Lecture 4 Composite Restoration Part 1 PDF

Summary

Lecture notes provided by Dr. Rehab Alwakeb covering composite restoration, including the history, different types of composite materials (macrofilled, microfilled, hybrid, nanofilled), their properties, and uses in dentistry. The lecture aims to detail and classify different aspects related to composite restorative materials.

Full Transcript

Composite Restoration(1)

By: Dr. Rehab Alwakeb
Operative Dentistry Division
Reference:

Art and science of operative dentistry
6th edition.
“Introduction to Composite Restorations ,
chapter 8, p:216.”
ILOs:

I. Define composite material.
II. Classify composite resin according
to filler content and handling
characteristics.
III. Determine different properties of
resin composite restoration.
History of resinous material (Unfilled Acrylic
Resin)

Self-curing (chemically activated) acrylic
resin for anterior restorations was developed
in Germany in the 1930s.
Early acrylic materials were disappointing
due to:
1. Poor activator systems.
2. High Polymerization shrinkage.
3. High coefficient of thermal expansion.
4. High wear.
Introduction (Acrylic resin)
which resulted in:
1. Marginal leakage.
2. Pulp injury.
3. Recurrent caries.
4. Color changes.
5. Loss of contour and contacts.
So, are they still being used??
 A current, although limited, use of acrylic resin is:
for making temporary restorations in operative
and fixed prosthodontic “indirect restoration
procedures fabrication” requiring two or more
appointments.

In an effort to improve the physical characteristics
of unfilled acrylic resins, a polymeric dental
restorative material reinforced with inorganic
particles was introduced in 1962 (by Bowen).

This filled resin material became the basis for the
restorations that are termed composites.
Dental Composite material
1. Definition.
2. Components.
3. Classification:
a. According to filler (size, amount and
composition).
b. According to Handling characteristics
 I. definition:

Composite is a material made from two or more
constituents with significantly different physical or
chemical properties that, when combined, produce a
material with characteristics different from the individual
components.
II. Components:
Matrix Initiators and
Filler Accelerators
Coupling Agent Pigments
 III. classification:

a. According to filler
size

Macrofil Microfil Hybrid Nanofilled
1. Macrofilled or Conventional Composites
They are no longer used in clinical practice
Contains approximately 75-80% inorganic
filler by weight.
The average particle size of this composites
was approximately 8 μm.
as it suffers of rough surface texture.
causes the restoration to be more susceptible
to discoloration from extrinsic staining
 2. Microfilled composite:
Microfill composites were introduced in the
late 1970s.
These materials were designed to replace the
rough surface characteristic of conventional
composites with a smooth, lustrous surface
similar to tooth enamel less susceptible to
plaque retention and discoloration.
Filler particle size: colloidal silica particles
whose average diameter is 0.01 to 0.04 μm.
Filler content: approximately 35% to 60% by
weight.
 Properties:
✓Some of their physical and mechanical
characteristics are inferior.
✓Clinically highly wear resistant.
✓Low modulus of elasticity may allow microfill
composite restorations to flex during tooth flexure,
better protecting the bonding interface.

This makes micro-fill composites an appropriate
choice for restoring Class V cervical lesions or
defects in which cervical flexure can be significant
(e.g., bruxism, clenching, stressful occlusion).
 3. Hybrid composite:
Hybrid composites were developed in an effort to
combine the favorable physical and mechanical properties
characteristic of macrofill composites with the smooth
surface of the microfill composites.

Filler size: mixture of microfiller and small filler particles
that results in a considerably smaller average particle size
(0.4–1 μm) than that of conventional.

Filler content: 75-85% by weight
 Properties:
✓Because of the relatively high content of
inorganic fillers, the physical and mechanical
characteristics are generally superior to those of
conventional composites.
✓Classic versions of hybrid materials exhibit a
smooth “patina-like” surface texture in the
finished restoration.
Nanohybrid composites: these are newer versions
of hybrid composites contain ultra-small
nanofillers, resulting in superior characteristics.
4. Nanofill composites

Filler particles size are extremely small
(0.005–0.01 μm).
Consequently, high filler levels can be
generated in the restorative material, which
results in:
1. Good physical properties
2. Improved esthetics.
3. The small primary particle size also makes
nanofills highly polishable
 Nanofill and Nanohybrid composites are the most
popular composite restorative materials in use.
These composites have almost universal clinical
applicability
Wear Comparison:
Porous friable nanoclusters
Lightly sintered

Hybrid-wear True Nano wear
III. Classification (cont.)

b. According to handling ccc

Flowable Packable
 1.Packable composite
Their development is an attempt to accomplish Easier
restoration of a proximal contours and contacts and

Because of the increased viscosity, it is typically more
difficult to attain optimal marginal adaptation.
 2. Flowable composite
Generally, have lower filler content and
consequently inferior physical properties such
as:
1. lower wear resistance.
2. Lower strength.
3. They also exhibit much higher polymerization
shrinkage.
WHY?
Due to decreased filler loading thus
Decrease viscosity
Decrease mechanical properties
Increased polymerization shrinkage.
 Uses:
1. Pit-and-fissure sealants,
2. Marginal repair materials.
3. First increment placed as a stress-breaking liner
under posterior composites.
4. First small increments in the proximal box of
Class II restoration in an effort to improve
marginal adaptation.
IV. Properties:

1. Linear Coefficient of Thermal
Expansion.
2. Water sorption.
3. Wear Resistance.
4. Surface Texture.
5. Radiopacity.
6. Modulus of Elasticity
7. Polymerization.
 1. Linear Coefficient of Thermal Expansion

the rate of dimensional change of a material per unit
change in temperature.
The LCTE of modern composites is approximately
three times that of tooth structure.
Bonding a composite to etched tooth structure reduces
negative effects due to difference between the LCTE
of the tooth structure and that of the material
IV. Properties:

1. Linear Coefficient of Thermal
Expansion.
2. Water sorption.
3. Wear Resistance.
4. Surface Texture.
5. Radiopacity.
6. Modulus of Elasticity
7. Polymerization.
 2. Water sorption:
Water sorption is the amount of water that a
material absorbs over time per unit of surface
area or volume.
Materials with higher filler contents exhibit
lower water absorption values than materials
with lower filler content.
Incompletely cured composites exhibit higher
water absorption values causing bulk
discoloration.
IV. Properties:

1. Linear Coefficient of Thermal
Expansion.
2. Water sorption.
3. Wear Resistance.
4. Surface Texture.
5. Radiopacity.
6. Modulus of Elasticity
7. Polymerization.
 3. Wear Resistance
Wear resistance refers to a material’s ability to
resist surface loss as a result of abrasive contact
with opposing tooth structure, restorative
material, food bolus, and such items as
toothbrush bristles and toothpicks.
Wear resistance of contemporary composite
materials is generally good.
IV. Properties:

1. Linear Coefficient of Thermal
Expansion.
2. Water sorption.
3. Wear Resistance.
4. Surface Texture.
5. Radiopacity.
6. Modulus of Elasticity
7. Polymerization.
4. Surface Texture

Surface texture is the smoothness of the
surface of the restorative material.
Nanohybrid and Nanofill composites also
provide surface textures that are polishable,
esthetically satisfying, and compatible with
soft tissues.
So, esthetical and biocompatible.
IV. Properties:

1. Linear Coefficient of Thermal
Expansion.
2. Water sorption.
3. Wear Resistance.
4. Surface Texture.
5. Radiopacity.
6. Modulus of Elasticity
7. Polymerization.
 5. Radiopacity
Esthetic restorative materials must be sufficiently
radiopaque so that the radiolucent image of recurrent
caries around or under a restoration can be seen more
easily in a radiograph.
Most composites contain radiopaque fillers such as
barium glass to make the material radiopaque.
IV. Properties:

1. Linear Coefficient of Thermal
Expansion.
2. Water sorption.
3. Wear Resistance.
4. Surface Texture.
5. Radiopacity.
6. Modulus of Elasticity
7. Polymerization.
 6. Modulus of Elasticity
is the stiffness of a material. A material having a higher
modulus is more rigid; conversely, a material with a
lower modulus is more flexible.
Clinical application:
This is particularly true for Class V restorations in teeth
experiencing heavy occlusal forces, where stress
concentrations exist in the cervical area. Such stress can
cause tooth flexure that can disrupt the bonding
interface.
Using a more flexible material such as a microfill
composite allows the restorations to bend with the
tooth, better protecting the bonding interface
Abfraction
A 17-year-old girl presents to the Dental Clinic
complaining of black spot on facial surface of
upper front tooth. Clinical examination reveals
small size cervical caries in teeth # 22. Class V
composite restoration is the treatment of choice.
Which composite is the best used?

Nanofilled/Nanohybrid
Thank You