Oral Biology I - Enamel PDF

Summary

This document is a lecture on the life cycle of ameloblast and the stages of enamel formation. It details the different stages, including the morphogenic, differentiation, synthesis, transitional, and maturative stages. It also covers the role of the Golgi complex, mitochondria, and endoplasmic reticulum in these stages. The document is about dental care and oral biology.

Full Transcript

Faculty of Dentistry
Oral Biology I

Life cycle of Ameloblast
I. Morphogenic stage
 At the early bell stage
 The IEE is Low columnar resting on basement membrane that
separates them from the cell free zone of dental papilla.
 Electron Microscopic Picture (E\M)
▪ Large nucleus that almost fills the
cell body.
▪ The Golgi apparatus and centrioles
are in the proximal end of the cell
(adjacent to the SI).
▪ Mitochondria are evenly scattered
throughout the cytoplasm.
▪ The cells have proximal junctional complex
II. Differentiation or Organizing stage
 At the late bell stage
 Pre- ameloblast cells (still undergoing
differentiation)
 No mitotic activity is detected
 The cells elongate to reach 40 microns
 Electron Microscopic Picture (E\M)
▪ The nuclei shift proximally towards
the stratum intermedium.
▪ The Golgi apparatus or complex increases its volume
and migrate from proximal position to distal end.
▪ Mitochondria cluster in the proximal end.

Enamel Menatalla M. Elhindawy
 Faculty of Dentistry
Oral Biology I
▪ The amount of rough endoplasmic reticulum (rER)
increases significantly.
 In this stage the ameloblast becomes a
polarized cell.
III. Synthesis, Secretory, Formative stage
 At the late bell stage and developing tooth
 Ameloblast cells have no mitotic activity
 Basement membrane disintegrated and
ameloblast is now in contact with first formed
layer of dentin and ameloblast is now fully
differentiated.
 E\M
▪ Golgi complex is condensed and developed occupying
the central part of the cell
▪ Mitochondria is still in the same position
▪ rER increased in number
▪ The cells developed distal junctional complex
 The first layer of enamel is formed with crystals randomly
oriented
 Ameloblasts migrate away from dentine surface which
permits the formation of Tomes’ process.
 Tome’s process
 Extension of the ameloblast
 Marked from the cell body by distal junctional complex.
 It contains primarily secretory granules and small
vesicles only with no cell organelles.
 The process is now embedded in a pit

Enamel Menatalla M. Elhindawy
 Faculty of Dentistry
Oral Biology I
 It creates a saw tooth appearance with the enamel
surface.
 Secretion of enamel is confined to two sites
1. Proximal end (close to the distal junctional
complex of the ameloblast) it forms the pit’s wall,
(inter rod).
2. Distal end, it forms the pit itself (enamel rod).
 This explains why the crystal orientation and direction
in the inter rod differs from those of the rod.
 The Tomes’ processes create the unique structure of
enamel and persist until just before the final few
increments at the surface are formed.
IV. Transitional stage
 During this stage the following events take place:
 Withdrawal of Tomes’ processes, reduction in the height
of the ameloblasts and decrease in its volume and
organelle content.
 The outermost layer of enamel is formed with randomly
arranged crystals
V. Maturative stage
 Enamel maturation (full mineralization) occurs after most of the
thickness of the enamel matrix has been formed in the occlusal
or incisal area.
 During maturative stage ameloblast display two forms
 Smooth border ameloblast, it is associated with removal
of protein and water, these ameloblasts have distal leaky
junction.

Enamel Menatalla M. Elhindawy
 Faculty of Dentistry
Oral Biology I
 Ruffled border ameloblast, it displays microvilli at their
distal extremities. This form is associated with
introduction of inorganic materials, these ameloblasts
have distal tight junctional

VI. Protective stage
 When the enamel has completely developed and fully
calcified, the ameloblasts secrete a material
between distal ends of cells and the enamel
surface identical to basal lamina
(Hemidesmosomes) providing a firm
attachment for ameloblasts and enamel
surface.
 Ameloblasts can’t be differentiated from the cells of the
stratum intermedium, stellate reticulum and outer enamel
epithelium forming reduced enamel epithelium (REE).
 The function of the REE is that of protecting the mature
enamel by separating it from the connective tissue until the
tooth erupts.

Enamel Menatalla M. Elhindawy
 Faculty of Dentistry
Oral Biology I
 If the connective tissue meets the enamel may be either
resorbed or covered by a layer of cementum
VII. Desmolytic stage
 The REE seems to induce atrophy of
the connective tissue separating it
from the oral epithelium as pathway
for tooth eruption. So, teeth erupt
without bleeding.
 Premature degeneration of the REE may prevent the eruption
of a tooth.

Amelogenesis process
 Two processes are involved in amelogenesis
▪ Matrix formation.
▪ Mineralization.
 Keep in mind the following
▪ Enamel mineralization doesn't wait for complete matrix
formation.
▪ No clear cut between matrix formation and mineralization.

▪ Matrix formation and mineralization take place almost at the
same time & crystals appear almost immediately in newly
secreted matrix.

Enamel Menatalla M. Elhindawy
 Faculty of Dentistry
Oral Biology I
A. Enamel matrix formation
Synthesis of enamel protein occurs in rER, where it passes to
the Golgi complex in which it is condensed, a polysaccharide
fraction is added and packed into
membrane bound secretory granules.
These granules migrate to the distal
extremity of the cell and contents are
released against the newly formed
dentine.
After the first formed layer of enamel
the ameloblasts move outward away
from dentine surface to allow space for more secretion of
matrix.
As enough enamel matrix is deposited, the ameloblasts
develop Tomes’ processes into the forming matrix, through
which further matrix is deposited. The ameloblast interface
has a saw-like shape.
Tome’s process controls the direction of crystal orientation
through two regions: distal end and proximal.
Crystal has a perpendicular direction on the membrane of
Tome’s process.
This orientation gives the unite structure of enamel, rod and
inter rod substance (proximal end gives inter rod; distal end
gives rod).

Enamel Menatalla M. Elhindawy
 Faculty of Dentistry
Oral Biology I
B. Mineralization
o Immediate partial mineralization
It occurs while matrix is laid down, which may account for
25% to 30% of the ultimate mineral content of enamel.
o Full mineralization
Once the full width of this enamel has been laid down,
enamel second maturation begins involving significant influx
of additional mineral coincidence to reach 96% with the
removal of organic material and water
o Mineralization starts from the height of the crown and
progresses cervically.

Enamel Menatalla M. Elhindawy