Restorative and esthetic dental materials
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About This Presentation
Restorative and esthetic dental materials
Slide Content
Copyright 2003, Elsevier Science (USA). All rights reserved.
Chapter 43
Restorative and Esthetic
Dental Materials
Copyright 2003, Elsevier Science (USA).
All rights reserved. No part of this product may be reproduced or transmitted in any
form or by any means, electronic or mechanical, including input into or storage in any
information system, without permission in writing from the publisher.
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Produced in the United States of America
ISBN 0-7216-9770-4
Chapter 43
Restorative and Esthetic
Dental Materials
Copyright 2003, Elsevier Science (USA).
All rights reserved. No part of this product may be reproduced or transmitted in any
form or by any means, electronic or mechanical, including input into or storage in any
information system, without permission in writing from the publisher.
PowerPoint
®
presentation slides may be displayed and may be reproduced in print
form for instructional purposes only, provided a proper copyright notice appears on
the last page of each print-out.
Produced in the United States of America
ISBN 0-7216-9770-4
Copyright 2003, Elsevier Science (USA). All rights reserved.
Introduction
Restorative dental materials fulfill an important
role in the way dentistry is delivered today.
Introduction
Restorative dental materials fulfill an important
role in the way dentistry is delivered today.
Copyright 2003, Elsevier Science (USA). All rights reserved.
ADA: criteria for a new material
•Must not be poisonous or harmful to the body.
•Must not be harmful or irritating to the tissues
of the oral cavity.
•Must help protect the tooth and oral tissues of
the oral cavity.
•Must resemble the natural dentition.
•Must be easily formed and placed in the
mouth.
Standardization of Dental Materials
ADA: criteria for a new material
•Must not be poisonous or harmful to the body.
•Must not be harmful or irritating to the tissues
of the oral cavity.
•Must help protect the tooth and oral tissues of
the oral cavity.
•Must resemble the natural dentition.
•Must be easily formed and placed in the
mouth.
Standardization of Dental Materials
Copyright 2003, Elsevier Science (USA). All rights reserved.
Mechanical properties must withstand the
biting and chewing force in the posterior area
of the mouth.
Force is any push or pull on matter.
Stress is the reaction within the material that
can cause distortion.
Strain is the change produced within the
material that occurs as the result of stress.
Properties of Dental Materials
Mechanical properties must withstand the
biting and chewing force in the posterior area
of the mouth.
Force is any push or pull on matter.
Stress is the reaction within the material that
can cause distortion.
Strain is the change produced within the
material that occurs as the result of stress.
Properties of Dental Materials
Copyright 2003, Elsevier Science (USA). All rights reserved.
Types of stress and strain:
•Tensile stress pulls and stretches the
material.
•Compressive stress pushes the material
together.
•Shear stress is the breakdown of the
material.
Mechanical Properties
Types of stress and strain:
•Tensile stress pulls and stretches the
material.
•Compressive stress pushes the material
together.
•Shear stress is the breakdown of the
material.
Mechanical Properties
Copyright 2003, Elsevier Science (USA). All rights reserved.
A change in temperature in the oral cavity due
to either a hot or cold product.
Contraction and expansion
•Dental materials will contract or expand at
their own rate.
•Change in temperature can cause a dental
material to pull away from the tooth.
•Microleakage
•Faulty restoration
Thermal Changes
A change in temperature in the oral cavity due
to either a hot or cold product.
Contraction and expansion
•Dental materials will contract or expand at
their own rate.
•Change in temperature can cause a dental
material to pull away from the tooth.
•Microleakage
•Faulty restoration
Thermal Changes
Copyright 2003, Elsevier Science (USA). All rights reserved.
An electrical current, or galvanic action, is
created when two different or dissimilar metals
are present in the oral cavity.
Conditions:
•Saliva.
•Two metallic components of different
composition.
•Electrical current.
•Galvanic action, or shock, is the coming
together of all conditions.
Electrical Properties
An electrical current, or galvanic action, is
created when two different or dissimilar metals
are present in the oral cavity.
Conditions:
•Saliva.
•Two metallic components of different
composition.
•Electrical current.
•Galvanic action, or shock, is the coming
together of all conditions.
Electrical Properties
Copyright 2003, Elsevier Science (USA). All rights reserved.
Reaction a metal has when it comes into
contact with corrosive products.
Solubility is the degree to which a substance
will dissolve in a given amount of another
substance.
Corrosive Properties
Reaction a metal has when it comes into
contact with corrosive products.
Solubility is the degree to which a substance
will dissolve in a given amount of another
substance.
Corrosive Properties
Copyright 2003, Elsevier Science (USA). All rights reserved.
Flow:
•The dental material must be pliable enough
to be placed in the preparation.
Adhesion:
•The force that causes unlike materials to
adhere to each other.
Wetting is the ability of a liquid to flow over the
surface.
Viscosity is the property of a liquid that
causes it not to flow easily.
Application Properties
Flow:
•The dental material must be pliable enough
to be placed in the preparation.
Adhesion:
•The force that causes unlike materials to
adhere to each other.
Wetting is the ability of a liquid to flow over the
surface.
Viscosity is the property of a liquid that
causes it not to flow easily.
Application Properties
Copyright 2003, Elsevier Science (USA). All rights reserved.
Surface characteristics is where a liquid flows
more easily on a rough surface than on a very
smooth surface.
Film thickness: In general, the thinner the film, the
stronger the adhesive junction.
Retention is the ability to hold two things firmly
together when they will not adhere to each other.
Curing
•Auto-cured material hardens as the result of a
chemical reaction of the materials.
•Light-cured material does not harden until it has
been exposed to a curing light.
Application Properties- cont’d
Surface characteristics is where a liquid flows
more easily on a rough surface than on a very
smooth surface.
Film thickness: In general, the thinner the film, the
stronger the adhesive junction.
Retention is the ability to hold two things firmly
together when they will not adhere to each other.
Curing
•Auto-cured material hardens as the result of a
chemical reaction of the materials.
•Light-cured material does not harden until it has
been exposed to a curing light.
Application Properties- cont’d
Copyright 2003, Elsevier Science (USA). All rights reserved.
Restorative: To replace or bring something
back to its natural appearance and function.
Esthetic: To replace or bring something back
to its pleasing appearance.
Restorative and Esthetic Materials
Restorative: To replace or bring something
back to its natural appearance and function.
Esthetic: To replace or bring something back
to its pleasing appearance.
Restorative and Esthetic Materials
Copyright 2003, Elsevier Science (USA). All rights reserved.
Restorative materials that are applied to the
tooth while the material is pliable and able to
carve and finish.
•Amalgam
•Composite resins
•Glass ionomer
•Intermediate restorative materials
•Tooth-whitening products
Direct Restorations
Restorative materials that are applied to the
tooth while the material is pliable and able to
carve and finish.
•Amalgam
•Composite resins
•Glass ionomer
•Intermediate restorative materials
•Tooth-whitening products
Direct Restorations
Copyright 2003, Elsevier Science (USA). All rights reserved.
Amalgam is a safe, affordable, and durable
material that is used predominantly to restore
premolars and molars (Figure 43-8).
Amalgam
Amalgam is a safe, affordable, and durable
material that is used predominantly to restore
premolars and molars (Figure 43-8).
Amalgam
Copyright 2003, Elsevier Science (USA). All rights reserved.
Fig. 43-8 Packing an amalgam carrier.
Fig. 43-8 Packing an amalgam carrier.
Copyright 2003, Elsevier Science (USA). All rights reserved.
In individuals of all ages.
In stress-bearing areas of the mouth.
When there is severe destruction of tooth
structure.
As a foundation.
When personal oral hygiene is poor.
When moisture control is problematic.
When cost is an overriding patient concern.
Indications for Using Amalgam
In individuals of all ages.
In stress-bearing areas of the mouth.
When there is severe destruction of tooth
structure.
As a foundation.
When personal oral hygiene is poor.
When moisture control is problematic.
When cost is an overriding patient concern.
Indications for Using Amalgam
Copyright 2003, Elsevier Science (USA). All rights reserved.
Indications for Not Using Amalgam
Esthetics is important.
Patient has a history of allergy to mercury or
other amalgam components.
The cost of other restorative materials or
treatment options is not a factor.
Indications for Not Using Amalgam
Esthetics is important.
Patient has a history of allergy to mercury or
other amalgam components.
The cost of other restorative materials or
treatment options is not a factor.
Copyright 2003, Elsevier Science (USA). All rights reserved.
Mercury (43% to 54%)
Alloy powder (57% to 46%)
•Silver, which gives it its strength.
•Tin for its workability and strength.
•Copper for its strength and corrosion
resistance.
•Zinc to suppress oxidation.
Chemical Makeup of Amalgam
Mercury (43% to 54%)
Alloy powder (57% to 46%)
•Silver, which gives it its strength.
•Tin for its workability and strength.
•Copper for its strength and corrosion
resistance.
•Zinc to suppress oxidation.
Chemical Makeup of Amalgam
Copyright 2003, Elsevier Science (USA). All rights reserved.
Harm to patients: Essentially harmless.
The exception is with patients who have many
amalgam restorations, or a high sensitivity to
metals.
Harm to Dental Personnel: Health
concerns with high exposure to mercury, not
amalgam.
•Tremors
•Kidney dysfunction
•Depression
•Nervous system disorders
Issues Concerning Amalgam
Harm to patients: Essentially harmless.
The exception is with patients who have many
amalgam restorations, or a high sensitivity to
metals.
Harm to Dental Personnel: Health
concerns with high exposure to mercury, not
amalgam.
•Tremors
•Kidney dysfunction
•Depression
•Nervous system disorders
Issues Concerning Amalgam
Copyright 2003, Elsevier Science (USA). All rights reserved.
Do not contact mercury with your skin.
Protect against spillage during trituration.
Keep lid closed during trituration.
Do not discard scrap amalgam into waste
containers.
Collect all scrap amalgam and store under water
or photographic fixer solutions in a closed
container.
Amalgam Hygiene
Do not contact mercury with your skin.
Protect against spillage during trituration.
Keep lid closed during trituration.
Do not discard scrap amalgam into waste
containers.
Collect all scrap amalgam and store under water
or photographic fixer solutions in a closed
container.
Amalgam Hygiene
Copyright 2003, Elsevier Science (USA). All rights reserved.
Capsules (600 mg of alloy): For small or
single‑surface restorations.
Capsules (800 mg of alloy): For larger
restorations.
Trituration: The process by which the mercury
and alloy are mixed together to form the mass
of amalgam.
Preparation of Amalgam
Capsules (600 mg of alloy): For small or
single‑surface restorations.
Capsules (800 mg of alloy): For larger
restorations.
Trituration: The process by which the mercury
and alloy are mixed together to form the mass
of amalgam.
Preparation of Amalgam
Copyright 2003, Elsevier Science (USA). All rights reserved.
1.Mixed amalgam placed in amalgam well.
2.Amalgam carried to the prepared tooth.
3.Amalgam placed in increments in the
prepared tooth.
4.Each increment is condensed immediately.
5.Carvers are used to carve anatomy into the
amalgam.
6.A burnisher is used to smooth the amalgam.
7.The new restorations occlusion is checked.
Direct Application of Amalgam
1.Mixed amalgam placed in amalgam well.
2.Amalgam carried to the prepared tooth.
3.Amalgam placed in increments in the
prepared tooth.
4.Each increment is condensed immediately.
5.Carvers are used to carve anatomy into the
amalgam.
6.A burnisher is used to smooth the amalgam.
7.The new restorations occlusion is checked.
Direct Application of Amalgam
Copyright 2003, Elsevier Science (USA). All rights reserved.
Becoming the most widely accepted material of
choice by dentists and patients because of their
esthetic qualities and new advances in their
strength (Figure 43-13).
Composite Resins
Becoming the most widely accepted material of
choice by dentists and patients because of their
esthetic qualities and new advances in their
strength (Figure 43-13).
Composite Resins
Copyright 2003, Elsevier Science (USA). All rights reserved.
Fig. 43-13 Resins supplied in a syringe.
Fig. 43-13 Resins supplied in a syringe.
Copyright 2003, Elsevier Science (USA). All rights reserved.
Withstand the environments of the oral cavity.
Be easily shaped to the anatomy of a tooth.
Match the natural tooth color.
Be bonded directly to the tooth surface.
Indications for Using Composite Resins
Withstand the environments of the oral cavity.
Be easily shaped to the anatomy of a tooth.
Match the natural tooth color.
Be bonded directly to the tooth surface.
Indications for Using Composite Resins
Copyright 2003, Elsevier Science (USA). All rights reserved.
Resin matrix
•Dimethacrylate, referred to as BIS‑GMA
•Monomer used to make synthetic resins
•Polymerization additives
•Allow the material to take form through a
chemical process
•Initiator
•Accelerator
•Retarder
•Ultraviolet (UV) stabilizers
Chemical Makeup of Composite Resins
Resin matrix
•Dimethacrylate, referred to as BIS‑GMA
•Monomer used to make synthetic resins
•Polymerization additives
•Allow the material to take form through a
chemical process
•Initiator
•Accelerator
•Retarder
•Ultraviolet (UV) stabilizers
Chemical Makeup of Composite Resins
Copyright 2003, Elsevier Science (USA). All rights reserved.
Fillers Add the strength and characteristics
necessary for use as a restorative material.
Inorganic fillers
•Quartz
•Glass
•Silica
•Colorants
Chemical Makeup of Composite
Resins-cont’d
Fillers Add the strength and characteristics
necessary for use as a restorative material.
Inorganic fillers
•Quartz
•Glass
•Silica
•Colorants
Chemical Makeup of Composite
Resins-cont’d
Copyright 2003, Elsevier Science (USA). All rights reserved.
A coupling agent strengthens the resin by
chemically bonding the filler to the resin matrix.
•Organosilane compound
Chemical Makeup of Composite
Resins-cont’d
A coupling agent strengthens the resin by
chemically bonding the filler to the resin matrix.
•Organosilane compound
Chemical Makeup of Composite
Resins-cont’d
Copyright 2003, Elsevier Science (USA). All rights reserved.
Types of Composites
Macrofilled composites contain the largest of
filler particles, providing greater strength but a
duller, rougher surface.
Microfilled composites: The inorganic filler is
much smaller and is capable of producing a
highly polishee, finished restoration, which is
used primarily in anterior restoration.
Hybrid composites contain both macrofill and
microfill particles.
Types of Composites
Macrofilled composites contain the largest of
filler particles, providing greater strength but a
duller, rougher surface.
Microfilled composites: The inorganic filler is
much smaller and is capable of producing a
highly polishee, finished restoration, which is
used primarily in anterior restoration.
Hybrid composites contain both macrofill and
microfill particles.
Copyright 2003, Elsevier Science (USA). All rights reserved.
The process in which the resin material is
changed from a plastic state into a hardened
restoration.
Polymerization of Composite Resins
• Auto-Cured
• Light-Cured
The process in which the resin material is
changed from a plastic state into a hardened
restoration.
Polymerization of Composite Resins
• Auto-Cured
• Light-Cured
Copyright 2003, Elsevier Science (USA). All rights reserved.
1.Select the shade of the tooth.
2.Express the needed amount of material onto
the treated pad or in the light-protected well.
3.Material placed in increments.
4.Material is light-cured.
5.Material is finished and polished.
Direct Application of Composite Resins
1.Select the shade of the tooth.
2.Express the needed amount of material onto
the treated pad or in the light-protected well.
3.Material placed in increments.
4.Material is light-cured.
5.Material is finished and polished.
Direct Application of Composite Resins
Copyright 2003, Elsevier Science (USA). All rights reserved.
1.Reduction of the material is completed by the
use of a white stone or a finishing diamond.
2.Fine finishing is completed with carbide
finishing burs and diamond burs.
3.Polish with medium discs and finish with the
superfine discs.
4.Finishing strips assist in the polishing of the
interproximal surfaces.
5.Use polishing paste with a rubber cup.
Steps in Finishing a Composite Restoration
1.Reduction of the material is completed by the
use of a white stone or a finishing diamond.
2.Fine finishing is completed with carbide
finishing burs and diamond burs.
3.Polish with medium discs and finish with the
superfine discs.
4.Finishing strips assist in the polishing of the
interproximal surfaces.
5.Use polishing paste with a rubber cup.
Steps in Finishing a Composite Restoration
Copyright 2003, Elsevier Science (USA). All rights reserved.
Glass ionomer is a versatile material with
chemical properties allowing it to be a
restorative material, liner, bonding agent, and
permanent cement.
Glass Ionomer Materials
Glass ionomer is a versatile material with
chemical properties allowing it to be a
restorative material, liner, bonding agent, and
permanent cement.
Glass Ionomer Materials
Copyright 2003, Elsevier Science (USA). All rights reserved.
Primary teeth.
Final restorations in non-stress areas.
Intermediate restorations.
Core material for a buildups.
Long-term temporary restorations.
Indications for Using Glass Ionomers
Primary teeth.
Final restorations in non-stress areas.
Intermediate restorations.
Core material for a buildups.
Long-term temporary restorations.
Indications for Using Glass Ionomers
Copyright 2003, Elsevier Science (USA). All rights reserved.
The ability to chemically bind to the teeth.
No need to prepare the tooth structure as
extensively as for preparing for an amalgam or
composite resin.
The release of fluoride after its final setting.
Qualities of Glass Ionomers
The ability to chemically bind to the teeth.
No need to prepare the tooth structure as
extensively as for preparing for an amalgam or
composite resin.
The release of fluoride after its final setting.
Qualities of Glass Ionomers
Copyright 2003, Elsevier Science (USA). All rights reserved.
Glass Ionomer
Glass
•Ceramic particles
•Glassy matrix
Acrylic acid
Tartaric acid
Maleic acid
Metal-reinforced glass ionomer
•Silver-tin alloy + Glass ionomer
Properties of Glass Ionomers
Glass Ionomer
Glass
•Ceramic particles
•Glassy matrix
Acrylic acid
Tartaric acid
Maleic acid
Metal-reinforced glass ionomer
•Silver-tin alloy + Glass ionomer
Properties of Glass Ionomers
Copyright 2003, Elsevier Science (USA). All rights reserved.
Powder and Liquid: Manually mixed together
on a treated paper pad.
Light-Protected Tubes: Dispensed onto a
treated paper pad.
Paste/Paste System: Mixed for application.
Premeasured Capsule: Triturated for
application.
Supply of Glass Ionomers
Powder and Liquid: Manually mixed together
on a treated paper pad.
Light-Protected Tubes: Dispensed onto a
treated paper pad.
Paste/Paste System: Mixed for application.
Premeasured Capsule: Triturated for
application.
Supply of Glass Ionomers
Copyright 2003, Elsevier Science (USA). All rights reserved.
Designed to maintain or restore function to a
tooth or teeth and keep the patient comfortable
for a period of time.
Temporary Restorative Materials
Designed to maintain or restore function to a
tooth or teeth and keep the patient comfortable
for a period of time.
Temporary Restorative Materials
Copyright 2003, Elsevier Science (USA). All rights reserved.
Reduce sensitivity and discomfort of a tooth to
determine its diagnosis.
Maintain the function and esthetics of a tooth
until a permanent restoration can be placed.
Protect the margins of a prepared tooth that will
receive a permanent casting at a later time.
Prevent shifting of the adjacent or opposing
teeth because of open space.
Indications for Using a Temporary
Restorative Material
Reduce sensitivity and discomfort of a tooth to
determine its diagnosis.
Maintain the function and esthetics of a tooth
until a permanent restoration can be placed.
Protect the margins of a prepared tooth that will
receive a permanent casting at a later time.
Prevent shifting of the adjacent or opposing
teeth because of open space.
Indications for Using a Temporary
Restorative Material
Copyright 2003, Elsevier Science (USA). All rights reserved.
Composition:
•Zinc-Oxide gives strength and durability.
•Eugenol has a sedative effect.
Intermediate Restorative Materials (IRM)
Composition:
•Zinc-Oxide gives strength and durability.
•Eugenol has a sedative effect.
Intermediate Restorative Materials (IRM)
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Restoration of primary teeth
Restorative emergencies
Caries management program
Supply of IRM
•Powder/liquid
•Premeasured capsules
Indications for Using IRM
Restoration of primary teeth
Restorative emergencies
Caries management program
Supply of IRM
•Powder/liquid
•Premeasured capsules
Indications for Using IRM
Copyright 2003, Elsevier Science (USA). All rights reserved.
Restorative material that covers the major
portion, if not the entire clinical portion of a
tooth or several teeth for a period of time.
Provisional Restorative Materials
Restorative material that covers the major
portion, if not the entire clinical portion of a
tooth or several teeth for a period of time.
Provisional Restorative Materials
Copyright 2003, Elsevier Science (USA). All rights reserved.
Auto-cured acrylic (methylmethacrylate)
Light-cured resin
Process of application
•Material is placed in either an alginate
impression or a vacuum-formed tray.
•Material is seated over the prepared tooth
and allowed to cure.
•Occlusion is adjusted.
•Material is cemented in place with temporary
cement.
Types of Materials Used
Auto-cured acrylic (methylmethacrylate)
Light-cured resin
Process of application
•Material is placed in either an alginate
impression or a vacuum-formed tray.
•Material is seated over the prepared tooth
and allowed to cure.
•Occlusion is adjusted.
•Material is cemented in place with temporary
cement.
Types of Materials Used
Copyright 2003, Elsevier Science (USA). All rights reserved.
The process of applying a material on anterior
teeth for a prescribed period of time to whiten
the color of one’s teeth.
Tooth Whitening Materials
The process of applying a material on anterior
teeth for a prescribed period of time to whiten
the color of one’s teeth.
Tooth Whitening Materials
Copyright 2003, Elsevier Science (USA). All rights reserved.
Teeth discolored
Aging
Consumption of staining substances
Trauma
Tetracycline staining
Excessive fluoride
Nerve degeneration
Old restorations
Indications for Using Tooth-Whitening
Products
Teeth discolored
Aging
Consumption of staining substances
Trauma
Tetracycline staining
Excessive fluoride
Nerve degeneration
Old restorations
Indications for Using Tooth-Whitening
Products
Copyright 2003, Elsevier Science (USA). All rights reserved.
Carbamide Peroxide: When the carbamide
peroxide breaks down, oxygen enters the
enamel and dentin and bleaches the colored
substances.
Concentrations: 10%, 16%, 22%
Tooth-Whitening Products
Carbamide Peroxide: When the carbamide
peroxide breaks down, oxygen enters the
enamel and dentin and bleaches the colored
substances.
Concentrations: 10%, 16%, 22%
Tooth-Whitening Products
Copyright 2003, Elsevier Science (USA). All rights reserved.
Types of dental restorations that dental
laboratory technicians create in the dental
laboratory.
These restorations are also referred to as
castings, cannot be reshaped, and are carved
once they are in this stage.
Indirect Restorations
Types of dental restorations that dental
laboratory technicians create in the dental
laboratory.
These restorations are also referred to as
castings, cannot be reshaped, and are carved
once they are in this stage.
Indirect Restorations
Copyright 2003, Elsevier Science (USA). All rights reserved.
By combining gold with other metals to form an
alloy, it creates the characteristics and
hardness required as an excellent choice for
an indirect restoration.
•Gold
•Palladium
•Platinum
Gold Alloys
By combining gold with other metals to form an
alloy, it creates the characteristics and
hardness required as an excellent choice for
an indirect restoration.
•Gold
•Palladium
•Platinum
Gold Alloys
Copyright 2003, Elsevier Science (USA). All rights reserved.
Soft, Type I alloys are used for casting
inlays subject to slight stress during
mastication.
Medium, Type II alloys can be used for
practically all types of cast inlays and possibly
posterior bridge abutments.
Hard, Type III alloys are acceptable for
inlays, full crowns, three‑quarter crowns, and
anterior or posterior bridge abutments.
Extra-hard, Type IV alloys are designed
for cast-removable partial dentures.
Types of Casting Alloys
Soft, Type I alloys are used for casting
inlays subject to slight stress during
mastication.
Medium, Type II alloys can be used for
practically all types of cast inlays and possibly
posterior bridge abutments.
Hard, Type III alloys are acceptable for
inlays, full crowns, three‑quarter crowns, and
anterior or posterior bridge abutments.
Extra-hard, Type IV alloys are designed
for cast-removable partial dentures.
Types of Casting Alloys
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Ceramics are compounds that involve a
combination of metallic and nonmetallic
elements, creating strength and aesthetics.
Ceramics
Ceramics are compounds that involve a
combination of metallic and nonmetallic
elements, creating strength and aesthetics.
Ceramics
Copyright 2003, Elsevier Science (USA). All rights reserved.
Porcelain fused to metal (PFM)
Porcelain bonded to metal (PBM)
Ceramco-metal restorations
Porcelain-metal restorations (P-M)
Types of Ceramic Restorations
Porcelain fused to metal (PFM)
Porcelain bonded to metal (PBM)
Ceramco-metal restorations
Porcelain-metal restorations (P-M)
Types of Ceramic Restorations
Copyright 2003, Elsevier Science (USA). All rights reserved.
Type of ceramic that is most commonly used in
dentistry. It combines strength, translucence
and the ability to match the natural tooth color.
Porcelain
Type of ceramic that is most commonly used in
dentistry. It combines strength, translucence
and the ability to match the natural tooth color.
Porcelain
Copyright 2003, Elsevier Science (USA). All rights reserved.
The shading of colors matches the tooth color
well.
It esthetically improves the appearance of
anterior teeth.
It has the strength of metal.
The material is a good insulator.
The material has a low coefficient of thermal
expansion.
Indications for Using Porcelain
The shading of colors matches the tooth color
well.
It esthetically improves the appearance of
anterior teeth.
It has the strength of metal.
The material is a good insulator.
The material has a low coefficient of thermal
expansion.
Indications for Using Porcelain
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