Histology of Digestive System-I Handout PDF

Summary

This handout covers the histology of the digestive system, including the oral cavity, alimentary tract, and accessory glands, and their functions relating to the digestive process. It describes the components and functions of the system, from ingestion to absorption, and the tissue types present.

Full Transcript

HISTOLOGY OF DIGESTIVE
SYSTEM-I
 THE DIGESTIVE SYSTEM
Histology of digestive system comprises
I. Oral cavity and its contents (Oral
histology)
II.Alimentary tract/Digestive tract or Gastro-
intestinal tract (GIT): a single tube which extends
from oral cavity to anus including pharynx, esophagus,
stomach, small intestine and large intestine.
III.Accessory/extrinsic glands of digestive
system: these include
major salivary glands (parotid,
submandibular & sublingual glands)
Liver
Gall bladder and
pancreas
 Functions of Digestive System
To obtain from ingested food the molecules
necessary for the maintenance, growth, and
energy needs of the body.
– Macromolecules such as proteins, fats, complex
carbohydrates, and nucleic acids are broken
down into small molecules that are more easily
absorbed through the lining of the digestive
tract, mostly in the small intestine.
Water, vitamins, and minerals from ingested
food are also absorbed.
In addition, the inner layer of the digestive
tract is a protective barrier between the
content of the tract's lumen and the internal
milieu of the body.
 The Oral/Mouth Cavity
Extends: from the lips and cheeks (externally) to
pillars of the fauces (internally), where it continues
posteriorly into the oropharynx through
oropharyngeal isthmus.
It has anterior and side walls, roof, and floor.
Subdivided into the oral cavity proper and the
vestibule, which communicate posteriorly behind the
last molar (wisdom) tooth when the mouth is closed.
The oral vestibule:
a slit like space between lips and cheeks
externally and gums and teeth internally).
receives the opening of parotid duct opposite to the
second upper molar tooth.
Mouth cavity Proper extends from inside of the teeth/
gingivae to oropharyngeal isthmus, which leads to Oropharynx.
 The Oral/Mouth Cavity
Functions:
1. Ingestion of food, mastication &
swallowing
2. Speech and ventilation (breathing)
Contents of oral cavity:
1.Tongue
2.Teeth
3. Minor/accessory salivary glands
 Boundaries of the Oral
Anteriorly: Lips
Cavity
Sidewalls: formed by Cheeks externally and by
gums and teeth internally.
Roof (superior boundary): formed by the hard
palate anteriorly and soft palate posteriorly.
Floor (inferior boundary): formed mainly by
myelohyoid muscle covered by oral mucosa
-occupied mainly by the tongue, lined with
thin epithelium- str, sq, non-keratinized
type
NB. Oral cavity is lined with stratified squamous
epithelium, keratinized or nonkeratinized, depending on
the region.
Boundaries of the Oral
Cavity
 LIPS
Fleshy fold of tissues forming the anterior boundary of
oral cavity.
Normally (Competent lips), the upper and lower lips are
lightly closed at rest forming the oral seal.
Each lip is attached to its respective gingiva by a fold of
mucosa known as frenulum on its internal surface:
– The upper lip is attached to the gingiva of the upper
jaw by frenulum of upper lip
– The lower lip is attached to the gingiva of the lower
jaw by frenulum of the lower lip
Each lip has a central bulk of skeletal
muscle (orbicularis oris) covered by
mucous membrane on inner side, & by
hairy skin on external/outer side.
 Competency of
Lips
Competent lips
- lips lightly closed at rest forming the
oral seal
Incompetent lips
- a lip seal is not produced at rest, i.e.
the lips are
merely held apart habitually.
Potentially competent lips
- lips that could be closed at rest in the
absence of interference caused by the
protruding incisors
LIPS-EXTERNAL surface

Cutaneous portion

Red Border

Red Border
Cutaneous portion
lips-Internal surface
(Mucous portion)

Frenulum of Lower lip

Mucous portion
 Histology of the Lips
1. Cutaneous Portion (External
surface of lip)
Consists of thin hairy skin
– keratinized stratified squamous epithelium
(epidermis), typical of thin skin
– the dermis consists of hair follicles, sebaceous and
sweat glands.
– passes through a transition zone to merge with oral
mucosa of the inner surface.
– irregular in outline due to hair follicles and ducts of
sweat glands which open onto the surface.
2. Red (Vermilion) Border or Transition
Zone
Constitutes the free, red portion of the lip, vermilion
refers to a brilliant red or scarlet color of this border
Consists of thin skin where epidermis is very thin,
lightly keratinized (with translucent prekeratin only)
stratified squamous epithelium, and transparent to
blood in the rich microvasculature of the underlying
connective tissue dermis from which it derives its
color.
 Vermilion border is devoid of hair follicles, sebaceous
and sweat glands, as a result it is prone to excessive
dryness and chapping in cold, dry weather.
 As a result requires continuous moistening from
saliva to prevent its dehydration and cracking.
 Its reddish color in the living state is from numerous
blood vessels in the connective tissue (lamina
propria).
 it is highly sensitive especially to touch due to its rich
sensory innervations.
3. Mucous Portion (Internal surface)
This is oral mucous membrane portion
Has smooth outline when compared to the outer
cutaneous portion
The mucosa consists of
Thick epithelium: non-keratinized stratified
squamous
Compact Lamina propria: houses minor salivary
glands of mucous type known as labial glands.
LIP TRANSVERSE SECTION

(Cutaneous Portion)

(Mucous Portion)
Histology of Lip cont’d…
A: Skin
(cutaneous
portion)
B: Vermilion
zone
C: Oral (labial)
mucosa
D: Minor salivary
glands (labial
glands)

LIP SAGITTAL SECTION
Histology of Lip
vertical
section

G= Salivary glands
OM= Oral mucosa
M= Orbicularis oris
muscle
F= Hair follicle
S= Skin (Cutaneous part)
V= Vermilion border
 General Histological Characteristics
of
The oral mucosa
Oral Mucosa consists of two layers: Surface
epithelium and Lamina propria
The epithelia form ridges that protrude towards
lamina propria known as epithelial ridges.
The papillary layer of the lamina propria
protrudes towards the oral epithelium (in between
the ridges) and carries blood vessels and nerves.
The epithelium is separated from the connective
tissue by means of a basement membrane
(*basal lamina + reticular lamina).
The oral mucosa is attached to the underlying
structures by a layer of tissue, the submucosa
consisting of connective tissue of varying
thickness, glands, blood vessels, nerves lymphatic
vessels and adipose tissue.
 THE CHEEKS
Forms the external side wall of oral cavity
Extend intraorally from the labial commissures
anteriorly to the ridge of mucosa overlying the
ascending ramus of the mandible posteriorly
Bounded superiorly by the upper and lower vestibular
sulci
Consists of a central bulk of skeletal muscle (mainly
buccinator) covered by mucosa on both surfaces.
1.Outer/External surface (cutaneous
portion)
– Covered by thin hairy skin (epidermis= keratinized
stratified squamous epithelium, and dermis with
sweat glands, sebaceous glands and hair follicles)
– Under skin is buccal pad of fat
2.Inner/Oral surface (mucous portion)
– Lined by oral mucosa
 The Oral mucosa of
Cheeks
The Epithelium: thick non keratinized stratified
squamous
Lamina propria:
– similar to the oral mucosa that lines the inner part of
the lips, but with abundant elastic fibers, which
permit over stretching of this tissue during blowing
and full mouth chewing.
– It is also smoking tissue
– Houses accessory (minor) salivary gland of mucous,
serous and mixed types called Buccal glands.
Ectopic sebaceous glands may be evident in the
mucosa as yellowish patches called Fordyce’s spots
The parotid duct drains into the cheek/vestibule
opposite the maxillary second molar tooth and its
opening is covered by a small fold of mucosa termed-
parotid papilla.
 ROOF OF ORAL CAVITY (Hard and
Soft
Palates palates)
form the roof of oral cavity (oral or lower part)
and floor of nasal cavity (nasal or upper part).
HARD PALATE
Constitutes the anterior 2/3rd of palates.
Its central bulk is bony and formed by palatine
processes of maxillae and horizontal processes of
palatine bones.
Covered by thin mucosae on both surfaces.
Lower surface (Oral part):
Lined by thin oral mucosa:
– Epithelium: non keratinized stratified squamous
epi.
– A dense fibrous lamina propria: devoid of glands,
near the midline and adherent to periosteum of the
bones.
 The lamina propria reveals transverse ridges to assist the
process of mastication.
As a result the mucosa is thrown into several transverse
folds known as palatine rugae or papillae.
These are equivalent to the dermal papillae of thick skin
which forms the finger and foot prints.
Except in the median palatal raphae & near the gum, the
lamina propria contains:
– Fat: in its anterior third (i.e. in its anterolateral aspect)
– Few accessory salivary glands of mucous type: in
its posterolateral part continuous with soft palate only.
Upper surface (Nasal part):
– Lined by respiratory mucosa formed by
pseudostratified
columnar epithelium and very thin lamina propria.
 SOFT PALATE
Constitutes the posterior 1/3rd of palates
Its central bulk consists of a thick bundle of
striated muscles
Covered by a thick mucosa on both surfaces
Lower surface (Oral part):
Lined by an oral mucosa formed by:
1.Epithelium: thick non keratinized stratified
squamous
2.Lamina propria:
Infiltrated with lymphocytes
Consists of accessory minor salivary glands
of mucous type known as palatal glands
and a few taste buds.
Upper surface (Nasal part):
PALATES
Surface features
- palatine rugae
- papillae
- free & attached
gingivae
- stippling only on
the attached
gingivae
- NB: finger prints vs
palatine rugae
 TONGUE
is the major content of oral cavity used for speech,
manipulation of food and for sensory perception.
is a pyramidal muscular organ with a wide base (root)
& a narrow apex (tip),upper (dorsal) and lower
(ventral) surfaces
placed horizontally in the oral cavity in anterior-
posterior axis, its apex directed anteriorly.
is a mass of striated muscle (forming its central bulk)
covered by a mucous membrane (oral mucosa) whose
structure varies according to the region.
its mucous membrane is specialized for manipulation
of food, general sensory reception and special visceral
sensory function of taste.
The mucous membrane is smooth on the lower
surface, while the dorsal surface is irregular & rough.
 THE
TONGUE
 Dorsum of
Tongue
The tongue's dorsal surface is divided into anterior
two third & posterior third by a V-shaped groove, the
terminal sulcus (Sulcus terminalis).
The vertex (apex) of this sulcus is directed posteriorly
and ends in a shallow pit, the foramen cecum.
Foramen cecum marks the embryonic origin of thyroid
gland from the floor of mouth.
Irregular and roughened by a great number of small
surface projections or eminences.
Anterior two-third of dorsum of tongue:
– lies in front of sulcus terminalis
– constitutes the body and apex or tip of the tongue
– roughened by mucosal projections called lingual
papillae of four types.
Tongue (Dorsum)
NORMAL TONGUE, TRANSVERSE SECTION
Posterior one-third of dorsum of tongue:
– lies behind the sulcus terminalis
– constitutes the root or base of the tongue
– roughened by masses of lymphoid nodules
separated by shallow grooves , tonsilar crypts, all
of which comprise the lingual tonsils.
– have deferent embryonic origin
Lingual papillae
are elevations of the mucous membrane of the
dorsum of the anterior two-third of the tongue
they assume various forms and functions
all contain cores of connective tissue (lamina propria)
covered by stratified squamous epithelium
(keratinized in filiform, in the others all, non-
keratinized)
 Four types are recognized: filiform, fungiform,foliate &
circumvallate
 1. Filiform
papillae
quite numerous and makes
up majority of the papillae
present over the entire
anterior surface of the
tongue
short (2.5-3mm high),
narrow, conical, bristle-like
highly keratinized
projections
thus resistant to abrasion
they facilitate mastication
they erect & directed
towards
the throat and assist in
movement of food towards
that direction
whitish appearance
devoid of taste buds
 2. Fungiform
papillae
wider (1 mm in diameter)
than filiform, but only about
1.9 mm high & interspersed
among them
resemble mushrooms in that
they have a narrow stalk & a
smooth surfaced, dome-
shaped upper dilated part
the lamina propria rich in
blood vessels & imparts
translucent, reddish color
covered by a thin non-
keratinized stratified
squamous epithelium.
more numerous near the tip
of the tongue
contain one or more
transversely placed taste
buds
FUNGIFORM PAPILLA

Non-keratinized, stratified
squamous epithelium

Core of lamina
propria
 3. Foliate
papillae
leaf-like, appear as closely
Foliate Papillae
packed folds bilaterally
located along the posterior
border of the body of
tongue
rudimentary in human
adult
present on the postero-
lateral margins of the
tongue
consist of 4 to 11 parallel
ridges that alternate with
deep grooves or furrows in
the mucosa, which receive
the openings of Von
Ebner’s glands
contain several taste buds
FOLIATE PAPILLAE WITH TASTE BUDS
Filiform papillae
FOLIATE PAPILLAE WITH TASTE BUDS
Taste buds
 4. Circumvallate
papillae
The largest (3 mm in
diameter) & least
common papillae
Not more than 12 (7-
12) in number
Arranged as a single
row in front of sulcus
terminalis
Each is surrounded by
a moat-like deep
groove, called trench Core of lamina
The trench receives propria
the openings of the
ducts of Von Ebner's
glands (serous
salivary glands)
 Circumvallate
papillae
Contain numerous taste buds
The taste buds are strategically placed along the
trenches so that the substances to be tasted can
easily reach & dissolved in the watery secretion
of Von Ebner’s glands.
This secretion also washes away chemicals that
are being tasted & prepares the receptors for
new stimuli.
Ebner’s glands also secrete a lingual lipase,
that probably prevents the formation of
hydrophobic layer over the taste pores that
could hinder the function of receptor cells.
Lingual lipase is also active in the stomach and
can digest up to 30% of dietary triglycerides.
 Taste
Buds
Are special visceral sense
organs located in epithelium
of dorsum of tongue along
the trenches and furrows.
Few taste buds are also
found in soft palate,
epiglottis, larynx, and
pharynx
Onion or barrel-shaped
intraepithelial structures
whose opening (taste pores)
face trenches
Also referred to as
Neuroepithelial
structures
 A Taste Bud
is about 80 microns in height and 40 microns in
width.
composed of about 30 to 50 modified epithelial
cells, some of which are supporting cells called
sustentacular cells and others of which are
taste (Gustatory) cells.
The taste cells are continually being replaced by
mitotic division of surrounding epithelial cells, so
that some taste cells are young cells.
Others are mature cells that lie toward the
center of the bud; these soon break up and
dissolve.
The life span of each taste cell is about 10 days
in lower mammals but is unknown for humans.
The outer tips of the taste cells are arranged
 Taste Buds
Each taste bud has three types of cells: taste cells,
supporting & basal cells.
1.Taste (Gustatory) cells
receptor cells of taste, and are most numerous cells
are light cells whose apex poke numerous microvilli
or taste hairs outward into the taste pore to
approach the cavity of the mouth
these microvilli provide the receptor surface for taste.
Receive contact tastants dissolved in saliva
Afferents nerve fibers are associated to the base of
these cells
2. Supportive cells (appear darker in routine stains)
secrete amorphous substance that surrounds microvilli

in a taste pore
 Taste Buds
3. Basal cells
Undifferentiated
stem cells
Replace all cells of
the buds by division
Taste
Bud
 A Taste Bud
Interwoven around the bodies of the taste cells is a
branching terminal network of taste nerve fibers
(unmyelinated) that are stimulated by the taste receptor
cells.
Some of these fibers invaginate into folds of the taste cell
membranes.
Many vesicles form beneath the cell membrane near the
fibers.
These vesicles are believed to contain a
neurotransmitter substance that is released through the
cell membrane to excite the nerve fiber endings in
response to taste stimulation.
Location of the Taste Buds.
The taste buds are found on three types of papillae of the
tongue.
Additional taste buds are located on the palate, and a
few are found on the tonsillar pillars, on the epiglottis,
TASTE BUD
 A person can perceive hundreds of different tastes. They
are all supposed to be combinations of five primary
taste sensations, just as all the colors we can see are
combinations of three primary colors (red, green & blue)
Taste buds detect at least five broad categories of
tastants: metal ions (salty); hydrogen ions from acids
(sour); sugars and related organic compounds (sweet);
alkaloids and certain toxins (bitter); and certain amino
acids such as glutamate (umami; Jap. umami, savory).
Umami Taste: is a separate, fifth category of primary
taste stimuli. Umami is a Japanese word (meaning
"delicious") designating a pleasant taste sensation that
is qualitatively different from sour, salty, sweet, or
bitter.
– Umami is the dominant taste of food containing L-
glutamate, such as meat extracts and aging cheese.
 Salty and sour tastes are produced by ion channels; the
other taste categories are mediated by G-protein-
coupled receptors.
Receptor binding produces depolarization of the
gustatory cells, stimulating the sensory nerve fibers
which send information to the brain for processing.
Conscious perception of tastes in food requires olfactory
and other sensations in addition to taste bud activity.
A taste receptor for l-glutamate may be related to one of
the glutamate receptors expressed in neuronal synapses
of the brain.
However, the precise molecular mechanisms responsible
for umami taste are still unclear.
Specificity of Taste Buds for a Primary Taste
Stimulus.
Microelectrode studies from single taste buds show that
each taste bud usually responds mostly to one of the
five primary taste stimuli when the taste substance is in
 Muscles of the
form the bulkTongue
of the tongue
all are skeletal (striated) muscles
The tongue muscle fibers cross one another in three
planes and are grouped in bundles separated by
connective tissue.
Because the connective tissue of the lamina propria
penetrates the spaces between the muscular bundles, the
mucous membrane is strongly adherent to the muscle
mucous and serous minor salivary glands (lingual glands)
are interspersed between the bundles of muscles
Are of two groups: INTINSIC & EXTRINSIC
Intrinsic muscles:
- they change the shape of the tongue
– fibers oriented in three planes:
Longitudinal ,Transverse and Vertical
Extrinsic muscles: change the position of the tongue
 Tongue skeletal muscle in three planes: A,
longitudinal fibers in x plane; B, vertical fibers in y
plane; C, transverse fibers in z plane direction
NORMAL TONGUE, TRANSVERSE SECTION
TONGUE, STRATIFIED SQUAMOUS EPITHELIUM AT HIGH
MAGNIFICATION
NORMAL TONGUE, TRANSVERSE
SECTION
Von Ebner’s glands
 TEETH
(DENTES)
Introduction
In human, there are two sets of teeth (dentition):
1.Primary dentition (temporary; deciduous;
milk teeth; baby teeth)- 20 in number
2. Secondary dentition (permanent; adult
teeth)-32 in ♯
In adult humans, 32 permanent teeth
- Disposed in two bilaterally symmetric arches in the
maxillary and mandibular bones, with eight teeth in each
quadrant: two incisors, one canine, two premolars, and
three permanent molars.
Twenty of the permanent teeth are preceded by deciduous
predecessors (baby teeth); the remainder (the premolars
and the last molar or wisdom teeth) have no deciduous
Left lateral view of dentition. Arrows, unerupted
permanent teeth.
 Types of Teeth and their
eruption time

NB. The years under brackets indicate time of eruption of permanent teeth
 Parts of a Tooth
Each tooth consists of the crown, neck and root(s)
1.Crown
is exposed portion that projects above the gingiva
is covered by extremely hard substance – enamel
 In young, anatomical crown is covered by enamel, but in
older an individuals most enamel is lost by erosion and the
exposed crown is called clinical or functional crown.
2. Root(s)= Radix
– is the portion in side the gum below the gingiva that
hold
the teeth in bony sockets called alveoli,
– can be one or more for each tooth.
– covered by another bone-like mineralized tissue, the
cementum.
3. Neck (cervix of the tooth)
- The constricted region between crown & roots
- The two coverings (enamel & cementum) meet at neck
VS through a
tooth
 Composition of a
Tooth
1.Dental Tissue Proper
Dentin
Enamel
Cementum and
Dental pulp- in pulp cavity (pulp
chamber and
root canal)
2. Supportive Tissues
Periodontal ligament
Alveolar bone and
Gingivae
 The main bulk of a tooth is composed of a calcified
material, dentin, that surrounds the pulp cavity.
The pulp cavity has a coronary portion (the pulp
chamber) and a root portion (the root canal),
extending to the apex of the root, where an orifice
(apical foramen) permits the entrance and exit of
blood vessels, lymphatics, and nerves of the pulp
cavity. Denti
n that is harder than bone
A calcified tissue
because of its higher content (70% of dry
weight) of calcium salts in the form of calcium
hydroxyapatite.
Its organic matrix contains type I collagen
fibers, glycos-aminoglycans, phosphoproteins,
phospho-lipids.
Its inorganic portion is highly mineralized & consists of
 The organic matrix of dentin is secreted by
odontoblasts,
Odontoblasts
are slender, tall polarized cells that line the pulp cavity
are bound together by junctional complexes as a layer,
with no basal lamina, and produce organic matrix only at
the dentinal surface.
neural crest origin (head mesenchyme)
are polarized, protein secreting cells with oval-shaped
basal nucleus (cell body) & apical cytoplasmic secretory
granules
their cell body face the pulp cavity and hence they are
called pulp cells
have slender, branched apical extensions that penetrate
perpendicularly through the width of the dentin—the
odontoblast processes (Tomes' fibers), which
run in small canals known as dentinal tubules.
 Dentinal Tubules
are living canals which carry blood vessels &
unmyelinated afferent nerve fibers to the odontoblast
processes
limited by uncalcified dental sheath of Newman.
also houses sensory receptors for pain, cold, warm,
PH, trauma, etc all of which are interpreted as pain in
CNS.
extensively branch near the dentino-enamel junction.
As the dentin-predentin layer thickens, Tome’s fibers
lengthen and send fine branches into smaller lateral
branches of these tubules.
The Dentine Matrix
The organic matrix produced by odontoblasts is
initially unmineralized/uncalcified and is called
predentin or dentinoid.
 The mineralization of developing dentin begins one day
of secretion, when membrane-limited vesicles—matrix
vesicles—appear, produced by odontoblasts.
The process of mineralization is similar to that
occurring in osteoid of developing bones & involves
binding of calcium & phosphate ions to collagen fibrils
(in the matrix vesicles), resulting in formation of fine
crystals of hydroxyapatite that grow and serve as
nucleation sites for further mineral deposition on the
surrounding collagen fibrils.
Odontoblasts remain active in predentin secretion
into adult life, gradually reducing the size of the pulp
cavity.
Odontoblast processes can be silver-stained and shown
to branch near the junction of dentin with enamel (E)
and along their length closer to their source (c), with
the lateral branches occupying smaller canaliculi within
dentin.
Histology of
Tooth
 Ultrastructure of dentinal tubule &
odontoblast
processes

Odontoblast process (OP) running in small canals called
dentinal tubules. Note its close association with an
unmyelinated nerve fiber (N) extending there from fibers in
the pulp cavity.
 These odontoblast process (OP) connections to the
odontoblasts (O) are important for the maintenance
of dentin in adult teeth.
Cross-section of an odontoblast process (OP) near
predentin (P) shows its close association with an
unmyelinated nerve fiber (N) extending there from
fibers in the pulp cavity (the above slide b).
These nerves respond to various stimuli reaching the
nerve fibers through the dentinal tubules, such as
heat, cold, trauma, and acidic pH, and all are
perceived as pain.
Therefore, pain is the only sensory modality
perceived in teeth.
According to the hydrodynamic theory, the different
stimuli cause the movement of fluids inside dentinal
tubules, which stimulate the nerve fibers located near
odontoblast processes.
 Dentine is similar in mineral & organic composition to
bone, but differs from it in the following ways:
 No Haversian system
 No odontocytes equivalents of osteocytes
 More harder than bone (due to its higher
mineralization than bone), that is why dentine
persists as a mineralized tissue long after
destruction of the odontoblasts and thus tooth
remains undecomposable
It is therefore possible to maintain teeth whose pulp
and odontoblasts have been destroyed by infection
(canal treatment).
In adult teeth, destruction of the covering enamel by
erosion from use or dental caries (tooth decay)
usually triggers a reaction in odontoblasts that
causes them to resume the synthesis of dentin
components
 Enamel
the hardest component of the human body
has highly calcified matrix composed of about
96% mineral (98% in dry state), 1% organic
material, and 3% water as the remainder in
living state.
the inorganic component of enamel is mostly
calcium hydroxyapatite crystals.
Other ions, such as strontium, magnesium, lead,
and fluoride, if present during enamel synthesis,
can be incorporated or adsorbed by the crystals.
enamel containing fluorapatite is more resistant
to acidic dissolution caused by microorganisms,
hence the addition of fluoride to toothpaste and
water supplies.
 Enamel
The organic enamel matrix is composed not
of collagen fibrils but of at least two
heterogeneous classes of glycoproteins
called amelogenins and enamelins.
The organic enamel matrix is secreted by
cells of ectodermal origin called
ameloblasts
Ameloblasts
ectodermal in origin, whereas most of the
other structures of teeth derive from
mesodermal or
neural crest cells
Their cell body found at periphery
 Amelobla
sts polarized cells with numerous
are tall columnar,
mitochondria, well-developed RER & Golgi apparatus
Each ameloblast has an apical extension, known as a
Tomes' process.
Tomes' process contains numerous secretory
granules that contain the proteins that make up the
enamel matrix.
After finishing the synthesis of enamel, ameloblasts
form a protective epithelium that covers the crown
until the eruption of the tooth.
This protective function is very important in
preventing several enamel defects.
After tooth eruption, they degenerate.
 Enamel consists of elongated rods or columns—
enamel rods (prisms)—that are bound
together by interrod enamel.
Enamel rods are externally covered by enamel
sheath
Both interrod enamel and enamel rods are
formed of hydroxyapatite crystals; they differ
only in the orientation of the crystals.
Each rod extends through the entire thickness
of the enamel layer and has a sinuous track.
The arrangement of rods in groups is very
important for enamel's mechanical properties.
MEDICAL APPLICATION
The susceptibility of enamel crystals to
dissolution in acidic pH is the basis for dental
caries, and some of these crystals (e.g.
 Ameloblasts and enamel

Ameloblasts (A) are tall polarized cells whose apical ends initially contact dentin (D).
Ameloblasts are joined to form a cell layer surrounded basally by connective tissue
(CT). As odontoblasts secrete predentin, ameloblasts secrete a matrix lacking collagens,
but rich in a few glycoproteins which quickly initiate calcium hydroxyapatite formation
to make enamel (E), the hardest material in the body. Enamel forms a layer, but
consists of enamel rods or prisms, solidly fused together by more enamel. No cellular
processes occur in enamel and the layer of ameloblasts surrounding the developing
crown is completely lost during tooth eruption. Teeth that have been decalcified for
histological sectioning typically lose their enamel layer completely.
 Dental Pulp and
Pulp Cavity
Pulp Cavity
a soft connective tissue-filled space surrounded
by dentin.
richly vascularized & contains afferent nerve
fibers.
All sensations from the pulp are interpreted as
pain in CNS.
its periphery contains the organized
odontoblasts
has two portions:
1. Pulp chamber- the upper, expanded coronary
portion
2. Root canal (root portion)- a narrow portion
which lies in the root(s), extending to the apex of the
root, which ends at apical foramen.
 Dental (Tooth)
Pulp
is loose gelatinous mucoid, embryonic CT, contained
within the pulp chamber and root canals.
its main components are:
- odontoblasts
- fibroblasts
- mesenchymal cells, all of neural crest origin
- reticulin & thin collagen fibrils, and a ground
substance
that contains glycosaminoglycans
- blood vessels, lymphatics & nerve fibers
Pulp is a highly innervated and vascularized tissue.
Blood vessels and myelinated nerve fibers enter the
apical foramen and divide into numerous branches.
Some nerve fibers lose their myelin sheaths and
extend for a short distance into the dentinal tubules.
These pulp fibers are sensitive to pain only.
Micrograph of
Dental Pulp
O-Odontoblasts
D-Dentine
V-Vessels

The periphery of the dental pulp contains the organized odontoblasts (O)
contacting the surrounding dentin (D). Centrally the pulp consists of
delicate, highly cellular connective tissue resembling undifferentiated
mesenchyme but with many thin-walled venules (V) and capillaries. Pulp
has reticulin fibers and other fine collagen fibers, with much ground
substance. Nerves fibers are also present. The blood and nerve supplies
enter the pulp cavity via the apical foramen at the apex of the roots.
 Periodontium (around
tooth)responsible for maintaining
comprises the structures
the teeth in the maxillary and mandibular bones.
consists of the cementum, periodontal ligament,
alveolar bone, and gingiva.

Cementum
is a calcified tissue covering dentine of the root
forms a thin layer of bone-like material secreted by
large, elongated cells called cementoblasts.
is similar in composition and calcification to bone,
although Haversian systems (osteons) and blood
vessels are absent.
It is thicker in the apical region of the root, where there
are cementocytes, cells with the appearance of
osteocytes.
 Like osteocytes, they are encased in lacunae; unlike
those cells, however, cementocytes do not
communicate through canaliculi, and their
nourishment comes from the periodontal ligament.
Like bone tissue, cementum is labile and reacts to the
stresses to which it is subjected by resorbing old
tissue or producing new tissue.
Continuous production of cementum in the apex
compensates for the physiological wear of the teeth
and maintains close contact between the roots of the
teeth and their sockets.
Compared with bone, the cementum has lower
metabolic activity because it is not irrigated by blood
vessels.
This feature allows the movement of teeth by
orthodontic appliances without significant root
resorption.
 micrographs of Periodontium
cementum (C), periodontal ligament (PL), alveolar
bone (B), and gingiva
FG = free gingiva, v = vessels, D = Dentine, P =
periosteum covering the bone, LP = lamina
propria of the gingiva, SF = Sharpey’s fibers

SF

PL

SF
 Periodontal Ligament
(membrane)
a dense fibrous connective tissue (about 150 to
350 µm) with bundles of collagen fibers inserted
into the cementum and alveolar bone, fixing the
tooth firmly in its bony socket (alveolus).
permits limited movement of the tooth within the
socket and the fibers are organized to support the
pressures exerted during mastication.
this avoids transmission of pressure directly to the
bone which would cause localized bone resorption.
unlike typical ligaments, it is highly cellular and has
a rich supply of blood vessels and nerves, giving
the periodontal ligament supportive, protective,
sensory, and nutritive functions.
 Collagen of the periodontal ligament has an
unusually high turnover rate (as demonstrated
by autoradiography) and a high content of
soluble collagens, with the space between its
fibers filled with glycosaminoglycans (GAGs).

MEDICAL APPLICATION
The high rate of collagen renewal in the
periodontal ligament allows processes affecting
protein or collagen synthesis, e.g., protein or
vitamin C deficiency (scurvy), to cause atrophy
of this ligament. As a consequence, teeth
become loose in their sockets; in extreme cases
they fall out. This relative plasticity of the
periodontal ligament is important because it
allows orthodontic intervention, which can
 Alveolar Bone (alveolar processes of the maxillae
and mandible)
The alveolar bone is in immediate contact with the
periodontal ligament, which serves as its periosteum.
It is an immature type of bone (primary bone) in
which the collagen fibers are not arranged in the
typical lamellar pattern of adult bone.
Many of the collagen fiber bundles of the periodontal
ligament penetrate this bone and bind it to the
cementum.
The bone closest to the roots of the teeth forms the
tooth sockets.
Vessels (perforating vessels) run through the
alveolar bone and penetrate the periodontal ligament
along the root.
Some vessels and nerves from alveolar bone run to
the apical foramen of the root to enter the pulp
 Alveolar
ManyBone (B) fibers of the periodontal
of the collagen
ligament (L) are arranged in bundles that penetrate
this bone and the cementum (C), forming a
connecting bridge between the two structures known
as Sharpey's fibers (SF).

SF

SF
 THE GINGIVA
a mucous membrane firmly bound to the periosteum of
the maxillary and mandibular bones.
composed of Keratinized stratified squamous
epithelium and lamina propria containing numerous
connective tissue papillae.
a very specialized part of this epithelium, the
junctional epithelium, is bound to the tooth enamel
by means of a cuticle that resembles a thick basal
lamina and forms the epithelial attachment of
Gottlieb.
the epithelial cells are attached to this cuticle by hemi-
desmosomes.
between the enamel and the epithelium is the gingival
sulcus or gingival crevice, a small deepening or
groove up to 3 mm surrounding the crown.
 Gingiva may be divided into two:
1. Attached Gingiva:
Part of the gingiva which provides protective covering
over the alveolar bone
2. Free Gingiva:
Part of the gingiva which forms a protective cuff
around the enamel at the neck of the tooth.
Between this gingiva and enamel is a potential space,
the gingival crevice or sulcus, which extends from
the tip of the free gingiva to the cemento-enamel
junction.
At the tip of free gingiva, the epithelium undergoes
abrupt transition to a thin layer of epithelial cells
tapering to only two or three cells thick at the base of
the gingival crevice.
This crevical epithelium is easily breached by
pathogens and the underlying lamina propria is thus.
 THE GINGIVAE

Attached gingiva

Attached
gingiva

Free gingiva

Medical Application
The depth of the gingival sulcus, measured during clinical
examination, is very important and may indicate periodontal
 Histology of gingiva
A.Epithelum
stratified squamous type smooth in free gingva,
stippled in attached gingiva.
according to the behavior of the surface layer,
different types of gingival epithelium can be
noticed.
1.Fully Keratinized epithelium- the surface
layer consist of flat tightly packed horny scales,
without nuclei (15%)
2.Parakeratinized epithelium- the surface
cells retain the pyknotic and condensed nuclei.
Keratinization is not complete (50%). Incomplete
parakeratosis may be observed
3.Non Keratinized epithelium- the surface
cells are flay with nuclei (10%)
 Histology of gingiva
B. Lamina propria:
consists of dense CT not highly vascular.
Macrophages are present. Fibroblasts are
abundant. Plasma cells and lymphocytes are also
present normally under the crevice.
There are also blood vessels, rich network of
lymphatic vessels and different nerve endings
such as Meissner or krause corpuscles, end bulbs,
etc.
 Tooth
Development
involves the following major stages: bud stage,
cap stage, bell stage and stage of root
development.
each tooth is derived from two embryological
sources:
the enamel is of epithelial (ectodermal)
whilst the
dentine, cementum, pulp, periodontal
ligament and alveolar bone are of
mesenchymal (mesodermal) origin
tooth development in human begins during the
6th week of intrauterine development.
appear as a thickening of a horseshoe-shaped
(C-shaped) epithelial ridge, known as dental
 Maxillary
Process

Stomodeum

Dental
lamina

Developing Tongue Mandibular process
 In each quadrant of the mouth, the dental
lamina develops four globular swellings-
the enamel organs (this marks the bud
stage).
The enamel organs are the future
deciduous central & lateral incisors,
canine & first molar teeth.
Subsequently, the dental lamina
proliferates backwards in each arch
successively giving rise to the enamel
organs of the future second deciduous
molar & the three permanent molars.
The permanent successors of the
deciduous teeth will later develop from
 1. Bud Stage

Intramembr
anous
Meckel’s ossification
cartilage

Bud stage is characterized by rounded, localized
growth of epithelium surrounded by
proliferating mesenchymal cells, which are
packed closely beneath and around the
 1. Bud Stage

In the bud stage, the enamel organ consists of peripherally located
low columnar cells and centrally located polygonal cells
 2. Cap Stage
The primitive mesenchyme subjacent to the
developing enamel organ proliferates to form a
cellular mass known as dental papilla, whilst
at the same time, the enamel organ becomes
progressively cap-shaped (marks cap stage), as
seen in micrograph (a), enveloping the dental
papilla.
During the cap stage, the cells lining the
concave face of the enamel organ in contact
with the dental papilla begin to differentiate into
tall columnar cells , the future ameloblasts,
which will form the enamel.
This, in turn, induces the differentiation of a
layer of columnar odontoblasts (dentine-
 Stages of Tooth formation and layers of
developing
OEE= Outer enamel/tooth
dental epithelium, DP= Dental papilla, O=
Odontoblasts, A= Ameloblasts, PD= Predentin, D= Dentin, B= alveolar
Bone,
 2. Cap
Stage

Enamel Organ Dental Papilla
Condensation of the ectomesenchyme immediately
subjacent to the tooth bud caused by lack of
extracellular matrix secretion by the cells thus
preventing separation.
Histodifferentiation begins at the end of cap
stage.
Epithelial outgrowth called Enamel Organ because
it will eventually form the enamel

 2. Cap Stage

Enamel organ

Enamel knot
Dental papilla

Dental follicle or sac
Dental follicle or dental sac is the condensed ectomesenchymal tissue
surrounding the enamel organ and dental papilla. This gives rise to
cementum and the periodontal ligament (support structures for
tooth)
 The outer surface of the enamel organ consists
of simple cuboidal epithelium- the
outer/external enamel epithelium
By the cap stage of development, the dental
lamina connecting the enamel organ to the oral
mucosa fragmented and, around the whole
developing bud, a condensation of mesenchyme
forms the dental follicle (sac) which will
eventually become the cementum,
periodontal ligament & alveolar bone.
Although enamel production is confined to the
crown, the rim of the bell of the enamel organ
nevertheless continues to proliferate, inducing
dentine formation & thereby determining the
shape of the tooth root.

 3. Bell stage
As the enamel organ develops further, it
assumes a characteristic bell shape, its free
edge proliferating so as to determine the
eventual shape of the tooth crown.
As the dentine of the crown and root are
progressively laid down the dental papilla
shrinks and eventually becomes the dental pulp
contained within the pulp chamber and root
canals.
The dentine and dental pulp directly develop
from the dental papilla, while the cementum,
periodontal ligament as well as the alveolar
bone develop from the dental follicle of the
surrounding mesenchyme

 3. Bell Stage
(Early) Outer dental epithelium
Stellate reticulum
Stratum intermedium

Inner dental epithelium

Dental papilla

Inner dental epithelium: Short columnar cells bordering the
dental papilla. These will eventually become ameloblasts
that will form the enamel of the tooth crown by differentiating
into tall columnar cells. The cells of inner dental epithelium
exert an organizing influence on the underlying mesenchymal
cells in the dental papilla, which later differentiate into
odontoblasts.
Outer dental epithelium: Cuboidal cells that cover the enamel
organ. Their function is to organize a network of capillaries
that will bring nutrition to the ameloblasts. In preparation to
formation of enamel, at the end of bell stage, the formerly
 3. Bell Stage (Early)
Outer dental epithelium

Stellate reticulum

Stratum intermedium

Inner dental epithelium

Dental papilla

Stellate reticulum: Star-shaped cells with processes,
present between the outer
and the inner dental epithelium. These cells secrete
glycosaminoglycans,
which attract water, thereby swelling the cells and pushing
them apart.
However, they still maintain contact with each other, thus
becoming star-shaped.
They have a cushion-like consistency that may support and
 Outer dental epithelium

Stellate reticulum

Stratum intermedium

Inner dental epithelium

Dental papilla

Dental Papilla: Before the inner dental epithelium begins to
produce enamel, the peripheral cells of the mesenchymal dental
papilla differentiate into odontoblasts under the organizing influence
of the epithelium. First, they assume a cuboidal shape and then a
columnar form and acquire the specific potential to produce dentin.
The basement membrane that separates the enamel organ and
the dental papilla just prior to dentin formation is called the
“membrana preformativa”
 3. Bell Stage

Dental lamina (and the lateral lamina) will
disintegrate and loose contact with oral
epithelium. Sometimes, these epithelial cells will
persist when they are called “epithelial pearls” or
“cell rests of Serre”
Clinical significance: Cysts will develop in these
(eruption cysts) and prevent eruption, or they
Eruption
Cyst
Future crown patterning also occurs in the bell stage, by folding of
the inner dental epithelium. Cessation of mitotic activity within the
inner dental epithelium determines the shape of a tooth.