Indian Dental Academy: will be one of the most relevant and exciting training
center with best faculty and flexible training programs for dental
professionals who wish to advance in their dental practice,Offers certified
courses in Dental implants,Orthodontics,Endodontics,Cosmetic Dentistry,
Prosthetic Dentistry, Periodontics and General Dentistry.
4. 2) Castable Ceramics
( Using casting & ceramming)
Flouromicas e.g.: Dicor
Apatite based Glass-Ceramics e.g. Cera Pearl
Other Glass-Ceramics
Lithia based
Calcium phosphate based
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5. 3) Machinable Ceramics
A) Analogous Systems (Pantograph systems – copying methods)
1)Copy milling / grinding techniques
a) Mechanical e.g. : Celay
b)Automatic e.g:Ceramatic II. DCP
2) Erosive techniques
a) Sono-erosion e.g: DFE, Erosonic
b) Spark-erosion e.g: DFE, Procera
B)Digital systems (CAD / CAM):
1) Direct e.g.: Cerec 1 & Cerec 2
2) Indirect e.g. : Cicero, Denti CAD, Automill, DCS-Presidentwww.indiandentalacademy.comwww.indiandentalacademy.com
7. 5. Infiltrated Ceramics
(slip-casting, sintering & glass infiltration)
Alumina based e.g: In-Ceram Alumina
Spinel based e.g: In-Ceram Spinell
Zirconia based e.g.: In-Ceram Zirconia
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8. Porcelain Jacket Crown
Land ---- high Feldspathic Porcelain with platinum foilLand ---- high Feldspathic Porcelain with platinum foil
matrixmatrix
Excellent estheticsExcellent esthetics
Difference in modulus of elasticity---supportive roleDifference in modulus of elasticity---supportive role
played by the preparation is limited.played by the preparation is limited.
Poor flexure strengthPoor flexure strength
Poor marginal adaptabilityPoor marginal adaptability
Thus to increase their reliability in service they need toThus to increase their reliability in service they need to
have surfaces that are flawless and they need tohave surfaces that are flawless and they need to
stiffened.stiffened.
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9. Requirements of a porcelain jacket crown TechniqueRequirements of a porcelain jacket crown Technique
Should not be opacifiedShould not be opacified
Should not contain quartz and light transmission of the body andShould not contain quartz and light transmission of the body and
veneered porcelain should approach that of dentine and enamelveneered porcelain should approach that of dentine and enamel
respectively.respectively.
Reduction of gross internal subsurface and surface defectsReduction of gross internal subsurface and surface defects
Accurately adapted crown marginsAccurately adapted crown margins
Relief of 50Relief of 50µm for cementµm for cement
Matched COTEMatched COTE
Method of stiffening without optically dense backgroundsMethod of stiffening without optically dense backgrounds
Good cement retentionGood cement retention
Future RCT scopeFuture RCT scope
Should not obscure pulp outline in radiographShould not obscure pulp outline in radiograph
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10. IndicationsIndications
Conservation of tooth structureConservation of tooth structure
Maintenance of periodontal healthMaintenance of periodontal health
EstheticsEsthetics
Lower incisors with available spaceLower incisors with available space
Limited use in premolars with protectedLimited use in premolars with protected
occlusion.occlusion.
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11. ContraindicationsContraindications
Para-functional activityPara-functional activity
Deflective malocclusionDeflective malocclusion
Unfavorable occlusal clearanceUnfavorable occlusal clearance
Insufficient tooth supportInsufficient tooth support
Tooth preparation with sudden change in shapeTooth preparation with sudden change in shape
Molar teeth----?????Molar teeth----?????
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12. Technique employed to reinforce porcelainTechnique employed to reinforce porcelain
jacket crownsjacket crowns
Platinum- bonded alumina crownsPlatinum- bonded alumina crowns
Electroformed gold matrixElectroformed gold matrix
Gold coated platinum foilGold coated platinum foil
Metal-ceramicMetal-ceramic
Alumina-reinforced porcelain crownsAlumina-reinforced porcelain crowns
Aluminous crowns reinforced with sintered highAluminous crowns reinforced with sintered high
alumina profilesalumina profiles
Previous refractory die techniquePrevious refractory die technique
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13. Aluminous Core CeramicsAluminous Core Ceramics
High strength ceramic core (High strength ceramic core (Mc Lean and Hughes -1965Mc Lean and Hughes -1965))
Aluminum oxide crystals dispersed in a glassy matrix (40-Aluminum oxide crystals dispersed in a glassy matrix (40-
50%)50%)
High fracture toughness and hardnessHigh fracture toughness and hardness
Technique involves use of an opaque inner core containingTechnique involves use of an opaque inner core containing
50% alumina for strength and the core was veneered with50% alumina for strength and the core was veneered with
15% and 5% crystalline alumina for esthetic body and15% and 5% crystalline alumina for esthetic body and
enamel porcelain respectively.enamel porcelain respectively.
Large sintering shrinkage and decreased translucencyLarge sintering shrinkage and decreased translucencywww.indiandentalacademy.comwww.indiandentalacademy.com
14. Fabrication procedureFabrication procedure
Diamond shape foil is adapted to the facialDiamond shape foil is adapted to the facial
surfacesurface
Two cuts are made, one on each incisal cornerTwo cuts are made, one on each incisal corner
and a triangle of foil is removed by cutting atand a triangle of foil is removed by cutting at
45° toward the corners.45° toward the corners.
Foil is folded on to the lingual surface andFoil is folded on to the lingual surface and
burnished.burnished.
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15. Foil is gathered on lingual surface with tweezersFoil is gathered on lingual surface with tweezers
and adapted with finger pressure.and adapted with finger pressure.
Foil is trimmed to follow the lingual contour andFoil is trimmed to follow the lingual contour and
two ends are separated.two ends are separated.
One end is trimmed half the width of otherOne end is trimmed half the width of other
Long end is folded over the shorter and relievingLong end is folded over the shorter and relieving
cuts are made.cuts are made.
Three thickness joint is folded toward the shortThree thickness joint is folded toward the short
end.end.
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16. Foil is adapted with a wooden point, startingFoil is adapted with a wooden point, starting
from incisal edge and working towards margin.from incisal edge and working towards margin.
Beaver-tail burnisher, working toward theBeaver-tail burnisher, working toward the
internal angle to prevent perforation.internal angle to prevent perforation.
Matrix is removed with sticky wax and annealedMatrix is removed with sticky wax and annealed
in a Bunsen flame.in a Bunsen flame.
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18. Platinum matrix is heated to drive off dissolvedPlatinum matrix is heated to drive off dissolved
gases, and the core material is built up.gases, and the core material is built up.
A thin blade is used to form a cervical ditchA thin blade is used to form a cervical ditch
which will matrix distortion during firing andwhich will matrix distortion during firing and
finally the foil is readapted and ditch is filled withfinally the foil is readapted and ditch is filled with
additional porcelainadditional porcelain..
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19. Captek systemCaptek system
Coping is produced from twoCoping is produced from two
metal impregnated waxmetal impregnated wax
sheets that are adapted to asheets that are adapted to a
die and fired.die and fired.
The first sheet forms aThe first sheet forms a
porous gold-platinum-porous gold-platinum-
palladium layer that ispalladium layer that is
impregnated with 97% goldimpregnated with 97% gold
when the second sheet iswhen the second sheet is
fired.fired.
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21. HICERAM
19851985 – Vita Zahnfabrik, Germany.– Vita Zahnfabrik, Germany.
Similar to traditional alumina but higher aluminaSimilar to traditional alumina but higher alumina
content.content.
Specific size distribution of crystalline phase ---Specific size distribution of crystalline phase ---
without worsening opacitywithout worsening opacity
Flexure strength of 155 MpaFlexure strength of 155 Mpa
Epoxy die ---- swaged resin copingEpoxy die ---- swaged resin coping
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22. Indications for HiceramIndications for Hiceram
Anterior crownsAnterior crowns
Posteriors with favorable occlusalPosteriors with favorable occlusal
Patient allergic to metal corePatient allergic to metal core
Some amount of light reflection is requiredSome amount of light reflection is required
from tooth.from tooth.
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23. New foil systemNew foil system
Modifications of original foil crownModifications of original foil crown
Layered noble metal foilsLayered noble metal foils
Strength – 30-80% of metal ceramic systemStrength – 30-80% of metal ceramic system
ExamplesExamples
RenaissanceRenaissance
SunriseSunrise
FlexobondFlexobond
PlatideckPlatideck
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24. MAGNESIA BASED CORE PORCELAIN
High expansion magnesia core material compatibleHigh expansion magnesia core material compatible
with porcelain.with porcelain.
Flexure strength ( 131 MPa)
Allows to veneer it with more widely available
porcelain ( match of COTE)
Glazing strengthen the magnesia core
Highly opaque
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25. Feldspathic porcelain higher leucite tetragonal crystalFeldspathic porcelain higher leucite tetragonal crystal
content.content.
The leucite and glassy components are fused during the bakingThe leucite and glassy components are fused during the baking
process…at 1020ºC.process…at 1020ºC.
Leucite reinforced porcelain
(OPTEC HSP)
45% vol
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26. ADVANTAGESADVANTAGES
☺ More esthetic due to a more translucent core.More esthetic due to a more translucent core.
☺ Greater strength. (104 MPa)Greater strength. (104 MPa)
☺ No special processing equipment required.No special processing equipment required.
DISADVANTAGESDISADVANTAGES
Increased leucite content contributes to theIncreased leucite content contributes to the
relatively high wear of opposing teethrelatively high wear of opposing teeth
Potential marginal inaccuracyPotential marginal inaccuracy
USESUSES
Inlays,onlays,low stress crowns.Inlays,onlays,low stress crowns.
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27. Low fusing Ceramics
In 1992 Duceram LFC was marketed as an ultra-low
fusing ceramic with amorphous glass containing
hydroxyl ions.
Hydrothermal low fusing ceramics
Greater density
Higher flexural strength ---- ion exchange
Greater fracture resistance
Low hardness --- lack of leucite crystals
Use of refractory dies.
USES: Inlays,Veneers,Full contour crowns.
( DUCERAM LFC)
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28. Slip casting ceramics
( INCERAM)
Slip casting is defined as a process used to form greenSlip casting is defined as a process used to form green
ceramic shapes by applying a slurry of ceramic particlesceramic shapes by applying a slurry of ceramic particles
and water or a special liquid to a porous substrate thereand water or a special liquid to a porous substrate there
by allowing capillary action to remove water, densify theby allowing capillary action to remove water, densify the
mass of deposited particles.mass of deposited particles.
IN CERAM (IN CERAM ( Sadoun- 1985Sadoun- 1985) is based on the slip casting) is based on the slip casting
of an alumina core with its subsequent glass infusion.of an alumina core with its subsequent glass infusion.
INCERAM ALUMINAwww.indiandentalacademy.comwww.indiandentalacademy.com
29. Fabrication procedure
Duplication of master die and preparation ofDuplication of master die and preparation of
refractory dierefractory die
Application of alumina slip 38gm:5 mlApplication of alumina slip 38gm:5 ml
( ultrasonic agitation- 3 minutes)( ultrasonic agitation- 3 minutes)
Initial firing cycle of long duration to 120Initial firing cycle of long duration to 120°C, then°C, then
alumina is fired at 1120°C .alumina is fired at 1120°C .
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30. Paint a thick coat of appropriate shade ofPaint a thick coat of appropriate shade of
glass (lanthum aluminosilicate) mixtureglass (lanthum aluminosilicate) mixture
and fire it at 1100°C.and fire it at 1100°C.
Apply body and incisal porcelain in usualApply body and incisal porcelain in usual
manner to achieve appropriate estheticmanner to achieve appropriate esthetic
results.results.
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31. Master die Duplication with refractory material
Ultrasonic dispersion Slip application Ceramet furnace
Trimming Lanthum aluminosilicate Veneering
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32. ADVANTAGES
Flexure strength ( 450-
600 MPa) --- strongest
Accurate marginal fit
Highly dense and fewer
processing defect
Highly strong .. Used for
fixed dental prosthesis
DISADVANTAGES
Opaque alumina
Special technique
Technique sensitive
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33. INCERAM SPINELLINCERAM SPINELL
Porous core is fabricated from the magnesiumPorous core is fabricated from the magnesium
alumina with specific crystalline structure.alumina with specific crystalline structure.
Light reflection and glass like shineLight reflection and glass like shine
Not as strong as conventional Inceram aluminaNot as strong as conventional Inceram alumina
(350MPa)(350MPa)
Increased translucency and biocompatibleIncreased translucency and biocompatible
Used in crowns, inlays, onlays, veneers inUsed in crowns, inlays, onlays, veneers in
esthetic areas.esthetic areas. www.indiandentalacademy.comwww.indiandentalacademy.com
34. INCERAM ZIRCONIA
33% Zirconia --- transformation toughening
Phase transformation from tetragonal to monoclinic is
stabilized at room temperature by addition of 16%
cerium oxide.
Highly strong (700 MPa)
Excellent marginal accuracy and biocompatibility
Least translucent in series
Inability to etch
Used in posterior three unit FDP’s.
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35. CASTABLE CERAMICS
FLUORO-MICASFLUORO-MICAS APATITE GLASSAPATITE GLASS OTHER GLASSOTHER GLASS
DICOR
CERAPEARL
(BIOCERAM)
Lithia based
Calcium phosphate based
These are polycrystalline materials developed for application
by casting procedures using the lost wax technique, hence
referred to as “Castable ceramics”.
They are fabricated in the vitreous (Glass or non-
crystalline/amorphous) state and converted to a ceramic
(crystalline state) by controlled crystallization using
nucleating agents during heat treatment.
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36. First commercially available castable glass-ceramic
Developed by Corning Glass Works
Dicor is a micaceous glass ceramic consist of 45% vol.
glass and 55% crystalline tetrasilicic mica.
DICOR
Glass Melt
Super cooled glass ( Room temperature)
Crystalline Glass
( dense mass with interlocking crystals)
Nucleating agents
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37. Glass ingots castable ceramic material is placed in a special
zirconia crucible (melted at 1360°C / 2600°F) and centrifugally
cast in the electronically-controlled DICOR Casting Machine.
Fabrication procedure
The transparent glass casting obtained is
amorphous and fragile. After cooling, it is
divested, sandblasted and carefully separated
from the sprue.
The wax pattern of the proposed restoration
made on the die is invested in Castable Ceramic
Investment and burned out in a conventional
burnout at 900°C for 30 mins.
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38. The transparent fragile casting is embedded in castable ceramic
embedment material in the DICOR Ceramming Furnace ( produce
controlled crystallization by internal nucleation and crystal growth
of microscopic plate like mica crystals within the glass matrix)
Ceramming
(1075 °C for 10 hours)
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39. Excellent esthetics resulting from natural translucency, light
absorption, light refraction and natural colour for the restoration.
(Chameleon effect)
Relatively high strength ( flexural strength of 152 MPa),
surface hardness (abrasion resistance) and occlusal wear similar to
enamel.
Inherent resistance to bacterial plaque
Chemical resistant
Low thermal conductivity.
Excellent marginal adaptation ( 30-60 µm)
ADVANTAGES
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40. Special and expensive equipments
Failure rates as high as 8% in the posterior region
Highly translucent --- require external veneering or
staining
More prone for stress cracking
DISADVANTAGES
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41. CASTABLE HRDROXYAPATITE GLASS CERAMICS
(CeraPearl) ( Kyocera Bioceram Group of Kyota city, Japan)
Sumiya Hobo & Iwata (1985)
Composed of CaO, P2O5, MgO, and SiO2 and traces of
other elements
Has similar crystalline microstructure to enamel but
different arrangement.
It is very white , so require external stains supplied by
Bioceram with complex glass formulation and various metal
oxides. www.indiandentalacademy.comwww.indiandentalacademy.com
42. Properties
Similar to natural enamel in composition, density,
refractive index, coefficient of thermal expansion and
hardness.
Bonding to tooth structure.
Biocompatible
Superior mechanical strength
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43.
Lithia Based Glass-Ceramic
(Olympus Castable Ceramic- OCC)
Developed by Uryu
It contains crystals of LiO.AI2O3.4SiO2 after heat
treatment.
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44. Kihara et al
It is a combination of calcium phosphate and phosphorus
pentoxide plus trace elements.
The glass ceramic is cast at 1050°C which is converted to a
crystalline ceramic by heat treating at 645°C for 12 hours.
Reported Flexural strength (166 MPa)
Hardness close to tooth structure.
Weaker than other castable ceramics
Opacity reduces the indication for use in anterior teeth.
Calcium Phosphate Glass-Ceramics
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46. CERESTORE
This shrink-free ceramic material essentially consists of Al2O3 and
MgO mixed with a Barium glass frits.
On firing crystalline transformation produces Magnesium
aluminate spinel, which occupies a greater volume than the original
mixed oxides compensates for the conventional firing shrinkage.
Good dimensional stability
Better accuracy of fit and marginal integrity
Esthetics enhanced due to the lack of metal coping
Biocompatible.
Low coefficient of thermal expansion
Advantages
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47. Complexity of the fabrication process.
Need for specialized laboratory equipment
Inadequate flexural strength (89MPa)
Poor abrasion resistance, hence not recommended in patients
with heavy bruxism or inadequate clearance.
Limitations and high clinical failure rates led to its withdrawal
from the market. It underwent further improvement with a 70 to
90% higher flexural strength and was marketed under the
commercial name Al Ceram
Disadvantages
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48. Recrystallization of residual glass – Fracture toughness
22.5 N/m2
(32,000psi)
High polycrystalline content
Same relative thermal conductivity of core and veneer
porcelain
Low coefficient of thermal expansion - Thermal shock
resistance.
High modulus of elasticity - Low stress on cement.
AL CERAM
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49. Leucite Based Heat-Pressed Ceramics
IPS EMPRESS
Wohlwend & Scharer
Leucite used as a reinforcing phase in amount varying from
35-55% dispersed in a glassy matrix.
Particle size ( 3-10 µm)
Ceramic ingots are pressed at a high temperature (1165°C) into
a refractory mold made by lost wax technique
Two finishing techniques
Characterization / stain
Layering / veneering
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50. Fabrication procedureFabrication procedure
Wax the restoration to final contour, sprue and invest.
Heat the investment to 800°C to burn out the wax
pattern
The ceramic ingot, plunger and the entire assembly is
preheated to 1,100ºC
Insert ceramic ingot and alumina plunger in the sprue
and place the refractory in special pressing furnace.
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51. • When the temperature reaches 1150ºC after a 20 minute
holding time the plunger presses the ceramic under
vacuum (0.3-0.4 MPa) into the mold, in which it is held
under pneumatic pressure (for a 45-minute period) to
allow complete and accurate fill of the mold.
• After pressing, recover the restoration from the
investment by airborne particle abrasion, remove the
sprue, and refit on the die.
• Esthetics can be enhanced by applying an enamel layer
of matching porcelain or by adding surface
characterization.
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53. Properties :
Reported flexural strengths are in the range of 160 to I80MPa.
The increase in strength has been attributed to the pressing step
which increases the density of leucite crystals.
Subsequent heat treatments which initiate growth of additional
leucite crystals.
Uses :
Laminate veneers and full crowns for anterior teeth
Inlays, Onlays and partial coverage crowns
Complete crowns on posterior teeth.
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54. Lack of metal or an opaque ceramic core
Moderate flexural strength (120-180MPa range)
Excellent fit (low-shrinkage ceramic)
Improved esthetics (translucent, fluorescence)
Etchable
Less susceptible to fatigue and stress failure
Less abrasive to opposing tooth
Biocompatible material
Does not require ceramming to initiate the crystalline phase
of leucite crystals
ADVANTAGES
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55. Potential to fracture in posterior areas
Need for special laboratory equipment
Inability to cover the colour of a darkened tooth
preparation or post and core, since the crowns are
relatively translucent.
Difficulty in removing the crown and cementing
medium during replacement.
Compressive strength and flexural strength lesser
than metal-ceramic or glass-infiltrated (In-Ceram)
crowns.
DISADVANTAGES
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56. Feldspathic porcelain with increased leucite content
Processed by molding under pressure and heat.
Reduced particle size and Increased Crystalline Leucite content
Increase in Flexural strength (over 23,000 psi )
Increase in Compressive strength (187,320 psi).
Higher abrasion resistance
OPTEC OPC
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57. Lithium Disilicate Based Heat-Pressed Ceramics
IPS Empress 2
Consist of core of 70% Lithium disilicate crystals of 0.5-
4µm length
Lithium orthophosphate crystals ( 0.1-
0.3µm diameter
Veneering ceramic fluorapatite crystals
The apatite crystals incorporated are responsible for the
improved optical properties (translucency, light scattering)
unique chameleon effect.
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58. High biocompatibility
Excellent fracture resistance
High radiopacity
Outstanding translucency.
Uses
Anterior and posterior crown
Premolar FPD.
ADVANTAGES
• IPS Empress 2 is used with special investment material,
an EP500 fully automatic high-tech press furnace.
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59. Other applications
• Cosmopost
• IPS Empress cosmoingot -
core build-up system with the
pre-fabricated zircon oxide
root canal posts.
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61. IPS EMPRESS ESTHETIC
The most recent innovation
Developed by Lee Culp CDT, and further refined with
Lee, Matt Roberts and Jürgen Seger, CDT .
It is a high-strength, optimized Leucite reinforced
glass ceramic.
Broader ingot shade range (11 with extended shades in
the bleach range) gives more selection to Used with a
traditional staining technique or a cutback technique.
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62. When coupled with the new line of IPS Empress
Esthetic Veneering Materials and IPS Empress Esthetic
Wash Pastes, Empress Esthetic offers ceramists the
added flexibility of using a cutback technique to
fabricate life-like restorations.
Used for single units, all-ceramic restorations,
including partially layered or stained veneers, crowns,
inlays and onlays.
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63. wax-up to optimal function and
Esthetics, Spruing, investing, burn out
and heat pressing with IPS Empress
Esthetic ingot into the mold.
Varify on the cast and then
intraorally for contours ,
occlusion and accuracy of
fit.
The incisal edge of the tooth is
reduced to maintain a minimal
thickness of 0.5 mm. Facial
surfaces are reduced while
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64. Add surface characterization
using the IPS Empress Esthetic
Veneer Wash Pastes to build
up internal effects.
To obtain a three dimensional
effect, layer over this using different
values and translucencies of clear
and opal enamel IPS Empress
Esthetic Veneer Materials.
Final contouring and glazing
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65. IPS e.max
IPS e.max comprises highly aesthetic and high-IPS e.max comprises highly aesthetic and high-
strength materials for both the PRESS andstrength materials for both the PRESS and
CAD/CAM technique.CAD/CAM technique.
IPS e.max Press are new highly aesthetic lithiumIPS e.max Press are new highly aesthetic lithium
disilicate glass-ceramic ingots with optimizeddisilicate glass-ceramic ingots with optimized
homogeneity and high strength.homogeneity and high strength.
They allow the fabrication of restorations with a highThey allow the fabrication of restorations with a high
accuracy of fit.accuracy of fit.
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66. The strength of 400 MPa which has been unmatchedThe strength of 400 MPa which has been unmatched
to date by glass-ceramics enables conventionalto date by glass-ceramics enables conventional
cementation.cementation.
Lifelike aesthetics independent of the shade ofLifelike aesthetics independent of the shade of
the prepared tooththe prepared tooth
Adhesive, self-adhesive and conventionalAdhesive, self-adhesive and conventional
cementation due to the unrivalled strength.cementation due to the unrivalled strength.
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67. IPS e.max CAD is based on the same materialsIPS e.max CAD is based on the same materials
technology as IPS e.max Press and ideallytechnology as IPS e.max Press and ideally
unites the CAD/CAM processing technique withunites the CAD/CAM processing technique with
a high-performance Lithium disilicate ceramic.a high-performance Lithium disilicate ceramic.
The IPS e.max CAD blocks are used forThe IPS e.max CAD blocks are used for
fabricating tooth-coloured restorations with highfabricating tooth-coloured restorations with high
strength in an innovative manufacturing process.strength in an innovative manufacturing process.
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68. IndicationsIndications
Anterior and posterior crownsAnterior and posterior crowns
Anterior and premolar bridges (only IPSAnterior and premolar bridges (only IPS
e.max Press)e.max Press)
Implant superstructuresImplant superstructures
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69. IPS e.max ZirCADIPS e.max ZirCAD thus also fulfils clinicalthus also fulfils clinical
requirements related to masticatory forces,requirements related to masticatory forces,
particularly in the posterior region.particularly in the posterior region.
IPS e.max ZirCAD frameworks are eitherIPS e.max ZirCAD frameworks are either
veneered with IPS e.max ceram or IPS e.maxveneered with IPS e.max ceram or IPS e.max
ZirPress is pressed onto them. Consequently,ZirPress is pressed onto them. Consequently,
highly aesthetic zirconium-reinforcedhighly aesthetic zirconium-reinforced
restorations can be fabricated.restorations can be fabricated.
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70. IPS e.max Ceram
One layering ceramic for different frameworkOne layering ceramic for different framework
materials.materials.
Apart from the Chromascope an A-D shades,Apart from the Chromascope an A-D shades,
IPS e.max Ceram is also available in 4 newIPS e.max Ceram is also available in 4 new
modern Bleach shades (BL1, BL2, BL3, BL4) asmodern Bleach shades (BL1, BL2, BL3, BL4) as
well as Gingiva shades.well as Gingiva shades.
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72. Regardless of the advanced state of the 300-
year old technique of casting, each of its steps
could induce error in the final casting.
Until 1988, indirect ceramic dental restorations
were fabricated by conventional methods
(sintering, casting and pressing) and neither
were pore-free.
Pore-free restorations can be alternately
produced by machining blocks of pore-free
industrial quality ceramic.
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73. The industrially prefabricated ceramic ingots/ blanks do not
require high temperature processing and glazing, hence have
a consistently high quality.
The blanks measure approximately 9 x 9 x 13 mm and are
industrially fabricated using conventional dental porcelain
techniques.
Frit powder is mixed with distilled water, condensed into a
10 x 10 x l5 mm steel die and fired under vacuum
Classes of machinable ceramics available are:
Fine-scale feldspathic porcelain
Alumina based
Glass-ceramics
Zirconia based
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74. The tremendous advances in computers and
robotics could also be applied to revolutionize
dentistry and provide both precision and reduce
time consumption.
With the combination of optoelectronics,
computer techniques and sinter-technology, the
morphologic shape of crowns can be sculpted in
an automated way.
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76. CAD/CAM
Uses digital information about the cavity
preparation or a pattern of the restoration to
provide a computer- aided design on the video
monitor for inspection and modification.
One of the three-dimensional image for the
restoration design is accepted, the computer
translates the image into a set of instructions to
guide a milling tool (CAM) in cutting the
restoration from a block of material.
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77. Brains AG (Switzerland) --- 1985
Material Used : Vita Mark II, ProCad, Inceram Alumina and
spinell
Cerec System consists of :
A 3-D video camera (scan head)
An electronic image processor (video processor) with
memory unit (contour memory)
A digital processor (computer) connected to,
A miniature milling machine (3-axis machine)
CEREC SYSTEM
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78. CERAC Computer,3D camera and milling unit
3D Impression
3D Porcelain restoration
Milling
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79. Clinical shortcoming of Cerec 1 system
Occlusal anatomy had to be developed by the clinician
using a flame-shaped, fine-particle diamond instrument and
conventional porcelain polishing procedures were required
to finalize the restoration.
Inaccuracy of fit or large interfacial gaps.
Clinical fracture related to insufficient depth of
preparation.
Relatively poor esthetics due to the uniform colour and
lack of characterization in the materials used.
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80. Siemens ( Germany) 1994
The major changes include –
Enlargement of the grinding unit from 3 axis to 6 axis.
Upgrading of the software with more sophisticated
technology which allows machining of the occlusal surfaces
for the occlusion and the complex machining of the floor parts.
Cerec 2 system
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81. Data representation in the image memory and processing
increased by 8 times
Magnification factor increased from 8X to 12X for
improved accuracy during measurements.
Monitor can be swiveled and tilted, thus facilitating visual
control of the video image.
The improved Cerec 2 camera : new design, easy to handle,
a detachable cover (asepsis), reduction in the pixel
Improved in rigidity and grinding precision
Improved accuracy of fit
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82. Cerec - 3
Werner H Mormann (2000)
Separate form grinding unit
Rapid occlusal and functional registration
Improved marginal adaptation
Tridimensional visualization of the projected restoration
with virtual seating capability.
Network and multimedia-ready
Laser scanner for indirect restorations
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83. This is a machinable glass-ceramic composed of fluorosilica
mica crystals in a glass matrix.
The mica-plates are smaller (2 µm) than conventional Dicor
Available as Dicor MGC - light and Dicor MGC – dark
Greater flexural strength than castable Dicor
Softer than conventional Feldspathic porcelain.
Less abrasive to opposing tooth than Cerec Mark I, and
more than Cerec Mark II (invitro study results).
Dicor MGC
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84. PROCERA SYSTEM
Developed by Nobel Biocare AB, Sandvik Hard materials
AB – 1993
It is composed of densely sintered, high purity aluminium
oxide core combined with a compatible all ceram
veneering porcelain
A unique feature of the procera system is the ability of
the procera scanner to scan the surface of the prepared
tooth and transmit the data to the milling unit to produce
an enlarged die through a CAD-CAM processor.
Thus the 15-20% shrinkage during sintering will be
compensated, which will shrink during sintering to the
desired size to give an accurate fit.
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85. Procedure
Die preparation and ditching
Scanning with contact scanner
Data acquisition on computer screen
Transfer of data through computer line
Milling of enlarged die with high alumina block
Copying is veneered with body and incisal porcelains
8 basic dentine and 12 modifiers
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87. Advantages and future
Natural colour effects
Fluorescence, opalescence, and translucency
Biocompatible
Excellent marginal fit
Excellent strength
5 year warranty for single units
Developing an optical camera
Procera Cera-one---customized implant superstructure
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88. USES
Anterior and posterior crowns
Veneers, onlays and inlays.
Ceramic abutment for implant supported single crowns
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89. CERCON ( Dentsply)
ZIRCONIA CORE CERAMICS
FABRICATION
Tooth preparation Impression made Wax
pattern (0.8 mm) made on model Anchored on
to the Cercon Brain A presintered zirconia
blank is attached on to the other side of the brain
unit Unit activated..pattern scanned
Blank is rough and fine milled in an enlarged size
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90. Milled prosthesis then
removed from unit and
placed in the Cercon furnace
(1350 ºc for 6 hours)
Trimming
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91. Finished ceramic core framework
After veneering
Greatest potential fracture toughness and flexural strength(>900 MPa)www.indiandentalacademy.comwww.indiandentalacademy.com
92. LAVA ( 3M ESPE)
ZIRCONIA CORE CERAMICS
Zirconia frameworks all ceramic restoration
Tooth preparation – all ceramic guidelines
Preparations are scanned and frameworks are
milled from presintered zirconia blanks.
The size of the framework is precisely increased
to allow for the shrinkage that occur during
sintering.
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94. When used as a satellite
scanner by Lava Design
Centers, the CAD file is
electronically transferred to
the Authorized Lava™
Milling Center for milling
and sintering via Lava
Connect Application and a
dedicated server for
transfer.
Excellent marginal fit
Optimal strength
High translucency
PFMLAVA
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95. In vizion ( VIDENT)
YZ blocs
Zirconia based
Used as indirect scanning of die and CAD/CAM
High strength and fracture toughness
opaque
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96. Scanning of Die
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97. OTHER DIGITAL SYSTEMS:
THE COMET SYSTEM
The Duret System (Hanson International):
The SOPHA System
The REKOW System
The Denti CAD system
The DUX system/The Titan System
CICERO System (Computer Integrated Crown Reconstruction)
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99. Ceramic CAD/ CAM restorations are bonded to tooth
structure by -
Etching for a bond to enamel
Conditioning, priming and bonding (when appropriate)
Etching (by HF acid) and priming (silanating)
Cementing with luting resin.
Properties:
Excellent fracture and wear resistance
Pore-free
Possess both crystalline and non-crystalline phase (a 2-phase
composition permits differential etching of the internal surface for
bonding). www.indiandentalacademy.comwww.indiandentalacademy.com
100. Mechanical shaping of an industrially prefabricated ceramic
material, which is consistent in quality and its mechanical
properties.
It includes fabrication of a prototype (pro-inlay or crown)
usually via impression making and model preparation.
The pattern is placed in the machine, a tracing tool passes
over the pattern and guides a milling tool which grinds a copy
of the pattern from a block of ceramic.
The coping is then glass infiltrated…built up with veneering
porcelain and fired.
ANALOGOUS SYSTEMS
(COPYING / PANTOGRAPHY METHODS )
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101. The Celay System became first commercially available in
1992. It is a high precision, manually operated copy milling
machine.
Milling arms are able to move in 8 axes of freedom,
which allows the milling of complex, three dimensional
shapes.
Direct and indirect restorations
Replica of the restoration is mounted on one side
(scanning side) and the ceramic block is mounted on the
milling side.
CELAY System (Vident)
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102. System uses a sequential milling procedure
proceeding from coarse to fine milling burs, and
can mill a typical restoration in about 15-20
minutes.
Materials used
Vitabloc
inceram alumina
Inceram spinell
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103. Ceramic polymers
Several unique materials are significant
advancement in resin technology although their
formulation is some what different, as a group
they provide an existing breakthrough for esthetic
ceramic alternatives.
Belle glass
Artglass
Sculpture / fibrekor
Targis / vectris
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104. Artglass (Jelenko / Kulzer)
Artglass represents a new category of restorative
materials. The polyglass, which combines benefits of
both porcelain & composite.
Composed of multifunctional methacrylates, bifunctional
monomers, 20% silica fillers, and microglass fillers.
Available in 16 Vita shades.
More wear resistant
Intra-oral corrections
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105. Targis / Vectris (Ivoclar / Williams)
Targis is a new ceromer restorative material,
vectris is a fiberglass reinforced composite.
Advantages
Ease of final adjustment
Excellent polish
Translucency and fluorescence
Chair side repair of restorations
Low degree of brittleness
Less susceptible to fracture
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106. Ceramic CAD/ CAM restorations are bonded to tooth
structure by
Etching for a bond to enamel
Conditioning, priming and bonding (when appropriate)
Etching (by HF acid) and priming (silanating)
Cementing with luting resin.
Properties
Excellent fracture and wear resistance
Pore-free
Possess both crystalline and non-crystalline phase (a
2-phase composition permits differential etching of the
internal surface for bonding).www.indiandentalacademy.comwww.indiandentalacademy.com
107. EXTENDED & INNOVATIVE APPLICATIONS OF CERAMICS
Posterior esthetic restorations (Inlay & Onlays)
All-Ceramic Post & Core systems (Zirconia ceramics)
In Dental Implants:
Ceramic coating for dental implants
Implant supported ceramic restorations
Ceramic Orthodontic Brackets
Ceramics for Oral Mucosal Stimulation
Silanized ceramic fibers in Ceromers (Eg: Targis)
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108. Criteria for selection and use of Dental Ceramics
1. Not to use in patients with extreme bruxism,
clenching and malocclusions.
2. Degree of wear of tooth or restoration.
3. Bite force capability.
4. Any previous history of all ceramic inlay/crown
fracture.
5. Experience of laboratory technician should be
extensive.
6. Esthetic demands of specific patient.
7. Degree of translucency of adjacent teeth.
8. Skill of dentist is of paramount importance.www.indiandentalacademy.comwww.indiandentalacademy.com
109. Dental ceramic technology is one of the fastest growing areas
of dental material research and development. The past
decades have seen the development of several new groups
of ceramics.
The diversity of dental ceramics continues to stimulate
laboratory and clinical research. Systems such as Dicor and
Empress are now established.
The potential of the In-Ceram system, remains to be exploited
to the full.
The diversity and sophistication of some of the CAD-CAM
systems may prove to be influential in the future.
CONCLUSION
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110. Each system has its own merits, but may also
have shortcomings. Combinations of materials and
techniques are beginning to emerge which aim to
exploit the best features of each. Glass-ceramic and
glass-infiltrated alumina blocks for CAD-CAM
restoration production are examples of these and it is
anticipated that this trend is likely to continue ….
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111. R e f e r e n c e s
Philips science of dental materials{10th
and 11th edition}
Review of All ceramic restorations: JADA 1997;128:297
Recent advances in restorative dental ceramics: JADA
1993;124:72
A new method : CAD-CAM system: JADA 1989;118:703
Slip casting alumina ceramics for crown and bridge
restorations: Quintessence international 1992;23:1
• Heat pressed ceramics:technology and strength: IJP 1999;5
• Procera All ceramic crowns: BDJ 1999;186:430
• Porcelain esthetics for 21 st century: JADA 2000;131:47
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112. Relative flexural strength of 6 new ceramic materials: IJP
1995;8:239
Cast glass ceramic: DCNA 1985;29:725
Recent advances in ceramic materials and systems: Dental
update 1999;26:65
Dental CAD-CAM:A millstone or a milestone: Dental update
1995;22:200
Machinable glass ceramics and conventional lab restorations:
Quint Int 1994;25:773
Ceramics in dentistry:Historical roots and current perspective:
JPD 1996;75
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113. Thank you
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