INTRODUCTION
The global demand for ideal dental aesthetics is based on the assumption that beauty is associated with favorable personality traits1. Ceramics are used in dentistry as aesthetic restorative materials due to their satisfactory mechanical properties such as high compressive strength, chemical stability, low electrical conductivity, thermal diffusivity, translucency, fluorescence, biocompatibility (they provide low solubility, reduce plaque accumulation and enable sufficient marginal adjustment), favorable aesthetic properties and thermal expansion coefficient similar to that of tooth structure2,3. However, the brittle nature of ceramics has led to high fracture rates, mainly in the case of glass-ceramic systems placed in the posterior region4. Lithium disilicate glass-ceramic system is a unique material with microstructure interconnected with lithium disilicate crystals similar to needles making up to 70% volume incorporated into a glassy matrix5. It is used in indirect restorations to emulate the aesthetics and natural resistance of dental structures6. It provides translucency similar to that of natural teeth and biaxial resistance of up to 400 MPa, which is almost three times higher than that of conventional glass ceramics5. The use of ceramic veneers in dentistry has increased due to high degree of aesthetic requirements, since lithium disilicate facets can restore dental aesthetics by making the restoration look very similar to the natural dental structure. Moreover, it requires less invasive preparations or even no cavity preparation at all7. The aesthetic quality of the material is not the only criterion to be taken into consideration to ensure successful restoration procedures. Ceramic veneers must be firmly attached to the dental structure by resin cements in order to ensure good strength, aesthetics and clinical longevity8,9.
According to their polymerization method, resin cements can be classified as chemically activated, physically activated or dual activation (dual cement), which combines both activation forms. Light-activated resin cements are the material of choice in situations such as cementation of ceramic veneers due to their color stability and long working time10. However, the maximum degree of conversion (DC) of light-activated resin cement cannot be ensured in situations where light has been attenuated. Insufficient degree of conversion can adversely affect the mechanical properties, change the dimensional stability and decrease bond strength between resin cements and dental and ceramic structures, thereby impairing the clinical longevity of restorations11. Accordingly, based on the aforementioned assumptions, further studies are needed to clarify the effect of processing techniques of the lithium disilicate-based restoration on the degree of conversion and bond strength of resin cement. The aim of the current study was thus to compare the effect of two lithium disilicate ceramic processing techniques (pressing and CAD/ CAM [Computer Aided Design/Computer Aided Machining]) on the degree of conversion of resin cement when it is photoactivated and the microshear bond strength of resin cement to ceramics. The null hypotheses are that there is no difference between the two processing techniques regarding either [1] the degree of conversion of resin cement or [2] the microshear bond strength of resin cement to ceramics.
MATERIALS AND METHODS
Ceramic disc and bar Preparation
Two discs (10 mm diameter by 0.6 mm thick) and twenty bars (6.5-mm long x 5-mm wide x 1-mm thick) were manufactured in lithium disilicate glass ceramic. One disc and 10 bars were based on the manufacturing technique applied to lithium disilicate ceramic indirect restorations, followed by the automation technique guided by the CAD/CAM system (IPS e.max CAD; Ivoclar Vivadent, Schaan, Liechtenstein), while the other disc and 10 bars were prepared by isostatic injection based on heat technology (IPS e.max Press; Ivoclar Vivadent), both in shade LT A1. The resulting discs were subjected to sequential wet polishing with silicon carbide abrasive papers (320, 400, 600 and 1200 grit; Norton SA, Sao Paulo, SP, Brazil) in a water-cooled automatic polisher (APL4; Arotec, Cotia, SP, Brazil), to achieve their final diameter (10 mm) and thickness (0.5 mm), and cleaned ultrasonically with distilled water for 10 min and dried with compressed air. Disc thickness was measured with a 0.01mm accuracy digital caliper (Mitutoyo Corporation, Tokyo, Japan).
The LED curing unit output (Radii Cal; SDI, Bayswater, Victoria, VIC, Australia) was measured with a power meter (Ophir Optronics Inc., Danvers, MA, USA) at irradiance 1200 mW/cm2.
Measurement of degree of conversion in resin cement
For analysis of degree of conversion, 10 cylindrical specimens were prepared by inserting Variolink Veneer light-curing resin cement (Ivoclar-Vivadent, shade HV+1) into a mold (1.0 mm deep / 7 mm diameter). Specimens were divided into two groups and cured for 20 s either through the CAD/CAM ceramic disc (n=5) or through the Press ceramic disc (n=5). Then they were washed in distilled water, dried with absorbent paper, placed in containers and stored at 37 °C for 24 hours.
The unpolymerized resin cement was accessed twice in order to set the bonding pattern of its monomeric state before sample analysis. Subsequently, all specimens were analyzed through Fourier Transform Infrared Spectroscopy - FTIR (Spectrum 100 Optica; Perkin Elmer, MA, USA), with attenuated total reflectance (ATR), using horizontal Zinc Seleneto crystal (Pike Technologies, Madison, WI, USA), which acted as active substrate for the infrared rays.
Graphs were generated in the Spectrum software version 6.3.1 (PerkinElmer) for visualization and analysis. The FTIR spectrometer operated under the following conditions: 300-4000 cm-1 wavelength, 4 cm-1 resolution and 16 scans. Degree of conversion (DC) was calculated by comparing the aliphatic carbon-carbon double bond ratio (C=C) at 1640 cm-1 and C=O at 1710 cm-1 in cured and uncured materials, based on the following equation: DC (%) = (polymerized 1 - R / unpolymerized R) X 100; wherein R = peak at 1640 cm-1/peak at 1710 cm-1. These calculations were carried out in Microsoft Office Excel 2007 software (Microsoft Office Professional Edition 2007, Microsoft Corporation).
Measurement of microshear bond strength
The bars were separated into two groups - Press ceramic group (n=10) and CAD/CAM ceramic group (n=10) according to the manufacturing method. Bars were wet polished with 600- and 1200-grit silicon carbide abrasive papers (Norton SA, Sao Paulo, SP, Brazil) to produce a flat surface, dried, and air-abraded with 50 pm Al2O3 particles (Bioart, Sao Carlos, SP, Brazil). Then they were ultrasound cleaned in distilled water for 10 min and dried again. Subsequently, they were treated with 10% hydrofluoric acid for 20 s (Dentsply, Petrópolis, RJ, Brazil), subjected to RelyX Ceramic Primer (3M ESPE, St. Paul, MN, USA) application for 60 s and thoroughly air-dried. Adper Scotchbond MultiPurpose Adhesive (3M ESPE) was applied with microbrush to all pretreated ceramic surfaces for 20 s, which were then thoroughly air thinned for 10 s and cured with LED curing light (Radii-Cal; SDI, Bayswater, VIC, Australia) at 1200 mW/cm2 for 10 s through their respective ceramic disc, according to each processing technique. Two transparent cylindrical molds (Tygon tubing - TyG-03; Saint-Gobain Performance Plastic, Maime Lakes, FL, USA) (height 1 mm; internal diameter 0.75 mm) were positioned on the surface of each bar12. A #5 exploratory probe (Hu-Friedy, Chicago, IL, USA) was used to apply the resin cement inside the molds. Each resin cement cylinder (two cylinders per bar) was photoactivated for 20 s through its respective ceramic disc and stored in distilled water at 37 °C.Twenty-four (24) hours later, the molds were removed with the aid of a scalpel blade to expose two cement cylinders with a bond area of 0.38 mm2 (each). Bars were mounted on a steel device in a universal testing machine (DL2000; Emic, Sao José dos Pinhais, PR, Brazil). Load was applied at the base of the cylinder with the aid of a steel wire (0.2 mm diameter) at speed of 0.5 mm/min until fracture to determine the microshear bond strength. Each group contained 10 bars and each bar had two cylinders, providing a total of 20 cylinders per group. The average between the two cylinders on each bar was considered a specimen.
Statistical Analysis
Data were subjected to statistical analysis in the SAS System for Windows 9.0 (SAS Institute Inc., Cary, NC, USA). Measurement distribution was subjected to Kolmogorov-Smirnov test, after which parametric tests were used. Degree of conversion (%) and microshear bond strength values (MPa) were subjected to Student's t-test, at 5% significance level.
RESULTS
Table 1 shows the mean values for degree of conversion and microshear bond strength. The mean of degree of conversion of resin cement was statistically higher when photoactivated through ceramic prepared with the CAD/CAM processing technique than through ceramic prepared with the Press processing technique. The microshear bond strength of resin cement was statistically higher when bonded to ceramic prepared with the CAD/ CAM processing technique than ceramic prepared with the Press processing technique.
DISCUSSION
Lithium disilicate-based ceramics have been extensively used to manufacture full and partial monolithic restorations13. Two processing techniques are available: pressing and CAD/ CAM technology14-16. Pressing technology is a classic methodology used to manufacture duplicate restorations in wax, which is inserted in a special investment cast. Next, flame-volatilized ceramic ingots are injected into the cast under high vacuum so that the shape of the final restoration is identical to that of the wax piece (lost-wax technique)15. CAD/CAM systems use digital workflow to achieve final restorations through digital casts. Restoration and the milling process are designed in computer software, which provides high precision, efficiency and accuracy, in addition to reducing processing time17. Thus, the current study assessed the degree of conversion of resin cement when photoactivated through ceramic prepared using two different processing techniques (Pressing and CAD/CAM) and the microshear bond strength of resin cement to ceramics prepared in these two ways.
It is known that resin cement polymerization can be affected if light does not reach it18. Thickness and shade are two of the factors capable of hindering polymerization processes19,20. Only discs with similar ceramic thickness (0.5mm) and shade (HV+1) were used in the current study to prevent these factors from affecting the degree of conversion of the resin cement. The photopolymerizing device was placed in contact with the ceramic bars in order to avoid any differences in the distance between the ceramic type and light. The same light-curing unit (LED with 1200 mW/cm2) and exposure time (20 s) were used for the resin cement. However, irradiance after the interposition of ceramic discs was attenuated to 1110 mW/cm2 in the CAD/CAM processing technique and to 1020 mW/cm2 in the Press processing technique. Few studies available in the literature have shown similar outcome for material microstructure. According to Alkadi and Ruse21, materials subjected to the pressing technique had increased crystallization rates, whereas Peng et al.22 found larger grain size of lithium-disilicate crystals in the pressable form (CAD/CAM — 0.1-1.0mm <Pressed — 3-6mm). Both complete crystallization and grain size of lithium-disilicate crystals can potentially affect the mechanical performance of the material. Based on the current results, ceramic manufacturing technique (Press or CAD/ CAM) significantly influenced the degree of conversion of the resin cement, which was statistically higher for resin cement photoactivated through ceramic processed with the CAD/CAM technique than for resin cement photoactivated through ceramic processed with the press technique.
Bond strength between resin cements and lithium disilicate ceramics is an important factor for ensuring long-lasting dental restorations6. Stress transfer to the remnant tooth through the ceramic restoration depends on adequate bonding interface, which can prevent failures23. The present study has found differences in the bond strength of resin cement to the lithium disilicate ceramics manufactured with different techniques. Findings in the present study are clinically acceptable, regardless of the material resistance to microshear values (13 MPa-30 MPa)24,25. Previous studies have found that material resistance declines over time24,25. However, the present study did not use simulated aging to assess microshear bond strength, which could be seen as a research limitation. Thus, further studies are needed focused on assessing bond strength after simulated aging based on different processing techniques. Based on results in the current study, the null hypotheses were rejected because different degrees of conversion [1] and microshear bond strengths [2] were found for the two processing techniques.
CONCLUSIONS
Based on the methodology and materials used, and on results observed in the current study, we conclude that:
1. The degree of conversion of resin cement was higher when it was photoactivated through ceramic prepared with the CAD/CAM technique than through ceramic prepared with the press technique.
2. The microshear bond strength of resin cement was greater when bonded to ceramic prepared with the CAD/CAM technique than ceramic prepared with the press technique.