REZİN MATRİKS SERAMİKLER-DERLEME

Year 2022, Volume: 32 Issue: 1, 114 - 118, 15.02.2022

Elif Melike Akarca Dilara Şahin Ragibe Şenay Canay

https://doi.org/10.17567/ataunidfd.888870

Abstract

Biyolojik uyumluluk ve yüksek estetik talepler konusunda endişelerin artması hastalar ve diş hekimlerini metalsiz, diş rengindeki restorasyonlara doğru yöneltmektedir. Giderek daha geniş kullanıma sahip olan bilgisayar destekli tasarım/ bilgisayar destekli üretim (CAD/CAM) sistemleri geçmişten günümüze büyük bir gelişim göstermektedir. Bu gelişim ile birlikte artan materyal seçeneği, daha hızlı ve yüksek kalitede estetik restorasyon üretimi olanağı tanımıştır. Diş hekimliğinde kullanılan iki önemli materyal grubu seramikler ve kompozitlerdir. Rezin matriks seramikler, hem seramiğin hem de kompozitlerin olumlu özelliklerini birleştiren yeni bir seramik sınıfıdır. Seramikler, biyouyumlu materyallerdir. Seramiklerin kimyasal stabiliteleri, bükülme dayanımları ve elastik modülleri kompozit materyallere göre oldukça yüksektir ancak bu materyallerin karşıt doğal dişte fazla aşınmaya sebep olmaları, millenmelerinin ve tamir edilebilmelerinin kompozitlere göre daha zor olması problem oluşturmaktadır. Kompozitlerin ise olumlu özelliklerinin yanı sıra aşınma dirençleri, biyouyumluluğu ve mekanik özellikleri seramiklere göre daha zayıftır. Bu iki materyalin olumlu özelliklerinin bir araya getirildiği, bilgisayar destekli tasarım/ bilgisayar destekli üretim teknolojisi ile kullanılan rezin matriks seramikler piyasaya sunulmuştur. Bu materyaller yüksek oranda doldurulmuş seramik parçacıkları içeren organik bir matriksten oluşur. Rezin matriks seramikler dentine yakın elastik modüle sahiptir ve ağız içerisinde kolaylıkla aşındırılıp cilası yapılabilir. Bu derlemenin amacı piyasaya yeni sunulan rezin matriks seramik materyallerinin mikroyapısal, mekanik ve fiziksel özellikleri hakkında bilgi vermektir.
Anahtar kelimeler: Rezin matriks seramik, nano seramik, hibrit seramik

RESIN MATRIX CERAMICS-AN OVERVIEW
Abstract
Patients and dentists tend to make metal-free, tooth-colored restorations with increasing concerns about biocompatibility and high aesthetic demands, computer aided design/computer aided manufacturing (CAD/CAM) systems which have become more widely used, have shown great improvement from past to present. Increasing material choice has enabled faster and higher quality aesthetic restoration production with this development. Two important material groups used in dentistry are ceramics and composites. Resin matrix ceramics is a new class of ceramics that combines the positive properties of both ceramics and composites. Ceramics are biocompatible materials. The chemical stability, flexural strength and elastic modulus of ceramics are considerably higher than composite materials, however they cause the problem such as excessive wear the opposing natural tooth, be more difficult to mill, and repair than composites. In addition to the positive properties of the composites, their abrasion resistance, biocompatibility and mechanical properties are weaker than ceramics. Resin matrix ceramics are used with computer aided design/computer aided manufacturing system technology, combining the positive properties of these two materials, were introduced to the market. This material consists of an organic matrix with a high proportion of ceramic particle-filled. Resin matrix ceramics have an elastic modulus close to dentin and they can easily be abraded and polished in the mouth. The purpose of this review is to give information about the microstructural, mechanical and physical properties of the newly introduced resin matrix ceramic materials.
Key words: Resin matrix ceramic, nano ceramic, hybrid ceramic

Keywords

Rezin matriks seramik, nano seramik,, hibrit seramik

References

• 1. Ruse ND, Sadoun MJ. Resin-composite blocks for dental CAD/CAM applications. J Dent Res 2014;93(12):1232–1234
• 2. Lauvahutanon S, Takahashi H, Shiozawa M, Iwasaki N, Asakawa Y, Oki M, Finger WJ, Arksornnukit M. Mechanical properties of composite resin blocks for CAD/CAM. Dent Mater J 2014;33(5):705–710
• 3. Villarroel M, Fahl N, De Sousa AM, De Oliveira OB Jr. Direct esthetic restorations based on translucency and opacity of composite resins. J Esthet Restor Dent 2011;23(2):73-87
• 4. Elsaka SE. Bond strength of novel CAD/CAM restorative materials to self-adhesive resin cement: the effect of surface treatments. J Adhes Dent 2014;16(6):531–540.
• 5. Karaalioğlu OF, Duymuş ZY. Diş hekimliğinde uygulanan CAD/CAM sistemleri. J Dent Fak Ataturk Uni 2008;(1):25-32.
• 6. Coldea A., Swain MV, Thiel N. Mechanical properties of polymer-infiltrated-ceramic-network materials. Dent Mater J 2013;29(4),419-426.
• 7. Chen C, Trindade FZ, de Jager N, Kleverlaan CJ, Feilzer AJ. The fracture resistance of a CAD/CAM Resin Nano Ceramic (RNC) and a CAD ceramic at different thicknesses. Dent Mater J 2014;30(9),954-962.
• 8. Della Bona A, Corazza PH, Zhang Y. Characterization of a polymer-infiltrated ceramic-network material. Dent Mater J 2014;30(5), 564-569.
• 9. Rohr N, Flury A, Fischer J. Efficacy of a universal adhesive in the bond strength of composite cements to polymer-infiltrated ceramic. J Adhes Dent 2017;19(5), 417-424.
• 10. Mainjot AK, Dupont NM, Oudkerk JC, Dewael TY, Sadoun MJ. From artisanal to CAD-CAM blocks: state of the art of indirect composites. J Dent Res 2016;95:487-495
• 11. Alt V, Hannig M, Wöstmann B, Balkenhol M. Fracture strength of temporary fixed partial dentures: CAD/CAM versus directly fabricated restorations. Dent Mater 2011;27(4):339-347.
• 12. Balkenhol M, Mautner MC, Ferger P, Wöstmann B. Mechanical properties of provisional crown and bridge materials: chemicalcuring versus dual-curing systems. J Dent 2008;36(1):15-20.
• 13. Stawarczyk B, Ender A, Trottmann A, Özcan M, Fischer J, Hämmerle CH. Load-bearing capacity of CAD/CAM milled polymeric three-unit fixed dental prostheses: effect of aging regimens. Clin Oral Investig 2012;16(6):1669-1677
• 14. Barutcigil K, Barutcigil Ç, Kul E, Özarslan MM, Buyukkaplan US. Effect of different surface treatments on bond strength of resin cement to a CAD/CAM restorative material. J Prosthodont 2019;28(1):71-78
• 15. Mörmann WH, Stawarczyk B, Ender A, Sener B, Attin T, Mehl A. Wear characteristics of current aesthetic dental restorative CAD/CAM materials: two-body wear, gloss retention, roughness and martens hardness. J Mech Behav Biomed Mater 2013;20:113-125
• 16. Nguyen J-F, Migonney V, Ruse ND, Sadoun M. Resin composite blocks via high-pressure high-temperature polymerization. Dent Mater 2012;28(5):529-534.
• 17. Spitznagel FA, Horvath SD, Guess PC, Blatz MB. Resin bond to indirect composite and new ceramic/polymer materials: a review of the literature. J Esthet Restor Dent 2014;26(6):382–393
• 18. Wang LK, Liu YN, Hui H, Li PP. Color stability of computer aided design and computer aided manufacture composite ceramic/resin cements after accelerated ageing. Zhonghua kou qiang yi xue za zhi=Chinese journal of stomatology 2019;54(11):765-769.
• 19. Awada A, Nathanson D. Mechanical properties of resin-ceramic CAD/CAM restorative materials. J Prosthet Dent 2015;114(4),587-593.
• 20. American Dental Association. CDT: Code on dental procedures and nomenclature. http://www.ada.org/en/publications/cdt/. Accessed March 17, 2015.
• 21. Gracis S, Thompson VP, Ferencz JL, Silva NR, Bonfante EA. A new classification system for all-ceramic and ceramic-like restorative materials. Int J Prosthodont 2015;28(3),227-235.
• 22. Lawson NC, Bansal R, Burgess JO. Wear, strength, modulus and hardness of CAD/CAM restorative materials. Dent Mater 2016;32(11),e275-e83.
• 23. Nguyen J, Ruse D, Phan A, Sadoun M. High-temperature-pressure polymerized resin-infiltrated ceramic networks. J Dent. Res 2014;93(1),62-67.
• 24. Facenda JC, Borba M, & Corazza PH. A literature review on the new polymer‐infiltrated ceramic‐network material (PICN). J Esthet Restor Dent 2018;30(4):281-286.
• 25. He L-H, Swain M. A novel polymer infiltrated ceramic dental material. Dent Mater 2011;27(6):527-534.
• 26. Tassin M, Bonte E, Loison-Robert LS, Nassif A, Berbar T, Le Goff S, et al. Effects of hightemperature-pressure polymerized resin-infiltrated ceramic networks on oral stem cells. PLoS One 2016;11(5):e0155450
• 27. Furtado de Mendonca, A., Shahmoradi, M., Gouvêa, C., De Souza, G. M., Ellakwa, A. Microstructural and Mechanical Characterization of CAD/CAM Materials for Monolithic Dental Restorations. J Prosthodont 2019;28(2):e587–e594.
• 28. Aladağ A, Oğuz D, Çömlekoğlu ME, Akan E. In vivo wear determination of novel CAD/CAM ceramic crowns by using 3D alignment. J Adv Prosthodont 2019;11(2):120–127.
• 29. Acar O, Yilmaz B, Altintas SH, Chandrasekaran I, Johnston WM. Color stainability of CAD/CAM and nanocomposite resin materials. J Prosthet Dent 2016;115(1):71–75.
• 30. Johnson AC, Versluis A, Tantbirojn D, Ahuja S. Fracture strength of CAD/CAM composite and composite-ceramic occlusal veneers. J Prosthodont Res 2014;58(2):107-114.
• 31. Shetty R, Shenoy K, Dandekeri S, Suhaim KS, Ragher M, Francis J. Resin-matrix ceramics – an overview. Int J Recent Sci Res 2015;6(11):7414-7417.
• 32. Goujat A, Abouelleil H, Colon P, Jeannin C, Pradelle N, Seux D, & Grosgogeat B. Mechanical properties and internal fit of 4 CAD-CAM block materials. J Proshet Dent 2018;119(3):384-389.
• 33. Lührs AK, Pongprueksa P, De Munck J, Geurtsen W, Van Meerbeek B. Curing mode affects bond strength of adhesively luted composite CAD/CAM restorations to dentin. Dent Mater 2014;30(3):281-291.
• 34. Sen N, Us YO. Mechanical and optical properties of monolithic CAD-CAM restorative materials. J Prosthet Dent 2018;119(4):593-599.
• 35. Albero A, Pascual A, Camps I, Grau-Benitez M. Comparative characterization of a novel cad-cam polymer-infiltrated-ceramic-network. J Clin Exp Dent 2015;7(4), e495–e500.
• 36. Lucsanszky IJ, Ruse ND. Fracture Toughness, Flexural Strength, and Flexural Modulus of New CAD/CAM Resin Composite Blocks. J Prosthodont 2020;29(1):34-41.
• 37. Schepke U, Meijer HJ, Vermeulen KM, Raghoebar GM, Cune MS. Clinical Bonding of R esin Nano Ceramic Restorations to Zirconia Abutments: A Case Series within a Randomized Clinical Trial. Clin Implant Dent R 2016;18(5):984-992.
• 38. Bonfante EA, Suzuki M, Lorenzoni FC, Sena LA, Hirata R, Bonfante G, Coelho PG. Probability of survival of implant-supported metal ceramic and CAD/CAM resin nanoceramic crowns. Dent Mater 2015;31(8):e168-e177.
• 39. Awad D, Stawarczyk B, Liebermann A, Ilie N. Translucency of esthetic dental restorative CAD/CAM materials and composite resins with respect to thickness and surface roughness. J Prosthet Dent 2015;113(6):534-540.
• 40. Zhang HB, Huo H, & Liu LJ. Influence of different surface treatments on resin nano ceramic-resin cement bond strength. Zhonghua kou qiang yi xue za zhi=Chinese journal of stomatology 2020;38(2):155.
• 41. Romanini-Junior JC, Hirata R, Bonfante EA, Bordin D, Kumagai RY, Fardin VP, Coelho PG, Reis AF. Monolithic CAD/CAM laminate veneers: Reliability and failure modes. Dent Mater 2020;36(6):724-732.
• 42. Voco Dental. Voco Grandio Block [online]. https://www.voco.dental/en/products/indirect-restoration/cad-cam-material/grandio-blocs.aspx [Accessed 2 June 2020].
• 43. Rosentritt M, Krifka S, Strasser T, Preis V. Fracture force of CAD/CAM resin composite crowns after in vitro aging. Clin Oral Investig 2020;24(7):2395–2401.
• 44. Tekçe N, Fidan S, Tuncer S, Kara, D, & Demirci M. The effect of glazing and aging on the surface properties of CAD/CAM resin blocks. J Adv Prosthodont 2018;10(1):50-57
• 45. Şişmanoğlu S, Gürcan AT, Yıldırım-Bilmez Z, Turunç-Oğuzman R, Gümüştaş B. Effect of surface treatments and universal adhesive application on the microshear bond strength of CAD/CAM materials. J Adv Prosthodont. 2020;12(1):22-32.
• 46. GC Cerasmart [online]. https://www.gcamerica.com/products/digital/CERASMART/ [Accessed 2 Semtember 2020].
• 47. Horvath, S. Key Parameters of Hybrid Materials for CAD/CAM-Based Restorative Dentistry. Compend Contin Educ Dent 2016;37(9):638-643.
• 48. Huang XQ, Hong NR, Zou LY, Wu SY, Li Y. Estimation of stress distribution and risk of failure for maxillary premolar restored by occlusal veneer with different CAD/CAM materials and preparation designs. Clin Oral Investig 2020;24(9):3157-67.
• 49. Fasbinder DJ, Neiva GF, Dennison JB, Heys DR. Clinical Performance of CAD/CAM-Generated Composite Inlays After 10 Years. J Cosmet Dent 2013;28(4):134-145.
• 50. Oğuz Eİ, Kılıçarslan MA, Özcan M. Effect of endodontic access simulation on the fracture strength of lithium‐disilicate and resin‐matrix ceramic CAD‐CAM crowns. J Esthet Restor Dent 2020;32(5):472-479
• 51. Coldea A, Swain MV, Thiel N. In-vitro strength degradation of dental ceramics and novel PICN material by sharp indentation. J Mech Behav Biomed Mater 2013;26:34-42.
• 52. Tinschert J, Zwez D, Marx R, Anusavice K. Structural reliability of alumina-, feldspar-, leucite-, mica-and zirconia-based ceramics. J Dent 2000;28(7):529-35.
• 53. Mine A, Kabetani T, Kawaguchi-Uemura A, Higashi M, Tajiri Y, Hagino R, et al. Effectiveness of current adhesive systems when bonding to CAD/CAM indirect resin materials: a review of 32 publications. Jpn Dent Sci Rev 2019;55(1):41-50.
• 54. Hampe R, Theelke B, Lümkemann N, Eichberger M, Stawarczyk B. Fracture toughness analysis of ceramic and resin composite CAD/CAM material. Oper Dent 2019;44(4):E190-E201.
• 55. Spitznagel FA, Scholz KJ, Strub JR, Vach K, Gierthmuehlen PC. Polymer-infiltrated ceramic CAD/CAM inlays and partial coverage restorations: 3-year results of a prospective clinical study over 5 years. Clin Oral Investig 2018;22(5):1973-1983.
• 56. Hampe R, Theelke B, Lümkemann N, Stawarczyk B. Impact of artificial aging by thermocycling on edge chipping resistance and Martens hardness of different dental CAD-CAM restorative materials. J Prosthet Dent 2020;available online 27 February 2020.
• 57. Chirumamilla G, Goldstein CE, Lawson NC. A 2‐year retrospective clinical study of enamic crowns performed in a private practice setting. J Esthet Restor Dent 2016;28(4):231-237.
• 58. Stawarczyk B, Liebermann A, Eichberger M, & Güth JF. Evaluation of mechanical and optical behavior of current esthetic dental restorative CAD/CAM composites. J Mech Behav Biomed 2016;55:1-11.
• 59. Mushashe AM, Farias IC, Gonzaga CC, Cunha LFd, Ferracane JL, Correr GM. Surface Deterioration of Indirect Restorative Materials. Braz Dent J 2020;31(3):264-71.
• 60. Fasbinder DJ. Materials for chairside CAD/CAM restorations. Compend Contin Educ Dent 2010;31(9):702-704.
• 61. Paradigm TM MZ100 Block Technical Product Profile. 3M ESPE [online]. https://multimedia.3m.com/mws/media/77596O/3m-paradigm-mz100-block-for-cerec-technical-product-profile.pdf. [Accessed 10 October 2020].
• 62. Höland W, Schweiger M, Frank M, Rheinberger V. A comparison of the microstructure and properties of the IPS Empress® 2 and the IPS Empress® glass‐ceramics. J Biomed Mater Res 2000;53(4):297-303.
• 63. Magne P, Knezevic A. Simulated fatigue resistance of composite resin versus porcelain CAD/CAM overlay restorations on endodontically treated molars. Quintessence Int 2009;40(2):125-133.
• 64. Tsitrou EA, Helvatjoglu-Antoniades M, Van Noort R. A preliminary evaluation of the structural integrity and fracture mode of minimally prepared resin bonded CAD/CAM crowns. J Dent 2010;38(1):16-22.
• 65. Kassem AS, Atta O, El‐Mowafy O. Fatigue resistance and microleakage of CAD/CAM ceramic and composite molar crowns. J Prosthodont 2012;21(1):28-32.
• 66. Thornton I, Ruse ND. Characterization of nanoceramic resin composite and lithium disilicate blocks. J Dent Res 2014;93(Special Issue B):151.
• 67. Demirel G, Baltacıoğlu İH. Influence of different universal adhesives on the repair performance of hybrid CAD-CAM materials. Restor Dent Endod 2019;44(3):e23.
• 68. Shofu. Shofu Block HC Broşür [online]. https://www.shofu.de/wp-content/uploads/2018/06/SHOFU-Block-HC-Disk-HC-Info-UK.pdf [Accessed 2 June 2020].