Publication: Resistencia al cizallamiento de tres sistemas totalmente cerámicos: estudio comparativo
Loading...
Official URL
Full text at PDC
Publication Date
2012
Authors
Advisors (or tutors)
Editors
Journal Title
Journal ISSN
Volume Title
Publisher
Citations
Exportar
Abstract
La resistencia al cizallamiento puede ser definida como la carga necesaria para producir una fractura en la interfase de unión entre dos materiales cuado se aplican fuerzas paralelas de sentido contrario. Las porcelanas de recubrimiento que se van a someter a este ensayo mecánico son tres cerámicas feldespáticas para óxido de zirconio: Cercon®Ceram, Vita®VM9 y GC®Initial.
El sistema ceramo-cerámico DSVita fue el que obtuvo una mayor resistencia al cizallamiento, aunque los 3 sistemas analizados podrían ser utilizados clínicamente con buenos resultados desde el punto de vista de resistencia al cizallamiento.
[ABSTRACT] Resistence to the shearing is the necessary charge to produce a fracture in the bonding interface between two materials when we apply opposite parallel forces. We have studied this 3 feldspar ceramic for zirconium oxide: Cercon®Ceram, Vita®VM9 y GC®Initial. The ceramo-ceramic system DS-Vita was the most resistent to the shearing, although the three analyzed systems could be used clinically with good results from the standpoint of resistence to the shearing.
Description
UCM subjects
Unesco subjects
Keywords
Citation
1. Vega del Barrio J. Porcelanas y cerámicas actuales. RCOE. 1999;4(1):41–54.
2. Caparroso C, Duque Vargas J. Ceramicas y sistemas para restauraciones CAD/CAM: Una revision. Rev Fac Odontol Univ Antioq. 2010 Nov. 5;22(1):88–108.
3. Álvarez-‐Fernández M, Peña-‐López J, González-González I, Olay-‐García M. Características generales y propiedades de las cerámicas sin metal. RCOE. 2003 Dec. 19;8(5):525–546.
4. Müller W, Paul T, Meyer L, Schöp C, König J, Abert C. Consideraciones de las propiedades materiales de la cerámica de núcleo verde. Quintessence técnica (ed. esp.). 2006;17(8):447–454.
5. Martínez Rus F, Pradíes Ramiro G, Suárez García M, Rivera Gómez B. Cerámicas dentales: clasificación y criterios de selección. RCOE. 2007;12(4):253–263.
6. Oumvertos S, Vagkopoulou T, Pelekanos S, Koidis P, Strub J. Zirconia in Dentistry: Part 2. Evidence-‐based Clinical Breakthrough. Eur J Esthet Dent. 2009 Nov. 23;4(4):348–380.
7. (null). “Métodos y aplicaciones en cerámica” CAD/CAM elaboración a máquina en duro. 2011 Nov. 9;:1–7.
8. Vega del Barrio J. Uniones ceramo-metálicas y ceramo-cerámicas: perspectivas futuras. Gaceta Dental. 2004;Junio(149):106–114.
9. Kurbad A. El mundo de las cerámicas CAD. Exigencias a los sistemas de cerámica sin metal. 2011 Oct. 31;:1–5.
10. Vagkopoulou T, Koutayas S, Koidis P, Strub J. Zirconia in Dentistry: Part 1. Discovering the Nature of an Upcoming Bioceramic. Eur J Esthet Dent. 2009 Jun. 4;4(2):130–151.
11. Delgado García-‐Menocal J, Morejón L, Martínez S, Gil F. Cerámicas de circona para aplicaciones biomédicas. Biomecánica. 2003;11:46–52.
12. Garvie R, Nicholson P. Structure and Thermomechanical Properties of Partially Stabilized Zirconia in the CaO-ZrO2 System. J American Ceramic Society. 1972;55(3):152–157.
13. Scott H. Phase relationships in the zirconia-yttria system. J Mater Science. 1975;(10):1527–1535.
14. Chevalier J, Gremillard L, Deville S. Low-Temperature Degradation of Zirconia and Implications for Biomedical Implants. Annu. Rev. Mater. Res. 2007 Aug. 1;37(1):1–32.
15. Kelly R, Denry I. Stabilized zirconia as a structural ceramic: An overview. Dent Mater. 2008 Jan. 17;24:289–298.
16. Denry I, Kelly R. State of the art of zirconia for dental applications. Dent Mater. 2008 Jan. 17;24:200–307.
17. Balmes Barnusell X. Zirconio, la respuesta. Dental Dialogue. 2006;3:56–63.
18. Curtis A, Wright A, Fleming G. The influence of surface modification techniques on the performance of a Y-TZP dental ceramic. J Dent. 2006;34:195–206.
19. Allahkarami M, Hanan JC. Mapping the tetragonal to monoclinic phase transformation in zirconia core dental crowns. Dent Mater. 2011 Dec. 1;27(12):1279–1284.
20. Guazzato M, Albakry M, Ringer S, Swain M. Strength, fracture toughness and microstructure of a selection of all-ceramic materials. Part II. Zirconia-based dental ceramics. Dent Mater. 2004 Apr.6;20:449–456.
21. Garvie RC, Hannink RH, Pascoe RT. Ceramic steel? Nature. 1975 Dec. 25;258(5537):703–704.
22. Chintapalli R, García-‐Marro F, Valle J, Jiménez-Piqué E, Hüzdos P, Anglada M. Change in microstructure and surface mechanical properties during hydrothermal ageing of Ytria doped Zirconia. Departament de ciència de materials I Enginyeria Metal. Lurgica, UPC, ETSEIB. 2008 Jul. 2;:1–10.
23. Kohal R, Weng D, Strub J. Loaded Custom-‐Made Zirconia and Titanium Implants Show Similar Osseointegration: An Animal Experiment. J Periodontol. 2004;75(9):1–4.
24. Kosmac T, Oblak C, Jevnikar P, Funduk N, marion L. The effect of surface grinding and sandblasting on flexural strength and reliability of Y-TZP zirconia ceramic. Dent Mater. 1999 Oct. 4;15:426–433.
25. Ichikawa Y, Akagawa Y, Nikai H, Tsuru H. Tissue compatibility and stability of a new zirconia ceramic in vivo. J Prosthet Dent. 1992;(68):322–326.
26. Tinschert J, Natt G, Mohbotter N, Spikermann H, Schuize K. Lifetime of Alumina-and Zirconia Ceramics Used for Crown and Bridge Restorations. J Biomed Mater Res Part B: Appl Biomater. 2006 Jul. 5;3(16):1–5.
27. Kobayashi K, Kuwajima H, Masaki T. Phase change and mechanical properties of ZrO2-Y2O3 solid electrolyte after ageing. Solid State Ionics. 1981;3-4:489–493.
28. Feder A, Llanes L, Anglada M. Efecto de la nitruración en la degradación hidrotérmica de circona tetragonal policristalina estabilizada con Y2O3. Boletin de la Sociedad Española de Cerámica y Vidrio. 2004;43(1):47–52.
29. Gaillard Y, Jiménez-Piqué E, F S, Mücklich F, Anglada M. Quantification of hydrothermal degradation in zirconia by nanoindentatio. Acta Materialia. 2008 Aug. 16;56:4206–4216.
30. Valle J, Jiménez-‐Piqué E, Mestra A, Anglada M. Tribological behaviour of surface nitrided zirconia. A: 11th. European Inter-regional Conference on Ceramics. “Proceedings of the 11h. European Inter-regional Conference on Ceramics, CIEC11.” 2008, p. 197-202. 2008 Sep. 10;:1–6.
31. Johnson P. Making White Steel. Dental Lab Products. 2008 Feb. 29;1.
32. Edelhoff D, Weber V, Johnen C, Beuer F. Experiencia clínica con subestructuras de puentes de óxido de zirconio CAD/CAM del sistema Digident. Quintessence Int. 2007;58(4):371–383.
33. Hulbert S, Morrison S, Klawitter J. Tissue reaction to three ceramics of porous and non-porous structures. J Biomed Mater Res. 1972;6(5):347–374.
34. Akagawa Y, Hosokawa R, Sato Y, Kamayama K. Comparison between freestanding and tooth-connected partially stabilized zirconia implants after two years function in monkeys: A clinical and histologic study. J Prosthet Dent. 1998;80(5):551–558.
35. Scarano A, Di Carlo F, Quaranta M, Piattelli A. Bone Response to Zirconia Ceramic Implants: An Experimental Study in Rabbits. J Oral Implantol. 2003;XXIX:8–12.
36. Rimondini L, Cerroni L, Carrassi A, Torriceli P. Bacterial Colonization of Zirconia ceramic Surfaces: An In Vitro and In Vivo Study. Int J Oral Maxillofac Implants. 2002;17(6):793–798.
37. Reich S, Petschelt A, Lohbauer U. The effect of finish line preparation and layer thickness on the failure load and fractography of ZrO2 copings. J Prosthet Dent. 2008 Apr. 23;99(5):369–376.
38. Casucci A, Monticelli F, Goracci C, Mazzitelli C, Cantoro A, Papacchini F, et al. Effect of surface pre-treatments on the zirconia ceramic-resin cement microtensile bond strength. Dent Mater. 2011 Oct. 1;27(10):1024–1030.
39. Kern M, Wegner S. Bonding to zirconia ceramic: adhesion methods and their durability. Dent Mater. 1998;14:64–71.
40. Wolfart M, Lehmann F, Wolfart S, Kern M. Durability of the resin bond strength to zirconia ceramic after using different surface conditioning methods. Dent Mater. 2007;23:45–50.
41. Atsu S, Kilicarslan M, Kucukesmen H, Aka P. Effect of zirconium-oxide ceramic surface treatments on the bond strength to adhesive resin. J Prosthet Dent. 2006;95(6):430–436.
42. Yang B, Wolfart S, Scharnberg M, Ludwig K, Adelung R, Kern M. Influence of Contamination on Zirconia Ceramic Bonding. J Dent Res. 2007 Aug. 1;86(8):749–753.
43. Quaas A, Yang B, Kern M. Panavia F 2.0 bonding to contaminated zirconia ceramic after different cleaning procedures. Dent Mater. 2007 Feb. 20;23:506–512.
44. Guazzato M, Quach L, Albakry M, Swain M. Influence of surface and heat treatments on the flexural strength of Y-TZP dental ceramic. J Dent. 2005;33:9–18.
45. García Arranz J. ¿Qué tipo de cerámica debo utilizar? Labor Dental. 1980;:1–9.
46. Choi JE, Waddell JN, Torr B, Swain MV. Pressed ceramics onto zirconia. Part 1: Comparison of crystalline phases present, adhesion to a zirconia system and flexural strength. Dent Mater. 2011 Dec. 1;27(12):1204–1212.
47. Sailer I, Filser F, Gauckler LJ, Luthy H, Hammerle C. Five-Year Clinical Results of Zirconia frameworks for Posterior Fixed Partial Dentures. Int J Prosthodont. 2007 Jul. 23;20:383–388.
48. Ertan A, Yuzugullu B, Canay S, Ersu B. Effect of Repeated Firings on Microtensile Bond Strength of In-Ceram Alumina with Two Differefnt Veneering Ceramics. Int J Prosthodont. 2011 Oct. 25;24(6):515–516.
49. Al-Dohan H, Yaman P, Dennison JB, Razzoog M, Lang B. Shear strength of core-veneer interface in bilayered ceramics. J Prosthet Dent. 2004 Apr. 8;91(4):349–355.
50. Thompson J, Anusavice K, Naman A, Morris H. Fracture Surface Characterization of Clinically Failed All-ceramic Croens. J Dent Res. 1994;73:1824–1832.
51. Quinn J, Sundar V. Fracture Toughness of Veneering Ceramics for Fused to Metal (PFM) and Zirconia. Dental Restorative Materials. J Res Natl Inst Technol. 2010 Sep. 27;115(5):343–352.
52. Ereifej N, Rodrigues FP, Silikas N, Watts DC. Experimental and FE shear-bonding strength at core/veneer interfaces in bilayered ceramics. Dent Mater. 2011 Jun. 1;27(6):590–597. 53. Choi JE, Waddell JN, Swain MV. Pressed ceramics onto zirconia. Part 2: Indentation fracture and influence of cooling rate on residual stresses. Dent Mater. 2011 Nov. 1;27(11):1111–1118.
54. Ban S, Anusavice K. Influence of Test Method on Failure Stress of Brittle Dental Materials. J Dent Res. 1990 Dec. 1;69(12):1791–1799.
55. Lawn B, Deng Y, Thompson V. Use of contact testing in the characterization and design of all-ceramic crownlike layer structures: A review. J Prosthet Dent. 2001 Nov. 14;86:495–510.
56. Guazzato M, Albakry M, Ringer S, Swain M. Strength, fracture toughness and microstructure of a selection of all-ceramic materials. Part I. Pressable and alumina glass-infiltrated ceramics. Dent Mater. 2004 Apr. 6;20:441–448.
57. Creugers N, Käyser A, van't Hof M. A meta-analysis of durability data on conventional fixed bridges. Community Dent Oral Epidemiol. 1994;22:448–452.
58. Scurria M, Bader J, Shugars D. Meta-‐analysis of fixed partial denture survival: Prostheses and abutments. J Prosthet Dent. 1998;74:459:464.
59. Näpankangas R, Raustua A. An 18-‐Year Retrospective Analysis of Treatment Outcomes with Metal-Ceramic Fixed Partial Dentures. Int J Prosthodont. 2011 Jun. 21;24:314–319.
60. De Backer H, Van Maele G, De Moor N, Van den Berghe L.A 20-year retrospective survival study of fixed partial dentures. Int J Prosthodont. 2006;(19):143–153.
61. Kim B, Zhang Y, Pines M, Thompson V. Fracture of Porcelain-veneered Structures in Fatigue. J Dent Res. 2007 Feb. 1;86(2):142–146.
62. Vult Von Steyern P, Carlson P, Nilner K. All-ceramic fixed partial dentures designed according to the DC-Zirkon technique. A 2-‐year clinical study. J Oral Rehabil. 2005;32:180–187.
63. Borba M, Araújo MD de, Lima E de, Yoshimura HN, Cesar PF, Griggs JA, et al. Flexural strength and failure modes of layered ceramic structures. Dent Mater. 2011 Dec. 1;27(12):1259–1266.
64. Tholey MJ, Swain MV, Thiel N. Thermal gradients and residual stresses in veneered Y-TZP frameworks. Dent Mater. 2011 Nov. 1;27(11):1102–1110.
65. Sundh A, Molin M, Sjögren G. Fracture resistance of yttrium oxide partially stabilized zirconia all-ceramic bridges after veneering and mechanical fatigue testing. Dent Mater. 2005 Apr. 6;21:476–482.
66. Benetti P, Pelogia F, Valandro LF, Bottino MA, Bona AD. The effect of porcelain thickness and surface liner application on the fracture behavior of a ceramic system. Dent Mater. 2011 Sep. 1;27(9):948–953.
67. Kokubo Y, Tsumita M, Kano T, Fukushima S. The influence of zirconia coping designs on the fracture load of all-ceramic molar crowns. Dent Mater J. 2011;30(3):281–285.
68. Panadero R, Font Fons A, Solá Ruiz M, Granell Ruiz M, Labaig-Rueda C, Amigo-Borras V. Comportamiento de la porcelana de recubrimiento en coronas de óxido de circonio tras someterlas a carga estática. SEPES CIENCIA Y DIFUSION (VERRRRRR). 2011 Oct. 31;:1–3.
69. Kokubo Y, Tsumita M, Kano T, Fukushima S. The influence of zirconia coping designs on the fracture load of all-‐ceramic molar crowns. Dent Mater J. 2011;30(3):281–285.
70. Doi M, Yoshida K, Atsuta M, Takahashi S. Influence of Pre-treatments on Flexural Strength of Zirconia and Debonding Crack-initiation Strength of Veneered Zirconia. J Adhes Dent. 2011 Mar. 1;13(1):79–84.
71. Lopez-‐Molla M Martinez-Gonzalez M, Manes-Ferrer J, Amigo-Borras V, Bouazza-Juanes K. Bond strength evaluation of the veneering-Ceramics bonds. Med Oral Patol Oral Cir Bucal. 2010;1(15):e919–e923.
72. Vega del Barrio J. Resistencia al cizallamiento de un sistema totalmente cerámico frente a siete sistemas ceramo-metálicos: estudio comparativo. RCOE. 2005;10(5):529–539.