Histology of Cementum - Oral Dental Sciences, Year 1 PDF

Summary

This document covers histology of cementum, including its composition, types, and functions. It is part of a module on Oral Dental Sciences, Year 1, and provides an overview of the subject matter.

Full Transcript

Histology of Cementum

Tutor: Lauren Stockham

Module: 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 cementum
Distinguish between the 2 main types of cementum and their distribution
Describe how the structure of cementum relates to its function
Apply this knowledge to interpret the clinical significance of cementum
in health and disease

GDC Learning Outcomes; 1.1.5, 1.1.6
Analogy for location of cementum

An ice-cream cone filled with ice-cream demonstrating an analogy of a tooth and cementum as the cone.
Cementum in relation to the Periodontium
Part of tooth root and periodontium structures.

Tooth root: Periodontium:
Dentine Alveolar bone
Pulp canals Periodontal ligament
Cementum Cementum

Cementum supports the junction between the tooth root and the alveolar bone
forming a key part of the periodontium and thus attachment.
Why do we need to know about Cementum?

Prevention and
In health Periodontal Disease
treatment Root Caries

Images: Stock images
Acellular and Cellular Cementum
Composition and Structure
Composition How does this compare to enamel,
dentine and bone?

Inorganic content:
45-50% hydroxyapatite crystal
critical pH=6.7 The point the crystals can start to disolve
Organic content:
50-55%
Collagen fibers mainly type I and minor
quantities of other types III, V, VI, XII
and XIV
Non-collagenous matrix proteins
Water
Overview of structural features
Structural features: Types of
Cementum

Cell presence Acellular Cellular

Extrinsic Intrinsic
Fibre type (Sharpey's
Fibres)
Afibrilar (no
fibres)
Mixed (intrinsic
and extrinsic)
(formed by
cementoblasts)

Time of formation Primary
Cementum
Secondary
Cementum

First cementum that’s formed Can continue forming through the lifecycle of cementum
Acellular cementum

Also known as primary cementum:
It covers the cervical and middle third
of the root (40-70% of root surface)
As the first formed cementum, it is
adjacent to the dentine creating the
dento-cementum junction (CDJ)
It forms slowly as the tooth erupts and
continues post-eruption
It contains collagen fibers (extrinsic)
and non-collagenous matrix proteins
Cross-section of the root surface of a tooth
No cells are present at the CDJ showing the structural layers.
Acellular cementum distribution

Acellular afibrillar cementum (AAC)
Found only in the cervical region
covering enamel and dentine AAC

Contains no collagen fibers
No known functional significance AECF

Acellular extrinsic fibers cementum
(AEFC)
The main type of acellular cementum
Key function in support and anchorage Lower molar tooth showing distribution of
acellular cementum - the AAC and AECF
Acellular cementum functions

Support and anchorage:
As part of the periodontium, Alveolar Cementum
cementum supports the tooth’s bone
position within the alveolar socket PDL

The extrinsic fibers form the
attachment with the periodontal
ligament fiber bundles known as
Sharpey’s fibers (formed by fibroblasts)
and the alveolar bone Sharpey’s fibres (extrinsic)
are embedded into
These fibers are oriented cementum and the alveolar
perpendicular to root surface bone
Cellular cementum Alveolar bone Cementum
Cementoid
Cementoblasts
Also known as secondary cementum:
Contains cemetocytes PDL
Forms quickly compared to primary
cementum
A layer of cementoid (unmineralized
matrix or pre-cementum) can found at
the periphery of cellular cementum
Contains intrinsic fibers that are
parallel to the root surface
Extrinsic fibers
Over time, also contains extrinsic fibers
Intrinsic fibers within cementum
Cementocytes
Cellular Cementum Cells

Cementoblasts
form cementum via cementogenesis
The picture can’t be displayed.
originate from the dental sac
Cementocytes
found in cellular cementum
originate from cementoblasts trapped
in the matrix as a result of the speed of
deposition
The cementocyte cell body (B) with its cytoplasmic
processes (C) embedded within cellular cementum
and the lines of rest in cementogenesis (A).
(Image sourced from the University of Kentuky
Digital Lab, link in resources.)
Cellular cementum distribution

Cellular intrinsic fiber cementum (CIFC)
Is found in the apical third of the roots
and inter-radicular regions of posterior
teeth
Often absent in single-rooted teeth

Cellular mixed stratified cementum
(CMSC)
Is a subcategory of CIFC containing
both intrinsic and extrinsic fibers
Lower molar tooth showing distribution of
Over time this makes up the bulk of cellular cementum - the CMSC, and CIFC
cellular cementum
Cellular cementum functions

Adaption is a key function of cellular Occlusal
cementum that enables: wear
reducing
Reshaping of the root to adjust for the height
movement of the tooth such as drifting of the
when a tooth has been extracted enamel
cusps over
Deposition of cementum at the apex to time
maintain occlusion and compensate for
occlusal wear – thicker in posteriors
teeth (post-eruptive movement)

Lower molar tooth showing thickening of cementum at the apex
to compensate for the occlusal wear that happens over time
Cellular cementum functions 2
The picture can’t be displayed.

Cellular cementum has the ability to
repair itself in two ways:
Anatomical repair - Able to repair
resorbed or fractured root surfaces to
some degree
Functional repair - Plays in a role in
periodontal disease healing
maintaining the width of the PDL (see
image)
Histological stained sample of the root surface
showing an area of functional repair at C. D is the
dentine. Image sourced from Ghanbarzadeh et al
(2017)
Distribution of cementum

Ground section of teeth showing the
distribution of cementum – acellular
cementum (AEFC) towards the cervical
of the roots the cellular cementum
(CMSC) towards the apical region note
the difference between the thickness
on the molar tooth compared to the
incisor. This is because molar teeth
undergo heavier occlusal loads.
(Image sourced from Yamamoto et al
2016).
Clinical significance
Functions
Cementum over the lifecourse
Cementogenesis takes place
continuously throughout life

The thickness, hardness and
mineral content increases with
age.
Representative graphs of cementum
width vs. anatomical location show a
two-step increase in cementum
thickness when measured from the
cementum enamel junction (CEJ) to the
root apex regions, that is, along the
length of the root. Graph sourced from
Jang et al (2014)
Cemento-Enamel Junction (CEJ)

The relationship of the CEJ (where to cementum and enamel meet) varies among teeth and within
the same tooth. A = Overlap 60-65%, B = GAP 10%, C = Meet 25-30%
Structural abnormalities
Hypercementosis is where there is excessive
deposition of cementum towards the apex resulting
in thicker roots.
The aetiology includes:
Local factors such as trauma or inflammation
Systemic factors such as Paget's disease, or
Idiopathic (unknown)
Clinical implications:
It may affect single or multiple teeth.
Often asymptomatic Periapical radiograph showing
hypercementosis of the lower left 6 distal
May cause problems for extractions root. (Image sourced from Pinto et al
2017)
Summary Inorganic and organic

Composition

Cellular and cellular
Fibre types
Functions Cementum Types

Anchorage
Support
Adaption
Repair

Clinical
implications
Continues to grow, deposit
Increase in thickness, hardness and mineral content
CEJ relationship variations
References for images:
Yamamoto, T., Hasegawa, T., Yamamoto, T., Hongo, H., & Amizuka, N. (2016). Histology of human cementum: Its structure, function, and
development. The Japanese dental science review, 52(3), 63–74. Available at: https://doi.org/10.1016/j.jdsr.2016.04.002
https://www.ncbi.nlm.nih.gov/pmc/articles/PMC5390338/#bib0380 Accessed date: 25 March 2021
Ghanbarzadeh, M., Heravi, F., Abrishamchi, R., Shafaee, H., Ghazi, N., Heravi, P., & Ghanbarzadeh, H. (2017). Cementum and dentin repair
following root damage caused by the insertion of self-tapping and self-drilling miniscrews. Journal of Orthodontic Science, 6, 91 - 96.
Jang, A. T., Lin, J. D., Choi, R. M., Choi, E. M., Seto, M. L., Ryder, M. I., Gansky, S. A., Curtis, D. A., & Ho, S. P. (2014). Adaptive properties of
human cementum and cementum dentin junction with age. Journal of the mechanical behavior of biomedical materials, 39, 184–196.
Available at: https://doi.org/10.1016/j.jmbbm.2014.07.015 Accessed date: 25 March 2021
Matalová, Lungová, &Sharpe, Chapter 26 - Development of Tooth and Associated Structures, Editor(s): Ajaykumar Vishwakarma, Paul
Sharpe, Songtao Shi, Murugan Ramalingam, Stem Cell Biology and Tissue Engineering in Dental Sciences, Academic Press, (2015), Pages
335-346, ISBN 9780123971579. Available at: https://doi.org/10.1016/B978-0-12-397157-9.00030-8. Accessed date: 25 March 2021
Pinto AS, Carvalho MS, de Farias AL, da Silva Firmino B, da Silva Dias LP, Neto JM, da Silva AM, Castro FA, Costa AL, De Castro Lopes SL.
Hypercementosis: Diagnostic imaging by radiograph, cone-beam computed tomography, and magnetic resonance imaging. J Oral
Maxillofac Radiol [serial online] 2017 [cited 2021 Mar 24];5:90-3. Available at: https://www.joomr.org/text.asp?2017/5/3/90/221078
Accessed date: 25 March 2021
Vandana, K. L., & Haneet, R. K. (2014). Cementoenamel junction: An insight. Journal of Indian Society of Periodontology, 18(5), 549–554.
Available at: https://doi.org/10.4103/0972-124X.142437 Accessed date: 25 March 2021