Oral Histology "tooth development"
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About This Presentation
Oral Histology
1st Lecture
Slide Content
UP TO DATE
IN
ORAL BIOLOGY AND EMBRYOLOGY
Prof. Dr. Nahed A. Khalil
Head of Oral Biology Department
&
Contributing Staff Members
Faculty of Oral &Dental Medicine
Cairo University
IN
ORAL BIOLOGY AND EMBRYOLOGY
Prof. Dr. Nahed A. Khalil
Head of Oral Biology Department
&
Contributing Staff Members
Faculty of Oral &Dental Medicine
Cairo University
At the age of 5-6 W.I.U.L. the primitive oral cavity is
lined by ectoderm composed of 2 -3 layers, basal
columnar & superficial flat cells.
The mesoderm containing ectomesenchymal cells is
separated from the oral ectoderm by a basment
membrane
lined by ectoderm composed of 2 -3 layers, basal
columnar & superficial flat cells.
The mesoderm containing ectomesenchymal cells is
separated from the oral ectoderm by a basment
membrane
At 5-6 w.i.u.l Embryo
Head Head
Stomodeum Stomodeum
Heart
Basement
membrane
MESODERM
ECTODERM
Head Head
Stomodeum Stomodeum
Heart
Basement
membrane
MESODERM
ECTODERM
The Morphological stages of tooth
development are:
1- dental lamina formation
2- Bud stage
3- Cap stage
4- Bell stage : which is divided into :
-* Early bell stage (before dentin formation).
-* Advanced (Late) bell stage (after formation of the 1
st
layer of dentin).
development are:
1- dental lamina formation
2- Bud stage
3- Cap stage
4- Bell stage : which is divided into :
-* Early bell stage (before dentin formation).
-* Advanced (Late) bell stage (after formation of the 1
st
layer of dentin).
Under the influence of the ectomesenchyme (neural crest cells),
ectodermal proliferation in the underlying connective tissue takes
place in separate islands that coalesce to form a band exhibiting
a horse shoe shape in the upper & lower jaws. This band is called
the tooth band or the dental lamina.
1- Dental lamina formation
ectodermal proliferation in the underlying connective tissue takes
place in separate islands that coalesce to form a band exhibiting
a horse shoe shape in the upper & lower jaws. This band is called
the tooth band or the dental lamina.
1- Dental lamina formation
11--Stage of dental laminaStage of dental lamina
Flat cells
Columnar cells
At 6-7 W.I.U.L
Ectomesenchymal tissue
Ectoderm
Basement
membrane
Flat cells
Columnar cells
At 6-7 W.I.U.L
Ectomesenchymal tissue
Ectoderm
Basement
membrane
Condensation of
ectomesenchymal cells occurs
around epithelial proliferation
at certain sites on the labial
surface of the dental lamina.
Each site represents one of the
deciduous teeth.
From this point tooth
development proceeds in 3
stages describing the
morphology of the developing
tooth germ: Bud, Cap & Bell.
ectomesenchymal cells occurs
around epithelial proliferation
at certain sites on the labial
surface of the dental lamina.
Each site represents one of the
deciduous teeth.
From this point tooth
development proceeds in 3
stages describing the
morphology of the developing
tooth germ: Bud, Cap & Bell.
2-Bud stage
The cells of the dental lamina
proliferates on the labial side of
dental lamina forming rounded
buds called the dental or enamel
organ.
The ectomesenchyme condenses
below the enamel organ & is called
the dental papilla.
The ectomesenchyme that encircle
both the enamel organ & the
dental papilla is called dental sac
The cells of the dental lamina
proliferates on the labial side of
dental lamina forming rounded
buds called the dental or enamel
organ.
The ectomesenchyme condenses
below the enamel organ & is called
the dental papilla.
The ectomesenchyme that encircle
both the enamel organ & the
dental papilla is called dental sac
22--BUD STAGE BUD STAGE (a(at 8- WIUt 8- WIU((
DENTAL
ORGAN
DENTAL
PAPILLA
DENTAL SAC
TOOTH
GERM
DENTAL
ORGAN
DENTAL
PAPILLA
DENTAL SAC
TOOTH
GERM
The vestibular lamina is
formed as ectodermal
proliferation in the
underlying
ectomesenchyme buccal
to the dental lamina.
Epithelial degeneration
occurs inside the
vestibular lamina to
form the oral vestibule
separating the cheek &
lip from the teeth
bearing area.
Oral
vestibule
Teeth buds
formed as ectodermal
proliferation in the
underlying
ectomesenchyme buccal
to the dental lamina.
Epithelial degeneration
occurs inside the
vestibular lamina to
form the oral vestibule
separating the cheek &
lip from the teeth
bearing area.
Oral
vestibule
Teeth buds
Differential growth
results in increase in the
size of the enamel organ
& change in its shape to
exhibit a cap shape with
short & broad connection
to the dental lamina.
The cap- shaped enamel
organ has a convex outer
surface & concave inner
surface.
Cap stage
results in increase in the
size of the enamel organ
& change in its shape to
exhibit a cap shape with
short & broad connection
to the dental lamina.
The cap- shaped enamel
organ has a convex outer
surface & concave inner
surface.
Cap stage
33--CAP STAGECAP STAGE
TOOTH
GERM At 9-10 WIU
1-
DENTAL
ORGAN
2- DENTAL
PAPILLA
3-
DENTAL
SAC
TOOTH
GERM At 9-10 WIU
1-
DENTAL
ORGAN
2- DENTAL
PAPILLA
3-
DENTAL
SAC
Cap stageCap stage
1- Outer enamel epithelium:
A single layer of cuboidal cells with
deeply stained rounded nuclei arranged
on the convex surface of the enamel
organ
2- Inner enamel epithelium:
A single layer of columnar cells with
deeply stained rounded nuclei arranged
on the concave surface of the enamel
organ.
A basement membrane separates the
inner & outer enamel epithelia from the
dental papilla & the dental sac
respectively.
1- Outer enamel epithelium:
A single layer of cuboidal cells with
deeply stained rounded nuclei arranged
on the convex surface of the enamel
organ
2- Inner enamel epithelium:
A single layer of columnar cells with
deeply stained rounded nuclei arranged
on the concave surface of the enamel
organ.
A basement membrane separates the
inner & outer enamel epithelia from the
dental papilla & the dental sac
respectively.
Cap stageCap stage
3- Stellate reticulum:
Star shaped cells with long processes
anastomse with each other by desmosomes.
4- Enamel Knot:
A condensation of ectodermal cells in the
central region of the inner enamel
epithelium that may bulge towards the
dental papilla.
It extends towards the outer enamel
epithelium forming a strand of cells
(Enamel cord).
They are both transient structures
They may have a role in determining the
cusp position in molars, or may give the
stratum intermedium in the bell stage
3- Stellate reticulum:
Star shaped cells with long processes
anastomse with each other by desmosomes.
4- Enamel Knot:
A condensation of ectodermal cells in the
central region of the inner enamel
epithelium that may bulge towards the
dental papilla.
It extends towards the outer enamel
epithelium forming a strand of cells
(Enamel cord).
They are both transient structures
They may have a role in determining the
cusp position in molars, or may give the
stratum intermedium in the bell stage
33( ( CAP STAGECAP STAGE
Enamel knot
Inner D. E.
Outer D. E.
Stellate R.
Enamel cord
Dental Papilla.
Dental Sac
Enamel knot
Inner D. E.
Outer D. E.
Stellate R.
Enamel cord
Dental Papilla.
Dental Sac
The bell stage
Differential growth accompanied by
Histodifferentiation &
Morphodifferentiation leads to increase
in size & shape of the enamel organ to
exhibit a bell shape.
It is divided into:
Early bell stage: before any hard tissue
formation
Advanced or late bell stage: which
begins by formation of the first layer of
dentin.
Differential growth accompanied by
Histodifferentiation &
Morphodifferentiation leads to increase
in size & shape of the enamel organ to
exhibit a bell shape.
It is divided into:
Early bell stage: before any hard tissue
formation
Advanced or late bell stage: which
begins by formation of the first layer of
dentin.
44--Early bell stageEarly bell stage
At 11-12 WIU
1- The dental lamina:
*Break up of the dental lamina
by mesenchymal invasion divides
it into:
Main dental lamina:
(carrying permanent successors)
Lateral dental lamina : which
become long & narrow
connecting the E. Org. of
deciduous teeth to the main
dental lamina.
At 11-12 WIU
1- The dental lamina:
*Break up of the dental lamina
by mesenchymal invasion divides
it into:
Main dental lamina:
(carrying permanent successors)
Lateral dental lamina : which
become long & narrow
connecting the E. Org. of
deciduous teeth to the main
dental lamina.
Early bell stageEarly bell stage
2- The enamel organ:
* The outer enamel
epithelium:
the cells decrease in
height & become low
cuboidal.
2- The enamel organ:
* The outer enamel
epithelium:
the cells decrease in
height & become low
cuboidal.
Early bell Early bell
stagestage
* The inner enamel epithelium:
(IEE) (Preameloblasts)
* The columnar cells elongate towards
the dental papilla at the expense of the
cell free zone to exhibit 40 microns length
& be on contact with the un-differentiated
M Cs. of the dental papilla causing an
organizing influence on them to
differentiate into Odontoblasts a process
called induction.
*They show alteration in functional
polarity in which the nucleus &
mitochondria migrate towards the
proximal end while the Golgi &
centerioles migrate towards the distal end.
stagestage
* The inner enamel epithelium:
(IEE) (Preameloblasts)
* The columnar cells elongate towards
the dental papilla at the expense of the
cell free zone to exhibit 40 microns length
& be on contact with the un-differentiated
M Cs. of the dental papilla causing an
organizing influence on them to
differentiate into Odontoblasts a process
called induction.
*They show alteration in functional
polarity in which the nucleus &
mitochondria migrate towards the
proximal end while the Golgi &
centerioles migrate towards the distal end.
* Cervical loop:
The outer & inner enamel
epithelium meet at the cervical
part of the enamel organ
The inner enamel epithelium
reflects on the outer E.E. for a
short distance.
It may contain small amount
of stellate reticulum.(rare)
The outer & inner enamel
epithelium meet at the cervical
part of the enamel organ
The inner enamel epithelium
reflects on the outer E.E. for a
short distance.
It may contain small amount
of stellate reticulum.(rare)
•The stellate reticulum:
* The star shaped cells of the st.
reticulum are connected to each
other, to the cells of the O.E.E. &
to the st. interm. by desmosomes
* The glucosaminoglycans are
hydrophilic & attract water into
the center of the enamel organ to
keep space for the developing
enamel.
Early bell stage
* The star shaped cells of the st.
reticulum are connected to each
other, to the cells of the O.E.E. &
to the st. interm. by desmosomes
* The glucosaminoglycans are
hydrophilic & attract water into
the center of the enamel organ to
keep space for the developing
enamel.
Early bell stage
Stratum intermedium
* 2-3 layers of flat cells between
inner E.E. & the stellate reticulum
& are connected to both of them
by desmosomes
* they are rich in alkaline
phosphatase enzyme essential for
enamel mineralization.
*With the ameloblasts, they are
considered as a functional unit in
enamel formation &
mineralization.
* They control fluid diffusion into
& out of the ameloblasts.
Early bell stage
* 2-3 layers of flat cells between
inner E.E. & the stellate reticulum
& are connected to both of them
by desmosomes
* they are rich in alkaline
phosphatase enzyme essential for
enamel mineralization.
*With the ameloblasts, they are
considered as a functional unit in
enamel formation &
mineralization.
* They control fluid diffusion into
& out of the ameloblasts.
Early bell stage
44--Early bell stageEarly bell stage
Cervical
loop
At 11-12 WIU
ODE
Preameloblasts
Stratum
Intermedium
Stellate
Reticulum
Cervical
loop
At 11-12 WIU
ODE
Preameloblasts
Stratum
Intermedium
Stellate
Reticulum
44--Early bell stageEarly bell stage
Dental
papilla
At 11-12 WIU
Odontoblasts
Dental sac
Dental
papilla
At 11-12 WIU
Odontoblasts
Dental sac
Inner Enamel Epithelium
Odontoblasts
Dental Sac
44--Early bell stageEarly bell stage
Odontoblasts
Dental Sac
44--Early bell stageEarly bell stage
44--Early bell stageEarly bell stage
SR
SI
Preameloblast
OB
DP
SR
SI
Preameloblast
OB
DP
44--Early bell stageEarly bell stage
SUCCESSIONAL LAMINASUCCESSIONAL LAMINA
DENTAL LAMINA
PROPER
LATERAL DENTAL LAMINA
SUCCESSIONAL
LAMINA
Dental Organ
SUCCESSOR
PRIMORDIUM
DENTAL LAMINA
PROPER
LATERAL DENTAL LAMINA
SUCCESSIONAL
LAMINA
Dental Organ
SUCCESSOR
PRIMORDIUM
Dentin Matrix FormationDentin Matrix Formation
Odontoblasts differentiation Early dentin formation
Odontoblasts differentiation Early dentin formation
5-Advanced (Late) bell stage
The Advanced Bell Stage
Deposition of the first layer of
dentin by the differentiated
odontoblasts, causes many
changes in the different layers of
the tooth germ:
1- The lateral dental lamina:
breaks up into islands of
epithelial cells called Serres
pearls or epith. Rests of Serrs
which separates the developing
tooth from the oral epith.
Deposition of the first layer of
dentin by the differentiated
odontoblasts, causes many
changes in the different layers of
the tooth germ:
1- The lateral dental lamina:
breaks up into islands of
epithelial cells called Serres
pearls or epith. Rests of Serrs
which separates the developing
tooth from the oral epith.
2- The outer enamel
epithelium:
Formation of dentin breaks up
the nutrition coming via the
dental papilla. Therefore:
* Folding of the outer E.E. will
increase the surface area for
increased nutrition.
The vascular inner layer of the
dental sac brings its Capillary
loops very close to the cells of the
enamel organ, providing it with a
rich source of nutrition.
* The cells of the outer E.E.
become flat, develop microvilli
& show increased mitochondria
epithelium:
Formation of dentin breaks up
the nutrition coming via the
dental papilla. Therefore:
* Folding of the outer E.E. will
increase the surface area for
increased nutrition.
The vascular inner layer of the
dental sac brings its Capillary
loops very close to the cells of the
enamel organ, providing it with a
rich source of nutrition.
* The cells of the outer E.E.
become flat, develop microvilli
& show increased mitochondria
The Advanced bell stage
3-The inner E.E. (Ameloblasts):
* The newly formed dentin exerts an influence on the inner enamel
epithelium to differentiate into ameloblasts, a process called reciprocal
induction.
* The ameloblasts are 40 microns in length & 4-5 microns in diameter
& in cross section they are hexagonal in shape. They are attached to
each other by junctional complexes & to the stratum intermedium by
desmosomes.
3-The inner E.E. (Ameloblasts):
* The newly formed dentin exerts an influence on the inner enamel
epithelium to differentiate into ameloblasts, a process called reciprocal
induction.
* The ameloblasts are 40 microns in length & 4-5 microns in diameter
& in cross section they are hexagonal in shape. They are attached to
each other by junctional complexes & to the stratum intermedium by
desmosomes.
4-Stellate reticulum:
Undergo shrinkage
The intercellular fluid is utilized in
nutrition & the space is utilized by
the formed enamel
5-Stratum intermedium:
*Its cells show high alkaline
phosphatese enzyme
activity that is important
for enamel mineralization.
Undergo shrinkage
The intercellular fluid is utilized in
nutrition & the space is utilized by
the formed enamel
5-Stratum intermedium:
*Its cells show high alkaline
phosphatese enzyme
activity that is important
for enamel mineralization.
55--Advanced (Late) bell stageAdvanced (Late) bell stage
STRATUM
INTER.
STELLATE
RETICULUM
PREDENTIN
ODONTOBLASTS
AMELOBLAST
STRATUM
INTER.
STELLATE
RETICULUM
PREDENTIN
ODONTOBLASTS
AMELOBLAST
ENAMEL
MATRIX
DENTIN
PREDENTIN
OUTER DENTAL
EPITHELIUM
CAPILLARY LOOP
SR
AB
SI
5-Advanced (Late) bell stage
MATRIX
DENTIN
PREDENTIN
OUTER DENTAL
EPITHELIUM
CAPILLARY LOOP
SR
AB
SI
5-Advanced (Late) bell stage
Dental
papilla
OB
PD
D
E matrix
SR
SI
AB
5-Advanced (Late) bell Stage
papilla
OB
PD
D
E matrix
SR
SI
AB
5-Advanced (Late) bell Stage
DENTAL LAMINADENTAL LAMINA
VESTIBULAR
LAMINA
VESTIBULAR
LAMINA
Stages of tooth development are also
described according to physiologic changes
& function during development & are
called histophysiological stages.
These include:
1- Initiation 2- Proliferation
3- Histodifferentiation
4- Morphodifferentiation
5- Apposition
described according to physiologic changes
& function during development & are
called histophysiological stages.
These include:
1- Initiation 2- Proliferation
3- Histodifferentiation
4- Morphodifferentiation
5- Apposition
Root FormationRoot Formation
Cervical loop
Hertwig’s epith.
root sheath
Odontoblast
differentiation
Dentin formation
Disintegration
of root sheath
Cementoblast
differentiation
Cervical loop
Hertwig’s epith.
root sheath
Odontoblast
differentiation
Dentin formation
Disintegration
of root sheath
Cementoblast
differentiation
Root formation
Begins when the enamel & dentin
formation reaches the future
cemento-enamel junction.
The epithelial cells of inner & outer
enamel epithelium proliferate from
the cervical loop to form a double
epith. membrane known as
Epithelial root sheath of Hertwig.
* It bends forming obtuse angle to
the enamel organ at the future
cemento-enamel junction to form the
epithelial diaphragm.
Begins when the enamel & dentin
formation reaches the future
cemento-enamel junction.
The epithelial cells of inner & outer
enamel epithelium proliferate from
the cervical loop to form a double
epith. membrane known as
Epithelial root sheath of Hertwig.
* It bends forming obtuse angle to
the enamel organ at the future
cemento-enamel junction to form the
epithelial diaphragm.
Root formation
* The inner enamel epithelium in the epithelial
root sheath of Hertwig, will induce U.D.M.Cs of
the dental papilla to differentiate into
Odontoblas which form the 1
st
layer of root
dentin.
* The Epithelial root sheath of Hertwig
degenerates forming epithelial rests of Mallassez
* The formed dentin that come in contact with
the dental follicle, induces the differentiation of
U.M.Cs. in the dental follicle in to
cementoblasts which lay down cementum.
* This occurs in the formation of single rooted
tooth.
Proliferation zone
cementoblasts
* The inner enamel epithelium in the epithelial
root sheath of Hertwig, will induce U.D.M.Cs of
the dental papilla to differentiate into
Odontoblas which form the 1
st
layer of root
dentin.
* The Epithelial root sheath of Hertwig
degenerates forming epithelial rests of Mallassez
* The formed dentin that come in contact with
the dental follicle, induces the differentiation of
U.M.Cs. in the dental follicle in to
cementoblasts which lay down cementum.
* This occurs in the formation of single rooted
tooth.
Proliferation zone
cementoblasts
Cervical loop
Hertwig’s epith.
root sheath
Hertwig’s epith.
root sheath
Odontoblast
differentiation
differentiation
Dentin formation
Disintegration
of root sheath
Cementoblast
differentiation
Disintegration
of root sheath
Cementoblast
differentiation
EPITHELIAL DIAPHRAGMEPITHELIAL DIAPHRAGM
Epithelial diaphragm
NEWLY FORMED ROOTNEWLY FORMED ROOT
MULTI-ROOTED TOOTHMULTI-ROOTED TOOTH
Formation of multi- rooted teeth
* The root trunk of molars is formed like single rooted tooth.
* At the bifurcation area, the epithelial diaphragm produces 2 or 3
tongue- like processes in case of 2 rooted & 3 rooted teeth.
* The processes grow towards each other & fuse dividing the wide root
trunk into 2 or 3 roots.
* Each one of these roots proceeds in development as in single rooted
tooth.
* The root trunk of molars is formed like single rooted tooth.
* At the bifurcation area, the epithelial diaphragm produces 2 or 3
tongue- like processes in case of 2 rooted & 3 rooted teeth.
* The processes grow towards each other & fuse dividing the wide root
trunk into 2 or 3 roots.
* Each one of these roots proceeds in development as in single rooted
tooth.
MULTI-ROOTED TOOTHMULTI-ROOTED TOOTH
Clinical consideration
Formation of accessory root canals :
Causes: 1) When the Hertwig’s epithelial root sheath looses its
continuity before odontoblastic differentiation & dentin formation.
2) Failure in fusion of the tongue –like processes of the epithelial
diaphragm in the pulpal floor.
3) If a large blood vessel is present and disturb the continuity of the
epithelial root sheath.
* If the continuity of the epithelial root sheath of Hertwig is broken
after odontoblastic differentiation & before dentin formation,
intermediate cementum will be deposited.
* if the epithelial root sheath of Hertwig remains adherent to the
dentin surface, its inner cells may differentiate into ameloblasts &
produce enamel, known as Enamel pearls.
Formation of accessory root canals :
Causes: 1) When the Hertwig’s epithelial root sheath looses its
continuity before odontoblastic differentiation & dentin formation.
2) Failure in fusion of the tongue –like processes of the epithelial
diaphragm in the pulpal floor.
3) If a large blood vessel is present and disturb the continuity of the
epithelial root sheath.
* If the continuity of the epithelial root sheath of Hertwig is broken
after odontoblastic differentiation & before dentin formation,
intermediate cementum will be deposited.
* if the epithelial root sheath of Hertwig remains adherent to the
dentin surface, its inner cells may differentiate into ameloblasts &
produce enamel, known as Enamel pearls.
ENAMEL PEARLENAMEL PEARL
ENAMEL PEARL
ENAMEL PEARL
Test yourselfTest yourself
Stellate reticulum
Stratum intermedium
Ameloblasts
Enamel matrix
Dentin
Predentin
Odontoblasts
Dental papilla
Stellate reticulum
Stratum intermedium
Ameloblasts
Enamel matrix
Dentin
Predentin
Odontoblasts
Dental papilla
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