Histology of Enamel PDF

Summary

This presentation covers the histology of enamel, including its composition, structure, functions, and clinical significance. It also discusses changes in enamel over the life course, along with its role on the processes involved in demineralization-remineralization and structural abnormalities.

Full Transcript

Histology of Enamel

Lauren Stockham

Oral Dental Sciences, Year 1
Intended learning outcomes

By the end of the session students should be able to:
Describe the composition and structure of enamel
Describe how the structure of enamel relates to its function
Be able to distinguish the clinical appearance of enamel over the life-course
Apply this knowledge to interpret the clinical significance of enamel in health and
disease
3

Assessment

Formative: (to support your learning)
Workbooks,
Quizzes

Summative:
E-assessment for Oral Dental Sciences
4

Histology of the tissues of the teeth and
supporting structures
Enamel
Dentine
Pulp
Cementum

Bone (alveolar)
Periodontal ligament
Gingiva
5

Let’s reflect on WHY we need to learn this…

→To effectively support, maintain and improve oral health for our
patients, examples:

To be able to give the
best came.
6

Refresh your knowledge Enamel

Where is enamel found?

What is the embryonic origin of
enamel? dental epithelium-Ectoderm origin

How does this link to the embryonic This Photo by Unknown Author is licensed under CC BY-SA-NC

origin of enamel?
Enamel protect.
the tooth

Refer to Oral Embryology and Tooth
Morphology lectures for more
information. Source: Unknown CC
7

Enamel

COMPOSITION AND STRUCTURE
8
components
Composition of enamel -
calciums Phosphata
-
Mineral (inorganic) content:
96% inorganic minerals
-

Majority - =>
calcium hydroxyapatite
(Ca5(PO4)3OH)
Minority – carbonate, fluoride
Organic content:
-
4%
-

Fibrous material (collagen)
Chemical structure of calcium hydroxyapatite
Water
(Rujitanapanich et al 2014). Some proteins
9

Overview of structure of enamel

Enamel rods (prisms)
Interrods
Crystallites (calcium hydroxyapatite)
Link to amelogenesis
Incremental lines
Prismless enamel (rod-less)
Dento-enamel junction and
microscopic features
The greenhouse in the Royal Opera House demonstrating an
analogy for a strong yet brittle structure like enamel.
Image credit: Lauren Stockham
 structural unit of enamel.
-key
Enamel rods
Enamel

Millions of enamel rods (prisms) make
up the structure of enamel.

They are tightly packed and organised
with a keyhole shape’ in cross-section
(b).

Each rod contains millions of calcium
hydroxyapatite crystallites (the
mineral/inorganic content of enamel).
Zoomed in detail of the enamel rods
from a molar tooth
11

Enamel rods

The key hole shape reflects different parts of
the enamel rod – a head and a tail (A).
The orientation of the head of each rod is
usually towards the occlusal/incisal surface
relative to the tail which is oriented towards
the cervical region.

The tail is also known as an interrod.
Structure of enamel rods in cross-section
and longitudinal sections
Each rod and interrod is surrounded by a
sheath (organic material).
12

Enamel crystallites

There are millions of crystallites
calci (hydroxyapatite) in each rod tightly packed in
keyhole shapes.

These are extremely long, thin and ribbon-like,
they may run the thickness of enamel.

&
In orientation, the crystallites in the head =
parallel with the long axis of the rod, and the&
-

- -
tail
= diverge slightly (c).
-

The pattern of the crystallites within the rod
adds to the strength of enamel. Structure of enamel crystallites within the enamel rods
13

Enamel rods - orientation

To account for the shape of the tooth, the
direction of the rods varies.
At the cervical margin they are directed more
horizontally-apically and at the cusp tips
they are almost vertical.

The overall thickness of enamel also varies
where it is thickest at the cusp tips and
incisal edges and thinnest at the cervical
margins. Dento-enamel junction-Seal.
-

to take forces-stronger
cusps
thicker-resistant
Why might this be?
Enamel rods

They run from the dento-enamel junction (DEJ) to
the enamel surface.

The rods traverse together bending right and left in
an s-shape manner.

At the DEJ the rods are positioned perpendicular (at
right angles) to the dentine in general.

At the cusps, the rods are twisted forming gnarled
enamel.

These structural features add to the overall strength
of enamel. Longitudinal section of enamel rods
from the DEJ to the surface
15

Enamel rods direction and clinical significance

The direction of the rods is a key
consideration in cavity preparation to
avoid unsupported enamel that will
fracture leading to failure.

Diagrams showing a posterior proximal cavity preparation
16

Enamel rods and amelogenesis Link back to Embryology
of the Crown lecture
The structure of the enamel rods is formed
by the ameloblasts during amelogenesis.

Each enamel rod (and associated interrod)
are formed by 1 ameloblast.

&
The lifecycle of ameloblasts is significant
since it means that enamel is inert – it has
no cell during its life. no source nutrients
of
or blood supply.
The pattern of amelogenesis results in
incremental lines.
-

as the
enamel
> lays
- down Source: dent-wiki.com
as long matrix, starts to mineralise
only live for Zoomed in longitudinal section of enamel rods
function
more into
Incremental
has formed
-

associated with the ameloblast. lines
protection during eruption-life cycleover.

of. ↑
Incremental lines
process of enamel formation.

&
Incremental lines represent the pattern of
amelogenesis that occurs in waves
reflecting active and rest phases of growth

Similar to growth rings (lines) of a tree, the
rings of growth in teeth are called Stria of
Retzius (line of retzius)
/
These lines may be detected clinically on
the surface of enamel as normal subtle
Tree in cross-section
features and as more distinct features
Incremental lines

Stria of Retzius - are visible under a microscope in
ground sections of enamel as growth rings/lines

Perkymata – The edge of the stria of retzius that is
visible as a shallow furrow on the enamel surface
showing where the incremental lines reach the
surface on the labial/buccal surfaces. These are
most marked when newly erupted and gradually
wear over time. Visible clinically.

Diagram of the incremental lines in enamel
Looking at the pattern of the Stria of Retzius - can you
remember where amelogenesis starts?
cusp tip
-

expands out and spreads.
 1. Identify the teeth present in each clinical image
2. Identify the perkymata in each – note that the teeth have been air-dried to
Take a look… enable visibility of these features
3. Identify the morphological features indicated by the arrows at the incisal
edges
mamelous.

4. Consider why there might be a difference in the size of the features between
3. both images. erupted teeth
newly.

URI ULL
2.

Perkymate CR2 LRR (U) (2
‘Prismless’ Enamel
Although enamel rods (prisms) are the main structural unit
of enamel, there are some area of enamel where it is
unstructured known as prismless/aprismatic.

Surface –
The very first and last formed enamel shows no usual prism no prisms
structure where the crystals are parallel with the surface.
Body –
prisms/
It is 30 microns wide at the surface, highly radio-opaque, rods
harder and less soluable – includes more fluoride -more
and
carbon thus key for demineralisation/ remineralisation. resistantLight microscopy image showing the
&
less resistant distinction between the surface enamel (no
rods/prisms) and body (rods) of enamel
It is seen in the primary dentition and 70% of the
permanent dentition, greatest in the cervical regions.
Clinical significance → may interfere with optimal etching.
 to DEJ
perpendicular.

Rods
Dentine-Enamel Junction (DEJ)

The junction between enamel and
dentine that forms once dentinogenesis
and amelogenesis have started.

Scalloped appearance under a
microscope thought to strengthen the
bond between the two materials almost
locking them together.

The dento-enamel junction between
enamel and dentine
Structural features at the DEJ
microscopic feature.

~
Enamel Tuft
Thought to result from abrupt changes in
direction of the enamel rods
This is because of the scalloped
boundary of enamel at DEJ
Possibly supports bond between dentine enamel -
and enamel?
No known clinical significance
Seen in traverse sections of enamel

Dentine

Cross-section of DEJ
 Dentinogenis isStarts before
Structural features at the DEJ Amelogenisis.

feature
microscopic
Enamel Spindles
extension of dentine tubules into enamel
May result from odontoblast processes
extending into the ameloblast layer
becoming trapped since dentine starts to
form before enamel
Possibly contribute to minor sensitivity
I
not sure.

Cross-section of DEJ
Structural features visible under a microscope

Features are only visible under a microscope,
they help to grasp the histological structure
light and dark bands under light microscope =
Hunter Schreger Bands
longitudinal section run upwards from
dentine – see image
cross-section appear as growth rings

Cross-section of enamel and
dentine
Structural features at the enamel surface
- developmental feature.

Lamella
Appear as cracks in enamel -
developmental defects
appear as jagged lines in surface of
crown clinically
extend inwards maybe as far as dento-
enamel junction
result of ameloblast ceasing production
of enamel
Can be mistaken for cracks in enamel
and vice versa

Cross-section of enamel and dentine
26

Link to structure

FUNCTIONS OF ENAMEL
Soft boiled egg analogy to explain the functions
and link with structure
28

Functions
mineralized
Highly
(oride)
·

als
-

miner
-

Inert tuptake
-

·

look.
Inability to
Ion
Protection Eating repair or Smile
exchange
feel injury
29

How the functions of enamel link to the
structure
Functions Structure
Protection of the tooth/pulp Thickest at cusp tips, occlusal and
Eating: chewing, biting etc incisal surfaces
Inability to repair or feel injury Covers the entire tooth crown
Able to remineralise and demineralise Inert tissue (no living cell due to
-

– ion exchange ameloblasts’ limited lifecycle
Smile - Aesthetically appealing ‘pearly Hardest biological tissue
whites’ Highly mineralized tissue
White translucent crystallite
Permeable ‘micropores’
31

Link to functions and clinical appearance

CHANGES IN ENAMEL OVER THE LIFE-
COURSE
32
because
Primary dentition whiter they
are thinner.

Enamel changes over the life-course

Over time enamel is subject to tooth
wear including:
can be
Attrition Crystallites acids
eroded away by.

Abrasion
Erosion
For example, perkymata are worn away,
scratches and cracks develop.
Colour changes – reduced translucency
and increase in underlying dentine makes
enamel appear yellower – normal aging
-

process.
reduced permeability.
33

Enamel changes over the life-course.
new tooth more permeable
Over time enamel is subject to: ~ Houride/calcium/phosphate
can be taken

Reduced ‘permeability’ – exchange of those ions.
up so exchange
ions such as Ca, PO, F-

Clinical significance for exposure to
topical fluoride as a younger tooth and
in the progression of early enamel
lesions.
Demineralisation-Remineralisation cycle

As a mineralised structure, enamel is subject to Link to Aetiology of Caries Lecture
demineralisation (loss of mineral) and
remineralisation (uptake of mineral)
In acidic conditions the balance favours
demineralisation
In alkaline conditions the balance favours
remineralisation enabling uptake of fluoride
and calcium phosphate
The critical pH of enamel is 5.5 Acid Alkaline
to
point at which enamel starts
demineralize.

What substance in the mouth is alkaline and thus
-

favours remineralisation?
-
*
tiva
Demineralisation-Remineralisation cycle

Since enamel does not contain any living cell, it is
not able to repair itself with the immune system
and therefore it can not feel injury

This allows the progression of the early stages of
dental caries to occur unnoticed to the host

The composition and structure of enamel is
relevant for the clinical prevention and treatment
of dental caries
·

Detect early changes
·

Kiskassen
Cross-section of DEJ
36

Clinical application – preventive and restorative

Fluoride – enamel that has fluoride
incorporated -(fluorapatite) has a critical
pH of 4.5, lower than hydroxyapatite thus
more resistant to acids and demin.cratisation.
--

Acid etch – acid removes minerals from
-

the enamel surface creating ‘tags’ that
enable the bond to fill in and stick the
composite to. X micro mechanical retention.

Link to Histopathology of Enamel
Caries lecture in Year 1.
37

The significance of the DEJ and caries
color change
Take close look at:
The breakdown of enamel
The progression into dentine and to the
pulp

Note the difference in size of the lesion
in enamel compared to the lesion in
-
&
dentine at the DEJ…
·
Mushrooms out.

Clinical image showing the progression of caries
38

Radiographic view of dental caries in enamel

Take a close look at the radiopaque
structures of enamel, dentine and
alveolar bone – the whiter it is, the more
mineralized it is.

The circle identifies a radiolucent area of
enamel that is consistent with
interproximal caries clinically although
not breached the DEJ.

Radiograph showing the LR56 · early loss of minerals.
39

Enamel

STRUCTURAL ABNORMALITIES
Structural abnormalities - Incremental Lines

Clinically distinct:
Neo-natal line
an exaggerated line representing the
distinction between enamel that has formed
before birth and after birth
It usually reflects a disturbance in the
amelogenesis at birth (perinatal) difficult
Other exaggerated lines extended
birth.
Reflect systemic disturbances during
amelogenesis ie fever, tetracycline staining
Primary dentition showing the distinction
between when enamel forms in the crown.
Structural abnormalities in enamel Link to Embryology of
the Crown lecture

As a result of disturbances during amelogenesis,
defects in the enamel structure may result from:
Local disturbances – affect individual teeth
such as trauma
systemic disturbances – affect all the teeth
forming at the time such as fluorosis (too much
fluoride), or exposure to tetracycline,
nutritional deficiencies, molar-incisor
hypomineralisation MI
Genetic factors – may affect all teeth such as
amelogenesis imperfecta

These defects may result in significant clinical Tetracycline staining of the primary dentition.
implications.
42

Structural abnormalities in enamel

Defects during amelogenesis can result in
enamel hypoplasia or enamel
hypomineralisation collectively known as
molar-incisor hypomineralisation.

The impact for patients can range from
Showing enamel hypomineralisation (Patel et al minimal to significant clinical
2019). implications.

Further information in articles.
Link to Developmental
Anomalies lecture.
43

Structural abnormalities in enamel
Can you identify:
Any colour changes in specific teeth?
Any morphology discrepancies with
specific teeth? MIH

Image showing Molar incisor-hypomineralisation in an 8
year old child. (Seow 2014).
44

Summary
Enamel

The clinical
Composition Structure Functions
significance

How functions
organic and structural
enamel rods link to
inorganic abnormalities
structure

changes over caries
the life-course prevention
45

Knowledge and understanding of enamel structure is essential to
promote the prevention of dental caries - most prevalent chronic
condition globally. Key area of research focus to understand how
enamel can be regenerated.
46

Reading

Highly recommend
reading – included in
post-session on moodle.
First article gives
detailed and succinct
explanation of
amelogenesis and
dentinogenesis
Both articles discuss
the clinical impact