DENT 112 LEC | Oral Histology Enamel Lesson 3 PDF

Summary

This document is a lecture on the enamel of teeth. It describes the physical and chemical properties of enamel, as well as its microscopic structures. It explains amelogenesis, clinical considerations, and important references for the topic. The document is for students in the 1st semester of a dental program for the academic year 2024-2025.

Full Transcript

DENT 112 LEC | ORAL HISTOLOGY
LESSON 3: ENAMEL
DR. EZEKIEL S. MAJAN
1ST SEMESTER A.Y. 2024-2025

OUTLINE Translucent Color of teeth is from dentin
Cervical area has thinner enamel —
ENAMEL appears more yellow (reflects more
1. PHYSICAL PROPERTIES dentin)
2. CHEMICAL COMPOSITION Color can also be affected by:
3. MICROSCOPIC STRUCTURES ○ Age — enamel abrades over time,
3.1. Enamel Prisms/Enamel Rod more of the yellow dentin is seen
3.1.1. Interrod Cementing
○ Diet — enamel is semi-permeable,
Substance/Interprismatic Substance
3.1.2. Prism Sheath/Rod Sheath color of food may stick
3.2. Hunter-Schreger Bands
3.3. Incremental Lines of Retzius
3.4. Structureless/Prismless Enamel
3.5. Perikymata/Imbrication Line of Pickerill
3.6. Neonatal Line/Ring
3.7. Enamel Cuticle/Nasmyth’s Membrane

3.8. Enamel Lamellae
Patients of Dr. Zeke
3.9. Enamel Tufts
3.10. Enamel Spindles In the cervical area, the color is more yellow
3.11. Scalloped DEJ showing that the enamel is quite thin
4. AMELOGENESIS Naturally yellow teeth + drinks coffee often
4.1. Functional Stages
4.1.1. Pre-secretory Permeable to TFA (Topical Fluoride Application) can
4.1.2. Secretory certain ions make enamel more resistant to caries
4.1.2.1. Tome’s Process Permeability decreases with age
4.1.3. Maturation ○ Recommended fluoride
4.1.3.1. Mineralization
application to kids as that’s when
4.1.3.2. Protective
4.1.3.3. Desmolytic it is most permeable
5. CLINICAL CONSIDERATIONS
6. REFERENCES Soluble in Acid attacks from caries and acid
7. TEST BANKS acids etching in restorations begin with the
8. SUMMARY dissolution of the mineral part of
enamel, followed by the degradation of
ENAMEL the organic part
○ Before getting tooth fillings, they
put a blue na parang maasim,
1. PHYSICAL PROPERTIES
that’s acid etching

Hard, translucent tissue
covering the anatomical 2. CHEMICAL COMPOSITION
crowns of teeth
Acts as a protective The enamel is very calcified and has a high mineral
covering of the coronal content
dentin — resist forces of
mastication
Mature Enamel 96% Inorganic substance
Hardest calcified tissue
in the body ○ Crystalline calcium
Enamel phosphate, Hydroxyapatite
crystals
Varies in Thickest at the cusp tips, thinnest at the 4% Organic substance + Water
thickness cervical third ○ Proteins (amelogenins &
Incisal edge = 2 mm non-amelogenins like
Premolar cusps = 2.3-2.5 mm enamelin & ameloblastin)
Molar cusps = 2.5-3 mm (masticatory Largely inorganic
forces)
Developing 70% Enamel Proteins (organic)
Hardest Hard due to its high mineral content Enamel/Premature ○ 90% amelogenins
calcified Hardness decreases from enamel to DEJ Enamel ○ 10% non-amelogenins
tissue in the (dentino-enamel junction) (enamelin and
human body ○ As it goes towards the pulp/dentin, ameloblastin)
the hardness decreases 30% minerals (inorganic)
Brittle and Prone to fracture if not supported by More organic
Inelastic sound dentin (Likened to glass)

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3. MICROSCOPIC STRUCTURES

GROUND SECTION DECALCIFIED

Inorganic substance Organic substance
remains remains
Organic is burnt Inorganic substance is
dissolved

→ Enamel and dentin → Pulp, dentin, cementum

In Cross Section:
Rods appear hexagonal,
oval or round, or
resemble a fish scale
Has a head and a tail that
resembles a
keyhole/paddle
However, fully mature
enamel are no longer
perfectly hexagonal
3.1. ENAMEL PRISMS / ENAMEL RODS
because enamel rods
press against each other
Fundamental organizational units of enamel are:
causing them to lose their
○ Enamel prism/rods
geometry
○ Interrod enamel/interprismatic substance
Basic structural unit of enamel formed by ameloblasts
In Longitudinal Section:
Long slender structures with roughly 5 or 6 sides
It has a segmented
appearance and dark lines
crossing the rod called
“Cross Striations”
These Cross Striations
represent the daily
appositional growth of
the enamel rods
Intervals between cross
striations: 5µ

Alternating constrictions & expansions of the rods in some
Shaped like a cylinder &
regions of enamel which may account for this banded
are made up of crystals
appearance in ground section
with long axes that run in
the general direction of The appearance could also result from structural
the longitudinal axis of interrelations among groups of rods rather than
the rod modification of a single rod
Built from closely packed
& long ribbon-like
hydroxyapatite crystals

One enamel rod is
surrounded with millions
of Hydroxyapatite
crystals
○ 60-70 nm in width
○ 25-30 nm in
thickness
The length spans ALMOST
the entire enamel
thickness Number of enamel rods can range from:
Extending from DEJ to the ○ Around 5 million (lower lateral incisors)
surface in a wavy course &
○ To 12 million (upper first molars)
oblique direction
In deciduous teeth, enamel rods are generally oriented
Since it is wavy = Length
occlusally/coronally
of rods > Thickness of
enamel

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In mature enamel, the rods 3.1.2. PRISM SHEATH / ROD SHEATH
are oriented at right
angles to the DEJ Outermost portion of the rod; takes stain easily because
Pits & Fissures: Tent-like it is more organic
manner Narrow space serving as the boundary between rod and
Proximal: Horizontal interrod enamel
Cervical: Oblique Contains organic material
○ Permanent: face
apically
○ Primary: face
coronally

3.2. HUNTER-SCHREGER BANDS

Alternating light and dark bands originating from the DEJ
towards surface (inner ⅘)
Caused by different directions of rods/crisscrossing of
rods
Seen in longitudinal ground section but under oblique
reflected light/polarized light
In cusps & incisal edges, there are bundles of rods
○ Under the microscope, these may or may
intertwining irregularly from DEJ, straightens as it reaches
not be seen, depending on how the slides
the surface of enamel called “Gnarled Enamel”
are prepared
The gnarled enamel offer the greatest resistance to
A manifestation of the crisscrossing of rods
cusps & incisal edges
Black arrow - Gnarled Enamel
3.1.1. INTERROD CEMENTING SUBSTANCE /
Red Arrow - Hunter-Schreger
INTERPRISMATIC SUBSTANCE
Bands (alternating dark & light
bands
Substance that cements rods
together
○ In between the rods
1µ thick
Formed by the proximal part
of the Tome’s process of
ameloblasts

3.3. INCREMENTAL LINES / STRIAE OF RETZIUS
Surround each rod & its crystals are oriented in a direction
different from those making up the rod Brownish bands illustrating the incremental pattern of
Rods and interrods have the same composition, just enamel/successive apposition of layers of enamel
different orientations Longitudinal section: Surround tip of dentin

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○ Cervical parts - run obliquely from DEJ to surface 3.4. STRUCTURELESS / PRISMLESS ENAMEL
occlusally
Cross section: Appear as concentric dark lines (like No prisms outlines visible
growth rings of a tree) 30μ thick
Found in: 10 (primary) teeth and cervical region of 20
(Polarized, longitudinal section) (permanent) teeth
Apatite crystals parallel to one another; perpendicular to
*Shows the incremental lines Striae of Retzius
of apposition More heavily mineralized than bulk of enamel beneath it
Visible in scanning microscopy (not detectable in light
microscopy)
Found in:
○ Innermost enamel (contains rods)
○ Outermost enamel (worn-off/abraded in mature
teeth)

(Cross-section)

Black triangles - Incremental
Lines of Retzius

*Appear as concentric lines

A (OBLIQUE lines) -
Incremental lines of
Retzius 3.5. PERIKYMATA / IMBRICATION LINE OF PICKERILL
Enamel Prisms (they
form right angles with the Transverse, wavelike grooves
dentin) Believed to be the External manifestation of Striae of
B - DEJ Retzius
C - Dentin Parallel to one another and CEJ
~10 perikymata/mm – occlusal/incisal
Periodic bending of enamel rods ○ Seen with bare eyes (Macroscopic)
Variation in basic organic structure ~30/mm – CEJ
Physiologic calcification rhythm
○ = periods of enamel matrix formation and of rests
20-80µm apart; 4-15µm in width

Surrounds the tip of the
dentin
Cervically - runs obliquely

3.6. NEONATAL LINE / RING
(Longitudinal section)
Accentuated Incremental Line of Retzius
Yellow arrow - enamel
separating/differentiating prenatally developed enamel
prisms/rod
from postnatal enamel
Yellow lines - Cross striations
Believed to be the result of abrupt changes in environment
White arrows - Incremental
and nutrition of newborn infant
lines of Retzius
○ The difference in environment and nutrition is
seen in the development of the enamel after birth

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The dark band is the 3.9. ENAMEL TUFTS
neonatal line/ring
It’s an accentuated ALWAYS originates from the DEJ
incremental line of Retzius 1/3 to 1/5 of entire enamel thickness
Separates prenatal and Filled with protein and organic material
postnatal enamel Believed to occur developmentally due to abrupt changes
○ [A] prenatal enamel in the direction of rod groups originating from the DEJ.
○ [B] postnatal enamel
“Tuft” –
resembles
blades of grass
attached to a
parent stem
Longitudinal Ground section in
polarized light

Narrow,
ribbon-like
structure
composed of
bundles of
poorly calcified
rods & interrod
cementing
substance
3.7. ENAMEL CUTICLE / NASMYTH’S MEMBRANE

Delicate membrane that covers the entire crown of a
newly erupted tooth
Protects your tooth
Shortly removed by mastication
○ Erupted teeth are covered by precipitates of
salivary proteins called PELLICLE
-> may be colonized by bacteria & food debris
-> once pellicle is colonized by bacteria, it
forms PLAQUE
-> once plaque calcifies, it becomes CALCULUS
-> pellicle reforms within hours after mechanical Ground Section of the Enamel
cleaning

3.8. ENAMEL LAMELLAE ENAMEL LAMELLAE = originates from the SURFACE
ENAMEL TUFTS = originates from the DEJ
Cracks in the enamel
ALWAYS originates from the SURFACE
Leaf-like structural defects 3.10. ENAMEL SPINDLES
Filled with enamel protein or organic debris from the oral
cavity -> possible avenue for dental caries Club-shaped extensions/projections of dentinal
tubules/odontoblastic processes in enamel
Consists of linear, Part of the dentin that penetrate the enamel
longitudinally oriented May contain a living process of the odontoblast
defects contributing to the vitality of the DEJ (extensions of dentin)

Smaller
than
enamel
tufts,
singular

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Randomly RECALL
distributed
in coronal & Advanced Bell Stage
sagittal Successional lamina seen above
sections blue arrow
Outer Enamel Epithelium
Stellate Reticulum
Inner Enamel Epithelium
Stratum Intermedium

2 PHASES: PROCESS OF DEVELOPMENT OF THE ENAMEL

Enamel Matrix When enamel first forms, it
Formation/Formative mineralizes only partially to
Phase approximately 30%
Enamel is ECTODERMAL in origin
Enamel Spindles ARE NOT
Mineralization or As the organic matrix breaks
○ They are projections of DENTINAL TUBULES.
Maturation Phase down and is removed, crystals
Dentin is MESODERMAL in origin
grow wider and thicker
Organic materials & water lost;
mineral added after full thickness
3.11. SCALLOPED DEJ of enamel layer has been formed
to attain 96% mineral content
Dentin surface on crown, they are shallow depressions/pits
where enamel caps are fitted CHEMICAL COMPOSITION OF ENAMEL
Firm attachment of enamel to dentin surface (scalloped for Developing Enamel/Premature Enamel
increased surface area & adhesion) ○ 70% Enamel Proteins
90% amelogenins
Concavity is
10% non-amelogenins (enamelin and
facing the
ameloblastin)
enamel
○ 30% Minerals
Immediate partial mineralization on
Convexity is
the first increment of enamel
facing the
dentin
4.1. FUNCTIONAL STAGES
Pacman eats the enamel :)

Ground section - “enamel space” because it is decalcified

A. Enamel Tufts
(t for tall)
B. Enamel
Spindles
(s for short)
C. Enamel
Lamellae
D. Dentin
E. Enamel
↑ DEJ

Life Cycle of an Ameloblast
4. AMELOGENESIS
3 MAIN FUNCTION STAGES + 6 FUNCTIONAL STAGES:
AMELOBLAST
Presecretory
Cells responsible for enamel formation
1. Morphogenetic
Derived from inner enamel epithelium of the enamel
2. Histodifferentiation
organ
Secretory/Formative
Ameloblast secrete matrix proteins & are responsible
3. Initial secretory + secretory
for creating & maintaining an extracellular environment
Maturation
favorable for mineral deposition
4. Ruffle ended ameloblast maturation
Ameloblast has a unique life cycle in the formation of
(transition), Smooth ended ameloblast
enamel
maturation (modulation)
5. Protective (reduced)
6. Desmolytic

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4.1.1. PRE-SECRETORY innermost portion of the tooth

Differentiating ameloblasts:
○ Acquire phenotype
○ Change polarity
○ Develop an extensive protein synthetic
apparatus
○ Prepare to secrete the organic matrix

RECIPROCAL INDUCTION
The short columnar cells of IEE become tall columnar,
polarized cells known as pre-ameloblasts The first enamel that is laid down (you can
○ Polarized because the nuclei moves away to see it on the top portion) is NOT PART of
one side from the dental papilla the rod and interrod enamel
They then induce the peripheral cells of the dental
papilla to increase in size and become polarized and Secretory As the early secretory ameloblast
become odontoblasts Ameloblasts produces enamel, it forms a process ->
○ Peripheral cells move away from the enamel TOME’S PROCESS
organ ○ Polarized
Odontoblasts then lay down pre-dentin ○ Picket-fence or saw tooth appearance
Pre-dentin is mineralized to become dentin (mantle
dentin)
○ Pre-dentin sends signals to the pre-ameloblasts
This induces the pre-ameloblasts to become
ameloblasts, which are now ready to secrete enamel
protein matrices

Amelogenesis: Pre-secretory

4.1.2. SECRETORY
Secretions of enamel proteins become staggered and
The basal lamina disintegrates, forming the DEJ confined to 2 sites:
(dentino-enamel junction)
The cells of the IEE, now ameloblasts, begin to secrete Proximal Forms enamel partitions that delimit a pit
more actively enamel proteins that accumulate and Portion (creates a space)
immediately participate in the formation of a partially Not distinct units and form a continuum
mineralized (30%) initial layer of enamel that HAS NO throughout enamel -> INTERROD
RODS ENAMEL
As enamel is laid down, ameloblasts will move away
from the dental papilla Distal Secretions with matrix forms ENAMEL
Portion ROD that later fills the pit
○ Ameloblasts will then develop cytoplasmic
projections called TOME’S PROCESS

1.1.1.1. TOME’S PROCESS
Juts into and interdigitates with newly forming enamel
Gives ameloblasts a picket-fence or saw-toothed
appearance

The ROD & INTERROD CONFIGURATION of enamel crystals is
a property of the AMELOBLASTS & TOME’S PROCESS

Ameloblasts in their secretory stage
Early Ameloblasts initially looked like this The proximal portion of the Tome’s process will lay
Secretory No tome’s process present -> no rods -> down enamel matrix first, leaving a pit or space that
Ameloblasts structureless/prismless enamel in the will be filled out by the distal portion of the process

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○ Cells from SI, SR, and OEE fuse into 1 layer ->
○ Proximal -> INTERROD ENAMEL
blood vessels invaginate deeply into this layer
○ Distal -> ROD ENAMEL
to form a convoluted structure
Enamel rod and interrod enamel have identical
SI + SR + OEE = Papillary Layer
composition but differs only in orientation of their
Ameloblasts attach to enamel by means of
crystals
hemidesmosomes
○ Different crystal orientation of enamel gives
When enamel is fully mature -> mature ameloblasts and
increased resistance to fracture
papillary layer regress together
○ Ameloblasts + Papillary Layer = Reduced
Enamel Epithelium (REE)

The distal portion of Tome’s process
○ Lengthens as enamel thickens
○ Becomes thinner as the rod is growing in
diameter and presses it against the wall of the
interrod cavity Advanced bell stage
As it lays down more enamel, parang
kamay siya na nage-extend until it thins C - Stellate Reticulum
out since as more enamel is laid down, Before the IEE become ameloblasts, they get their
nap-press siya against the interrod blood supply from the dental papilla
enamel As enamel forms, the IEE moves away from the
○ As the distal Tome’s process disappears, a dental papilla because of dentin and enamel
narrow space is created along the IEE will then get blood supply from the oral
circumference between rod & interrod enamel epithelium -> stellate reticulum becomes thinner as
-> formation of the PRISM/ROD SHEATH enamel matures
The space that was formerly the distal D - Outer Enamel Epithelium
portion of the Tome’s process is filled E - Ameloblasts
by organic material and now it forms Produce enamel
the surrounding prism sheath G - Inner Enamel Epithelium

SI + SR + OEE = PAPILLARY LAYER
Papillary Layer + Mature Ameloblasts = REDUCED ENAMEL
EPITHELIUM

When enamel layers are formed, ameloblasts become
shorter and lose distal portion of Tome’s process but
they still continue to secrete enamel

-> Once the ameloblasts lose the Tome’s process and still secrete
enamel, will the outermost layer of enamel have rods?
NO, because there is no distal portion of the Tome’s
process that’s why the innermost and outermost Decalcified Section Preparation
enamel are prismless
Two Forms of Maturation (Ruffle or Smooth-Ended)
1.1.1. MATURATION
Ruffle-Ended Adds minerals to enamel
When full thickness of enamel is complete, ameloblasts Maturation
enter the maturation stage Stage
○ Post-secretory transition ameloblasts shorten
and restructure into maturation cells
(ruffle-ended or smooth-ended)

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Smooth-Ended Removes water and proteins from enters their system and can be incorporated into
Maturation enamel enamel during this maturation stage
Stage
4.1.3.3. DESMOLYTIC
After enamel and dentin reach the CEJ (crown
Protective Stage formation finishes) and root formation begins, cells of
Part of REE to protect the tooth
the REE produce enzymes that cause lysis of the
connective tissue (desmolysis) above it
RECALL: REE = OEE + SI + SR + ameloblasts
The REE then unites with the oral epithelium (OE) to
form the EPITHELIAL CUFF, where the tooth will pass
as it erupts
REE remains until tooth erupts
As tooth passes OE (or as it erupts),
○ INCISALLY: the part of REE joined with the OE
is destroyed
○ CERVICALLY: REE interacts with OE to become
the primary epithelial attachment and form the
JUNCTIONAL EPITHELIUM
Once the tooth erupts, the inner part of REE (made of
reduced ameloblasts) will lose its blood supply and die
○ Disappearance of REE -> formation of
GINGIVAL SULCUS

That’s why 30% becomes 96% minerals due to BLEEDING AND TOOTH ERUPTION
ruffle-ended and smooth-ended ameloblasts
Blood vessels can be found in connective tissues.
However, REE destroys CT as tooth erupts.
1.1.1.1. MINERALIZATION There are also no blood vessels in the epithelium;
hence, we don't bleed when our tooth is erupting.
First to mineralize - cusp tips
Last to mineralize - cervical areas, fissures, and bottom
of pits DIAGRAM *aralin daw to sabi ni sir

Primary and Secondary Calcification

1o Calcification Partial mineralization of the segments
of matrix as it reaches a certain
thickness
About 25-30% of mineral salts may be
deposited into the matrix

2o Calcification Gradual completion of the
mineralization where the rest of the
mineral contents are deposited by Completion of crown formation
ruffle-ended and smooth-ended A
Layers (bottom up): dentin, enamel, regressed REE
ameloblasts
REE produces enzymes that destroy connective
B, C, D
4.1.3.2. PROTECTIVE tissue above it, then merges with OE and forms cuff

REE continues to cover the tooth and has a protective E REE is destroyed incisally, but persists cervically
function
At this phase, the tooth has still not erupted and enamel Inner REE will disappear to form gingival sulcus
F
composition can still be modified observable at G
○ Fluoride*, if available, can still be incorporated
NOT topical (directly applied/ 5. CLINICAL CONSIDERATIONS
pinapahid), but systemic fluoride (e.g.
taken orally through tablets)
Since the tooth is unerupted! ENAMEL HYPOPLASIA & ENAMEL HYPOCALCIFICATION

SYSTEMIC FLUORIDE Hypoplasia – defective enamel matrix
Hypocalcification – defective enamel maturation
In the US, children take fluoridated water. Fluoride

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Maybe caused by: ATTRITION
S̀ystematic
○ Vitamin D Deficiency - Ca & Ph deposition Physiologic wearing
(Minerals found in enamel) away of teeth due to
Can even occur in the womb, if the mother has occlusion, diet and
Vitamin D deficiency mastication
○ Vitamin A Deficiency - Affects ectodermal tissues Physiologic – part of
(enamel); if severe = no enamel formation the teeth’s function
○ Febrile Illness - formation is disturbed that all
teeth is characterized by distinctive bands of
malformed enamel
As a kid is growing up, getting a fever can
affect enamel formation
○ Tetracycline Antibiotics - May also cause bands of ABRASION
brown pigmentation
Local Pathologic wearing
away of teeth through
○ Caused by very extensive carious lesion such that
an abnormal
2° successor is affected
mechanical process
causing severe loss of
CLINICAL SCENARIO:
tooth structure
A child has a febrile
Toothbrush abrasion –
illness
caused by brushing too
During the development
hard
of their teeth, they got
sick
SEEN: normal enamel +
zone of defective
ATTRITION AND ABRASION
enamel (developed
enamel when the patient Both are wearing away of the teeth
was sick) + tetracycline Differentiated through taking history
stains

EROSION
SIDE NOTE
Loss of tooth
Parents often assume that baby teeth don’t need
substance by
attention because they will eventually be replaced by
chemical process
permanent teeth. However, it is the responsibility of the
(acids) without
dentist to inform them that neglecting to treat issues in
bacterial action
baby teeth can impact the development of the
permanent tooth underneath
If a lesion is extensive, it can lead to conditions like
local enamel hypoplasia or hypocalcification, known
as Turner’s Tooth
CARIES
If carious lesion reaches the developing permanent
tooth before it erupts, it can adversely affect the quality
Action of acids formed by microorganisms that dissolves
of the enamel
enamel
Direction of enamel rods affects the spread of caries
○ Pit and fissure caries appear like small lesions outside,
but because of the direction of enamel rods and
AMELOGENESIS IMPERFECTA dentinal tubules, once you drill up that area, a bigger
cavity inside is revealed
Group of inherited defects that cause disruption to the ○ Spread of carious lesion on DEJ because of the tufts
structure and clinical appearance of tooth enamel (organic, less material for acids to break down →
Almost no enamel is visible spreads)

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○ Deposited in calcified tissues (bones and teeth)
ACID ETCHING
The fluoride ion enhances the precipitation of fluorapatite
crystals from calcium and phosphate in the saliva
Apply acids (phosphoric acid) to enamel to create micro
○ As the tooth is demineralized from bacterial acid
porosities to fill with composite, sealant and bond ortho
attacks, the hydroxyapatite are broken down
brackets (for bonding)
○ Fluorapatite crystals replace the hydroxyapatite
Etchant is acid and removes organic film on the tooth
crystals
surface and creates a rougher surface for bonding
○ Fluorapatite crystals are less soluble and more
resistant to acid
Too much fluoride (> 1 ppm) can affect ameloblasts while
the tooth is developing
○ Will form mottled enamel, seen as white patches of
hypomineralized and altered enamel. Still able to
resist caries

WILL FLUORIDE MAKE ENAMEL HARDER?
→ No. Fluoride makes the enamel more resistant to acid
attacks (won’t demineralize easily). Makes it stronger, not
harder.

CAVITY PREPARATION

Cavity preparation should follow the course of enamel
rods
Enamel rods at pit and fissure areas run at right angles
from the DEJ. Enamel rods close to CEJ run in a more
horizontal direction
Mottled enamel
It is important that unsupported enamel rods are not left
in cavity margins due to risk of fracture and possible
CAN ENAMEL REGENERATE?
leakage. Bacteria will lodge in these spaces inducing
→ No. At the end of amelogenesis, no ameloblast are left. Enamel
secondary or recurring dental caries.
cannot regenerate but it can be remineralized because of the
Enamels are brittle and inelastic and needs dentin for
calcium and phosphate in saliva, even better if fluoride is present.
support, without it, enamel will break

SIDE NOTE

Too much fluoride can affect the ameloblast when
the tooth is developing mottled enamel (fluorosis)
Mottled enamel – white patches of hypomineralized
outer enamel
Cavite has the most cases of fluorosis because
fluoride exists naturally in their water sources

Unsupported Enamel 6. REFERENCES
Rods – do not have
underlying dentin support [RECORDING] 112 Enamel.m4a
= prone to fracture [PPT] ENAMEL-Lecture-2024.pdf
In cavity preparations
(esp. In cervical areas)
7. TEST BANK
maintaining 90o at the
enamel margin can 1. T or F. Ameloblasts and amelogenin are important cells
increase the risk of in enamel formation.
enamel fracture, which
2. T or F. Enamel lamellae make the tooth more
leads to microleakage and
susceptible to caries.
bacterial infiltration
A beveled margin 3. Which of the following does NOT play a role in the
(15-20o) is recommended hardness of enamel?
a. Orientation of enamel rods
b. Fluoride incorporation into enamel
FLUORIDATION c. Amelogenin degradation during enamel
maturation
Fluoride ions have the same charge and radius as d. Degree of mineralization
hydroxide ions and can replace each other in mineral
structures

UPCD 2028 | AUSTRIA, DACUNES, MANUEL, ONG, ORIO, ORLEANS, PACHECO, PERALTA, PLACIDO, SUNICO, TANAGON 11
 D112 | LESSON 3 | ENAMEL

4. Enamel spindles are formed by which of the following AMELOGENESIS
mechanisms? Ameloblast
a. Dislocation of dentin during the secretory ○ Enamel formation
phase ○ From IEE
○ Secrete matrix proteins
b. Extension of odontoblastic processes into the
2 Phases
enamel layer
○ Formative
c. Irregular deposition of enamel proteins
○ Maturation
d. Microfractures in the enamel during FUNCTIONAL STAGES
mastication ○ Pre-secretory: Differentiation of ameloblast
5. Identify the pointed structure(s) below. Morphogenetic
Histodifferentiation
○ Secretory/formative: formation of DEJ; Tome’s
process; rod and interrod enamel form
Initial secretory + secretory
○ Maturation: post-secretory ameloblast restructure;
mineralization reached 96%
Ruffle ended ameloblast maturation
(transition), smooth ended ameloblast
maturation (modulation)
Protective (reduced)
Desmolytic

CLINICAL CONSIDERATIONS
Enamel hypoplasia and enamel hypocalcification
Amelogénesis imperfecta
6. What cells are responsible for removing water and Attrition
proteins from the enamel as it matures? Abrasion
7. Erupted teeth are covered by precipitates of salivary Erosion
proteins called ___? Caries
Acid etching
ANSWERS: 1F, 2T, 3C, 4B, 5Retzius, Cavity preparation
6Smooth-ended mat. cells, 7pellicle Fluoridation

8. SUMMARY
ENAMEL

PHYSICAL PROPERTIES
Thickness
Hardest calcified tissue
Brittle and Inelastic
Translucent
Permeable to certain ions
Soluble in acids

CHEMICAL COMPOSITION

Mature 96% Inorganic substance
Enamel 4% Organic substance + Water
Largely inorganic

Developing 70% Enamel Proteins (organic)
Enamel 30% minerals (inorganic)
More organic

MICROSCOPIC STRUCTURES
Enamel rods
○ Interrod Cementing Substance/Interprismatic
Substance
○ Rod Sheath\
Hunter-Schreger Bands
Incremental Lines of Retzius
Structureless/Prismless Enamel
Perikymata/Imbrication Line of Pickerill
Neonatal Line/Ring
Enamel Cuticle/Nasmyth’s Membrane
Enamel Lamellae
Enamel Tufts
Enamel Spindles
Scalloped DEJ

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