Dental porcelain

Dental porcelain (also known as dental ceramic) is a dental material used by dental technicians to create biocompatible lifelike dental restorations, such as crowns, bridges, and veneers. Evidence suggests they are an effective material as they are biocompatible, aesthetic, insoluble and have a hardness of 7 on the Mohs scale. For certain dental prostheses, such as three-unit molars porcelain fused to metal or in complete porcelain group, zirconia-based restorations are recommended.[1]

The word "ceramic" is derived from the Greek word κέραμος keramos, meaning "potter's clay".[2] It came from the ancient art of fabricating pottery where mostly clay was fired to form a hard, brittle object; a more modern definition is a material that contains metallic and non-metallic elements (usually oxygen). These materials can be defined by their inherent properties including their hard, stiff, and brittle nature due to the structure of their inter-atomic bonding, which is both ionic and covalent. In contrast, metals are non-brittle (display elastic behavior), and ductile (display plastic behaviour) due to the nature of their inter-atomic metallic bond. These bonds are defined by a cloud of shared electrons with the ability to move easily when energy is applied. Ceramics can vary in opacity from very translucent to very opaque. In general, the more glassy the microstructure (i.e. noncrystalline) the more translucent it will appear, and the more crystalline, the more opaque.[3]

Composition

Ceramic used in dental application differs in composition from conventional ceramic to achieve optimum aesthetic components such as translucency.

As example the composition of dental feldspathic porcelain is as follows:[4]

  • Kaolin 3-5%
  • Quartz (silica) 12-25%
  • Feldspar 70-85%
  • Metallic colourants 1%
  • Glass up to 15%

Classification

Ceramics can be classified based on the following:[3][5]

Feldspathic porcelain fabricated on a dental model, then clinically cemented on the central anterior teeth

Classification by Microstructure

At the microstructural level, ceramics can be defined by the nature of their composition of amorphous-to-crystalline ratio. There can be an infinite variability of the microstructures of materials, but they can be broken down into four basic compositional categories, with a few subgroups:

  • Composition category 1 – glass-based systems (mainly silica), example is the feldspathic porcelain.
  • Composition category 2 – glass-based systems (mainly silica) with fillers, usually crystalline (typically leucite or, more recently, lithium disilicate)
  • Composition category 3 – crystalline-based systems with glass fillers (mainly alumina)
  • Composition category 4 – polycrystalline solids (alumina and zirconia).

Dental ceramic is generally regarded as biologically inert. However, other toxicities may exist from depleted uranium as well as some of the other accessory materials; in addition, the restoration may increase wear on opposing teeth.[6]

Classification by Processing Technique

  • Powder/liquid, glass-based systems
  • Machinable or pressable blocks of glass-based systems
  • CAD/CAM or slurry, die-processed, mostly crystalline systems[7][8]

Classification of crystalline ceramics

Classification of crystalline ceramics[5]
Fabrication technique Crystalline phase
Metal-ceramics Sintering Leucite
Heat-pressing on metal Leucite, leucite & fluorapatite
All-ceramics Sintering Leucite
Heat-pressing Leucite, lithium disilicate
Dry pressing and sintering Alumina
Slip-casting & glass infiltration Alumina, spinel, alumina-zirconia (12Ce-TZP)
Soft machining & glass-infiltration Alumina, alumina-zirconia (12Ce-TZP)
Soft machining & sintering Alumina, zirconia (3Y-TZP)
Soft machining, sintering & heat-pressing Zirconia/fluorapatite-leucite glass-ceramic
Hard machining Sanidine, leucite
Hard machining & heat treatment Lithium disilicate

Types of Ceramics

The range of dental ceramics determined by their respective firing temperatures are:

  • Ultra-low

Fired below 850 °C - mainly used for shoulder ceramics (aims to combat the problem of shrinkage, specifically at the margins of the prep, when the early sintered ceramic state is fired to produce the final restoration), to correct minor defects and to add colour/shading to restorations

  • Low fusing

Fired between 850 and 950 °C - to prevent the occurrence of distortion, this type of ceramic should not be subjected to multiple firings

  • Higher fusing

This type is used mainly for denture teeth

Laboratory Procedure

The dentist will usually specify a shade or combination of shades for different parts of the restoration, which in turn corresponds to a set of samples containing the porcelain powder. There are two types of porcelain restorations:[9]

  • Porcelain fused to metal
  • Complete porcelain

Ceramic restorations can be built on a refractory die, which is a reproduction of a prepared tooth made of a strong material with the ability to withstand high temperatures, or it can be constructed on a metal coping or core.

For ceramic fused to metal restorations, the black color of metal is first masked with an opaque layer giving it a shade of white before consecutive layers are built up. The powder corresponding to the desired shade of dentine base is mixed with water before it is fired. Further layers are built up to mimic the natural translucency of the enamel of the tooth. The porcelain is fused to a semi-precious metal or precious metal, such as gold, for extra strength.

Systems which use an aluminium oxide, zirconium oxide or zirconia core instead of metal, produces complete porcelain restorations.[10]

Firing

Once the mass has been built up, it is fired to allow fusion of the ceramic particles which in turn forms the completed restoration; the process by which this is done is referred to as ‘baking’.[4]

The first bake forces water out and allows the particles to coalesce. During this initial process, a large amount of shrinkage occurs until the mass reaches an almost void-free state; to overcome this the mass is built-up to a size larger than the final restoration will be.

The mass is then left to cool slowly to prevent cracking and reduced strength of the final restoration.

Adding more layers to build up the restoration to the desired shape and/or size requires the ceramic to undergo further rounds of firing.

Staining

Ceramic can also be stained to show tooth morphology such as occlusal fissures and hypoplastic spots. These stains can be incorporated within the ceramic or applied onto the surface. [4]

Glazing

Glazing is required to produce a smooth surface and it's the last stage of sealing the surface as it will fill porous areas and prevent wear on opposing teeth. Glazing can be achieved by re-firing the restoration, which fuses outer layers of the ceramic, or by using glazes with lower fusing temperatures; these are applied on the outer surface of the restoration in a thin layer. Any adjustments are then made with polishing rubbers and fine diamonds.[4]

Use of CAD-CAM

Recent developments in CAD/CAM dentistry uses special partially sintered ceramic (zirconia), glass-bonded ceramic or glass-ceramic (lithium disilicate)[11] formed into machinable blocks, which are fired again after machining.[12][8]

By utilising in-office CAD/CAM technology, clinicians are able to design, fabricate and place all-ceramic inlays, onlays, crowns and veneers in a single patient visit. Ceramic restorations produced by this method have demonstrated excellent fit, strength and longevity. Two basic techniques can be used for CAD/CAM restorations:

  • Chairside single-visit technique
  • Integrated chairside–laboratory CAD/CAM procedure[13]

Ceramic Restorations can be

Ceramic restorations are indicated for most dental applications including:[4]

However, each system will have its own set of specific indications and contraindications which can be obtained from the manufacturers guideline.

Contraindications for Ceramic Restorations

Ceramic restorations are contraindicated when a patient presents with the following:[4]

Other uses

Denture Teeth

Poly(methyl methacrylate) (PMMA) is the material of choice for denture teeth, however ceramic denture teeth have been, and still are used for this purpose. The main benefit associated with the use of ceramic teeth is their superior wear resistance. There are however a number of disadvantages to using ceramic for denture teeth including their inability to form chemical bonds with the PMMA denture base; rather, ceramic teeth are attached to the base via mechanical retention which increases the chance of debonding during use over time. Additionally, they are more likely to fracture due to their brittle nature.[4]

Endodontic Posts

Ceramic can be used in the construction of non-metallic posts, however, it is a brittle material and as such may fracture within the root canal or may cause fracture of the root due to its increased strength. Another disadvantage is that once placed, removal may not be possible.[4]

References

  1. Della Bona A, Kelly JR (September 2008). "The clinical success of all-ceramic restorations". Journal of the American Dental Association. 139. 139 Suppl: 8S–13S. PMID 18768903. Archived from the original on 2012-07-09. Retrieved 2009-01-04.
  2. Liddell & Scott, An Intermediate Greek–English Lexicon
  3. 1 2 McLaren EA, Cao PT (October 2009). "Ceramics in Dentistry—Part I: Classes of Materials". Inside Dentistry. 5 (9).
  4. 1 2 3 4 5 6 7 8 Bonsor SJ, Pearson GJ (2013). A clinical guide to applied dental materials. Amsterdam: Elsevier/Churchill Livingstone. ISBN 9780702046964. OCLC 824491168.
  5. 1 2 Denry I, Holloway J, Denry I, Holloway JA (2010-01-11). "Ceramics for Dental Applications: A Review". Materials. 3 (1): 351–368. doi:10.3390/ma3010351. PMC 5525170.
  6. Mackert JR (September 1992). "Side-effects of dental ceramics". Advances in Dental Research. 6: 90–3. doi:10.1177/08959374920060012301. PMID 1337968.
  7. Silva LH, Lima E, Miranda RB, Favero SS, Lohbauer U, Cesar PF (August 2017). "Dental ceramics: a review of new materials and processing methods". Brazilian Oral Research. 31 (suppl 1): e58. doi:10.1590/1807-3107bor-2017.vol31.0058. PMID 28902238.
  8. 1 2 Kastyl, Jaroslav; Chlup, Zdenek; Stastny, Premysl; Trunec, Martin (2020-08-17). "Machinability and properties of zirconia ceramics prepared by gelcasting method". Advances in Applied Ceramics. 119 (5–6): 252–260. doi:10.1080/17436753.2019.1675402. ISSN 1743-6753.
  9. Porcelain-Fused-to-Metal Crowns versus All-ceramic Crowns: A Review of the Clinical and Cost-Effectiveness. CADTH Rapid Response Reports. Ottawa (ON): Canadian Agency for Drugs and Technologies in Health. 2015. PMID 26180882.
  10. Lawson NC, Burgess JO (March 2014). "Dental ceramics: a current review". Compendium of Continuing Education in Dentistry. 35 (3): 161–6, quiz 168. PMID 24773195.
  11. Tysowsky G. "The Science Behind Lithium Disilicate". Retrieved 1 February 2012.
  12. Fasbinder DJ (September 2006). "Clinical performance of chairside CAD/CAM restorations". Journal of the American Dental Association. 137. 137 Suppl: 22S–31S. doi:10.14219/jada.archive.2006.0395. PMID 16950934. Archived from the original on 2012-07-09. Retrieved 2009-01-04.
  13. Shenoy A, Shenoy N (October 2010). "Dental ceramics: An update". Journal of Conservative Dentistry. 13 (4): 195–203. doi:10.4103/0972-0707.73379. PMC 3010023. PMID 21217946.
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