Refereed journal article or data article (A1)
Long term water storage deteriorates bonding of composite resin to alumina and zirconia short communication
List of Authors: Heikkinen TT, Matinlinna JP, Vallittu PK, Lassila LV
Place: Netherlands
Publication year: 2013
Journal: Open Dentistry Journal
Journal name in source: The open dentistry journal
Journal acronym: Open Dent.J.
Volume number: 7
Start page: 123
End page: 125
Number of pages: 3
ISSN: 1874-2106
DOI: http://dx.doi.org/10.2174/1874210601307010123
Abstract
Objective of this study was to evaluate the effects of long term water storage and ageing on the bond strength of resin composite cement to yttria-stabilized zirconium dioxide (zirconia) and dialuminium trioxide (alumina). Substrate specimens of alumina and zirconia were air particle abraded with dialuminium trioxide before priming and application of composite resin. Priming was made with gamma metharyloxy-trimethoxysilane or acryloxypropyl-trimethoxysilane monomer after which the intermediate dimethacrylate resin was applied and photopolymerized. This was followed by curing particulate composite resin cement (Relyx ARC) to the substrate as a resin stub. The ageing methods of the specimens (n=6) were: (1) they stored four years in 37+/-1 masculineC distilled water, (2) thermocycled 8000 times between 55+/-1 masculineC and 5+/-1 masculineC, (3) stored first in water for four years and then thermocycled. Specimens which were stored dry, were used as controls. Bonding of composite resin was measured by shear-bond strength test set-up. Both thermocycling and long-term water storage decreased significantly shear bond strength values compared to the control group (from the level of 20 MPa to 5 MPa) regardless of the used primer or the type of the substrate. Combination of four years water storage and thermocyling reduced the bond strength even more, to the level of two to three megapascals. In can be concluded that water storage and thermocycling itselves, and especially combination of water storage and thermocycling can cause considerable reduction in the bond strength of composite resin cement to alumina and zirconia.\nLR: 20131101; JID: 101480503; OID: NLM: PMC3807579; OTO: NOTNLM; 2013 [ecollection]; 2013/06/03 [received]; 2013/08/16 [revised]; 2013/09/03 [accepted]; 2013/09/30 [epublish]; epublish
Objective of this study was to evaluate the effects of long term water storage and ageing on the bond strength of resin composite cement to yttria-stabilized zirconium dioxide (zirconia) and dialuminium trioxide (alumina). Substrate specimens of alumina and zirconia were air particle abraded with dialuminium trioxide before priming and application of composite resin. Priming was made with gamma metharyloxy-trimethoxysilane or acryloxypropyl-trimethoxysilane monomer after which the intermediate dimethacrylate resin was applied and photopolymerized. This was followed by curing particulate composite resin cement (Relyx ARC) to the substrate as a resin stub. The ageing methods of the specimens (n=6) were: (1) they stored four years in 37+/-1 masculineC distilled water, (2) thermocycled 8000 times between 55+/-1 masculineC and 5+/-1 masculineC, (3) stored first in water for four years and then thermocycled. Specimens which were stored dry, were used as controls. Bonding of composite resin was measured by shear-bond strength test set-up. Both thermocycling and long-term water storage decreased significantly shear bond strength values compared to the control group (from the level of 20 MPa to 5 MPa) regardless of the used primer or the type of the substrate. Combination of four years water storage and thermocyling reduced the bond strength even more, to the level of two to three megapascals. In can be concluded that water storage and thermocycling itselves, and especially combination of water storage and thermocycling can cause considerable reduction in the bond strength of composite resin cement to alumina and zirconia.\nLR: 20131101; JID: 101480503; OID: NLM: PMC3807579; OTO: NOTNLM; 2013 [ecollection]; 2013/06/03 [received]; 2013/08/16 [revised]; 2013/09/03 [accepted]; 2013/09/30 [epublish]; epublish
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