Anatomy Mod 10 PDF

Summary

This document provides an overview of dental anatomy, focusing on the structure and function of enamel, dentin, pulp, and periodontium. It discusses their properties, composition, and microscopic features. The document also includes sections on clinical considerations, age changes, and different types of bone loss within the structures.

Full Transcript

Chapter 12‐ Enamel
Fehrenbach and Popowics
Enamel Characteristics
 Hardest mineralized tissue in the human body
 Avascular and has no nerve supply
 Non‐vital
 When lost it is gone forever
 Can undergo demineralization and remineralization
 Appears radiopaque on x‐ray
 Covers the anatomical crown
Enamel Composition
Mature enamel by weight:
96% Inorganic material
1% Organic material
3% Water

 Calcium hydroxyapetite crystals
 Calcium, phosphate, hydroxide
 Also contains:
 Carbonate, magnesium, potassium, sodium, and
fluoride
Enamel
 Where is enamel thickest?
 Near CEJ
 In the middle
 Near incisal edge/cusps

 Where is enamel thinnest?
 Near CEJ
 In the middle
From Anatomy of Orofacial Structures,
 Near incisal/cusps 6th ed. by R.W. Brand and D.E. Isselhard,
1998, St. Louis, MO: Mosby.
Clinical Significance of Enamel Features

 Color
 Bluish white

 Brittleness
 Fairly brittle‐ prone to fracture

 Solubility
 Acid causes demineralization
 Fluoride reduces solubility

 Permeability
 Ability to be penetrated‐ Fluoride, whitening agents, also
stains
Enamel Caries‐ Incipient Lesions
Microscopic Features of Enamel
 Enamel rod
 Cylindrical in longitudinal section
 Head and tail ends
 Longer near cusp tips/ incisal edge
 Shorter near CEJ
 Interrod enamel
 Between enamel rods
Appearance of Enamel Rods
Enamel Rods
Hunter‐Schreger Bands

 Crystals in each enamel
rod are oriented
differently than in other
rods
 Seen microscopically as
light and dark bands in
enamel with reflected
light
Lines of Retzius

 Incremental lines formed
from daily deposition of
enamel matrix

 Neo‐natal line
 pronounced line of
Retzius
 found in teeth that are
forming at birth
Appearance of Enamel
 Imbrication lines
 Horizontal ridges
 Perikymata –
 Grooves
 Visible on the surface of
enamel
 Formed by overlapping ends
of lines of Retzius
Perikymata/ Imbrication lines
Enamel Spindles
 Blind ends of dentinal
tubules
 Caused by
odontoblasts that lined
up on the wrong side
of the DEJ
Enamel Tufts & Lamellae
 Tufts
 Located at the DEJ
 Form between the
groups of enamel rods.
 Lamella
 Extend from the DEJ to
the enamel surface.
Fehrenbach and Popowics
Properties of Dentin
 Bulk of tooth
 Yellowish
 Less mineralized than enamel
 70% inorganic
 20% organic
 10% water
 Slightly elastic
 More porous and soluble than enamel
 Staining, faster attrition, abrasion and caries spread
more quickly
Problems with Exposed Dentin
Due to gingival recession:
 Sensitivity
 Staining
 Root caries
 Maturation of Dentin
 2 phases of mineralization
 Primary
 Initial calcium hydroxyapatite crystal globules form
 Produces interglobular dentin
 Less mineralized
 Secondary
 Later, new areas of mineralization occur
 Layered on the initial crystals
 Produces globular dentin
 Complete crystalline fusion‐ highly mineralized (stronger)
Components of Dentin
 Dentinal tubules
 Odontoblast process
inside
 Contains dentinal
fluid
 Has an afferent axon
 Perceives pain only
from different
stimuli
 Overview: Types of Dentin
 In relationship to the  According to the time it
dentinal tubules: was formed in the tooth:
 Peritubular  Primary dentin
 Intertubular  Secondary dentin
 Reparative (tertiary)
 In relationship to the dentin
DEJ:  Sclerotic dentin

 Mantle dentin
 Circumpulpal
Dentin in relation to Dentinal
Tubules
 Peritubular
 Creates the wall of
dentinal tubule
 Highly mineralized
 Intertubular
 Found between the
dentinal tubules
 Less mineralized
Dentinal Tubules

peritubular

intertubular
Dentin in Relationship to the DEJ
 Mantle dentin (C.)
 First predentin that forms in
tooth
 Highly mineralized
 Circumpulpal (B.)
 Deep to mantle dentin
 Makes up the bulk of the
dentin
 Lines pulpal wall
Dentin based on Time of
Development
 Primary
 Laid down before
completion of apical
foramen
 Secondary
 Laid down after
completion of apical
foramen
 Tertiary
 Laid down in response
to trauma
Tertiary Dentin
 Causes of injury may include:
 Caries
 Cavity preparation
 Attrition
 Recession
 Reactive
 Made by existing
odontoblasts
 Reparative
 Made by pulpal cells that
differentiated into new
odontoblasts
Sclerotic Dentin
 A type of tertiary dentin
 Associated with chronic injury
 Odontoblasts die leaving dentinal tubules vacant
 Tubules fill with minerals
 Increases in amount with age
 Block caries advance
 Permeability to pulp blocked
Clinical Considerations‐ Dentinal
Tubules
 Exposed dentinal tubules can serve as an entryway for
bacteria
 Leading to caries of the dentin
 Rapid expansion, must be restored
 Exposed dentinal tubules contribute to sensitivity,
triggers for dentinal hypersensitivity include:
 Thermal changes
 Mechanical irritation
 Dehydration
 Chemical exposure
 Hydrodynamic Theory of Dentinal Sensitivity

 Changes in dentinal
fluid trigger a pain
response in the pulp
 Evaporation of fluid
 Movement of the
fluid
 Ionic changes in the
fluid
Microscopic features of Dentin
 Imbrication lines of von
Ebner
 Look like growth rings
on a tree
 Show daily deposition of
dentin by odontoblasts
Microscopic features cont.
 Contour lines of Owen
 Dark bands of adjoining
imbrication lines that
show disturbances to
odontoblasts
Microscopic features cont.

 Tomes granular layer
 Found beneath cementum in the root
 By the DCJ
 More interglobular dentin
 Less mineralized
Aging and Dentin
 Diameter of dentinal tubules narrows
 Less sensitivity
Composition of the Pulp
 Innermost part of the tooth
 Not mineralized‐ 0% inorganic
 Connective tissue proper ‐ soft & gelatinous
 Radiolucent on radiographs
Functions of the Pulp
 Nutritive – blood vessels carry oxygen and nutrition to
the tooth
 Formative – houses the odontoblast cell bodies that
allow for continued formation of dentin
 Sensory‐ perceives pain (only)
 Protective – WBCs (inflammatory and immune
response)
Pulp Anatomy
 Pulp chamber
 Follows the shape of the
tooth
 Coronal & radicular
 In crown
 Includes pulp horns
 In root
 Includes apical foramen &
accessory canals
Apical Foramen/ Accessory Canals
 Apical Foramen
 Opening from pulp to PDL
 In apex of tooth
 Largest opening
 Becomes smaller with age
 May be at direct apex or off to the side
 Accessory Canals
 Smaller openings from pulp to PDL
 Form when HERS encounters a blood vessel during root
formation
Apical Foramen/ Accessory
Canals
 Top arrow – accessory
canal

 Bottom arrow – main
canal of apical
foramen
Cells of the Pulp
 Fibroblasts‐ produce fibers & ground substance
 Collagen
 Reticular
 Most common cell in the pulp

 Odontoblasts‐
 Cell body only
 Mesenchymal cells‐ differentiate to become
fibroblasts & odontoblasts
Cells of the Pulp Cont.
 WBCs‐  Nerves‐
 involved in the inflammatory and  Myelinated
immune response
 Perceive pain only
 RBCs‐  Non‐myelinated
 Carry oxygen
 Extensive vascular
supply
 Lymphocytes ‐
immune function
4 Microscopic Zones of Pulp
 Odontoblastic layer
 Cell‐free zone
 Cell‐rich zone
 Pulpal core
4 Zones of Pulp
 Odontoblastic
 Next to dentin
 Cell bodies of odontoblasts
 Secondary or tertiary dentin will encroach on this area
 Cell‐free
 Fewer cells than odontoblastic layer
 Collagen fibers & ground substance (tissue fluid)
 Nerve and blood vessel plexus
4 Zones of Pulp
 Cell‐rich
 fibroblasts, mesenchymal cells, WBCs
 collagen fibers & ground substance
 larger blood vessels
 Central pulp or pulpal core
 Many fibroblasts, mesenchymal cells, WBCs
 Collagen fibers & ground substance
 Large blood vessels & nerves
Age Changes in the Pulp
 Pulp horns
recede
 Decrease in cells
 Less intercellular
substance
 fibrosis
 Less sensitivity
 Obliteration of
the apical
foramen
Comparing Dentin & Pulp
from Young to Old Tooth
Clinicial Consideration‐ Pulp Stones
 True
 Mineralized masses of dentin with dentinal tubules and
odontoblastic processes
 False
 Amorphous in structure
 Chapter 14
Fehrenbach and Popowics
Cementum
 Thickest at root apex
 Thinnest at the CEJ
 Avascular
 No nerve supply
 Dull yellow in color
 Grainy feel with explorer
 Easily worn away when exposed in the mouth
 Soft‐ gauging of root is possible w/ instruments
Composition of Cementum
 Inorganic
 65%  Water
 Calcium hydroxyapatite  12%

 Organic
 23%
 Collagen fibers
 Glycoproteins
 Proteoglycans
Cementum Histology
 Mineralized fibrous
matrix
 Sharpey fibers‐ collagen
fibers from the PDL that
insert on the cemental
surface at a 90 degree
angle
 Attach root to bone
 Intrinsic non‐
periodontal fibers‐
collagen fibers made by
cementoblasts
Cementum Histology cont.
 Cells
 Cementocytes‐
entrapped
cementoblasts
 Lie in a lacuna
 With canaliculi
 Cementoblasts
 Line the PDL space
 CEJ Interfaces

 3 possible
interfaces:
 OMG
 Overlap, Meet,
Gap
 M = most
common
 Consequences
of gap
Types of Cementum
 Acellular
 1st layers of
cementum
 No embedded
cementocytes
 Width never
changes
 Cellular
 Deposited later
 Contains
cementocytes
 Width can
change
Cementum Repair
 Cementum can be
removed from the root
resulting in microscopic
reversal lines
 Arrest lines can be seen
microscopically after
new secondary
cementum is deposited
Clinical Consideration‐
Cementicles
 Mineralized bodies of
cementum
 Attached
 Free in PDL
Alveolar Process
 Part of the maxilla or mandible that supports and
protects the teeth
 60% mineralized/ inorganic
 25% organic
 15% water
 More easily remodeled than teeth
 Allows for orthodontic movement
Anatomy of the Jaws
 2 types of bone
 Alveolar process
 Contains the roots of the teeth
 Basal bone
 Apical to the roots of the teeth
Alveolar Process Anatomy
 Alveolar bone proper
 Lining of tooth socket
 Compact bone/ lamina
dura
 Sharpey fibers
 Supporting alveolar bone
 Cortical plate facial and
lingual to the teeth
 Trabecular bone
between plates and ABP
Alveolar Process Anatomy cont.
 Interdental septum
 ABP (compact bone)
 Supporting bone‐
Trabecular bone
(cancellous)
 Interradicular septum
 ABP (compact bone)
 Supporting bone‐
Trabecular bone
(cancellous)
Location of the Alveolar Crest
 1‐2 mm apical to the
CEJ of the tooth

 Creates a scalloped
border similar to the
gingival margin
From Dental Radiography
E‐Book, 5th ed. by J.M.
Iannucci and L.J.
Howerton, 2017, St. Louis,
MO: Elsevier.
Types of Bone Loss
Remodeling of the Alveolar Process

 Effect of pressure
 Compression zone on
one side
 PDL crushed
 Triggers bone resorption
 Tension zone on the
other side
 PDL stretched
 Triggers bone deposition
Periodontal Ligament
 Appears on radiographs as a radiolucent area
 PDL space‐ non‐mineralized
 Organized fibrous connective tissue
 Allows for a small amount of movement of the tooth
 Shock absorber
 Sensory function
 Can sense more than pain
 Pressure, temperature and touch as well
 Composition of the PDL
 Cells
 Fibroblasts
 Mesenchymal cells
 Epithelial rests
 WBCs & lymphocytes
 Cementoblasts
 Osteoblasts
 Osteoclasts
 Odontoclasts
PDL Principal Fiber Groups
 Collagen
 Arranged in bundles

 Alveolodental ligament
 Support tooth
 Interdental ligament
 Between neighboring teeth
 Gingival fiber group
 Support free gingiva
Alveolodental Ligament Fiber
Subgroups
 Alveolar crest
 Horizontal
 Oblique
 Apical
 Interradicular
Interdental Ligament
Gingival Fiber Group
Changes in the PDL
 Hourglass
 Wider near apex and CEJ
 Narrower in the middle
 Excessive function= wider
ligament
 Lack of function = thinner
ligament
 Periodontal disease
 Disorganization