

b. Villi but no submucosal glands = jejunum or ileum
Microanatomy of the Intestines and Anal Canal
Rod D. Braun Page 31 of 33

4. Two well-defined smooth muscle layers in muscularis
externa: inner circular and outer longitudinal.

C. LARGE INTESTINES
1. Surface of mucosa is smooth. No villi in large intestines!

2. Mucosal glands are relatively long simple tubular glands
(crypts of Lieberkühn).

3. Muscularis externa
a. Two layers of smooth muscle in muscularis externa:
inner circular and outer longitudinal.

b. In colon, outer longitudinal layer is organized into
three distinct and separate bands, the taeniae coli.

References:

Erlandsen, S.L. and Magney, J.E., Human Histology: A Microfiche Atlas, University of Minnesota
Press: Minneapolis, 1985.

Gartner, L.P. and Hiatt, J.L., Color Atlas of Histology, 3rd ed., Lippincott Williams & Wilkins:
Philadelphia, 2000, Ch. 13.

Kessel, R.G. and Kardon, R.H., Tissues and Organs: A Text-Atlas of Scanning Electron Microscopy,
1979.

Kierszenbaum, A.L and Tres, L.L., Histology and Cell Biology: An Introduction to Pathology, 5th ed.,
Elsevier-Saunders, Philadelphia, 2020, Ch. 16.

MacCallum, D.K., Michigan Medical Histology, University of Michigan, Ann Arbor, 2000.
Microanatomy of the Intestines and Anal Canal
Rod D. Braun Page 32 of 33

Meyer, D.L., Unpublished histology slide atlas, Department of Anatomy, Wayne State University
School of Medicine, Detroit, 1970.

Rhodin, J.A.G., Histology: A Text and Atlas, Oxford University Press: New York, 1974, Ch. 30.

Ross, M.H. and Pawlina, W., Histology: A Text and Atlas, 6th ed., Lippincott, Williams, & Wilkins:
Philadelphia, 2011, Ch. 17.

Ross, M.H. and Pawlina, W., Histology: A Text and Atlas, 7th ed., Lippincott, Williams, & Wilkins,
WoltersKluwer Health: Philadelphia, 2016, Ch. 17. (major source)

Wismar, B.L. and Ackerman, G.A., A Visual Approach to Histology, Davis: Philadelphia, 1970.

See next page for summary table and diagram.
Microanatomy of the Intestines and Anal Canal
Rod D. Braun Page 33 of 33

Layers in GI Tract

Muscularis Fibrosa or
Mucosa Submucosa
Externa Serosa
Portion of GI Muscularis
Epithelium Glands Glands Layers
Tract Mucosae
Deep
Mucosal or cardiac esophageal or IC/OL
Esophagus SSNK Yes Fibrosa
glands near ends esophageal Skeletal → Smooth
proper
Stomach - Simple columnar
Cardiac Glands Yes None IO/MC/OL Serosa
Cardia (surface mucous cells)
Stomach - Simple columnar Fundic (Gastric,
Yes None IO/MC/OL Serosa
Fundus (surface mucous cells) Oxyntic) Glands
Stomach - Simple columnar
Pyloric Glands Yes None IO/MC/OL Serosa
Pylorus (surface mucous cells)
Small Intestine Simple columnar Intestinal (Crypts of Brunner’s
Yes IC/OL Serosa
- Duodenum (enterocytes + Goblet) Lieberkűhn) Glands
Small Intestine Simple columnar Intestinal (Crypts of
Yes None IC/OL Serosa
- Jejunum (enterocytes + Goblet) Lieberkűhn)
Small Intestine Simple columnar Intestinal (Crypts of
Yes None IC/OL Serosa
- Ileum (enterocytes + Goblet) Lieberkűhn)
Simple columnar Intestinal (Crypts of IC/OL + Taenia Serosa or
Large Intestine Yes None
(enterocytes + Goblet) Lieberkűhn) Coli Fibrosa
Upper Anal Upper: Simple columnar Intestinal (Crypts of IC → IAS (smooth)
Yes None Fibrosa
Canal (enterocytes + Goblet) Lieberkűhn) OL (stays smooth)
IAS (smooth) →
Lower Anal Stratified columnar →
None Lost (No) None EAS (skeletal) Fibrosa
Canal SSNK → SSK
OL terminates

Key: IC = inner circumferential IAS = internal anal sphincter
OL = outer longitudinal EAS = external anal sphincter
IO = inner oblique
MC = middle circumferential

Features of Mucosa in GI Tract (not to scale)

RDB: 9/30/2024