INTRODUCTION
Light-curing composites are the most frequently used materials in dental practice, with a wide range of applications. In recent years, a new kind of composite resins has been developed, known as bulk-fill composites because they can be placed in a single increment, thereby simplifying and shortening the restoration procedure. They are presented commercially according to consistency as high- or low-viscosity, and according to polymerization activation as self-curing, light-curing or dual-curing. These materials polymerize adequately when applied in layers 4 or 5 mm thick, according to brand. Some manufacturers explain that the greater curing depth of these materials is due to the addition of a more sensitive photoinitiator system and greater translucence of the material 1 . At the same time, they generate less shrinkage stress, which may vary according to composition, whether by modification of monomers or the filler content, or by addition of stress mitigators or polymerization modulators 2, 3 . Increasing the thickness of the layer of material would imply an increase in polymerization shrinkage. This needs to be considered in the development of these materials in order to compensate for it by modifying the formulations, e.g., by increasing the ceramic filler load or the molecular weight of the monomers 4 . These modifications imply an increase in the modulus of elasticity of the material, which minimizes the possibility of dissipating tensions generated during polymerization 5 .
Flowable bulk-fill composites have a greater content of organic matrix, which may lead to greater polymerization shrinkage and low mechanical properties, which conditions its application in occlusal areas. Bulk-fill composite manufacturers therefore indicate that they must be covered with a layer of conventional composite 3, 6 . Some authors confirm a reduction in shrinkage stress in bulk-fill composites with low percentage of filler despite the increase in thickness of the layer of material 2, 4 . These materials with low percentage of ceramic filler, such as SDR Flow, minimize shrinkage stress because they contain a chemical component that acts as polymerization modulator, with the aim of slowing polymerization speed to reduce shrinkage stress in spite of being polymerized with curing units in continuous, high-intensity mode 2 .
The aim of this new kind of restorative composites, which is to shorten operation times by increasing the thickness of each layer, may hinder the penetration of curing light, reducing the degree of conversion of monomers to polymers 7 . The degree of conversion of a composite depends not only on its composition, but also on factors related to photoactivation, including the curing unit used, the type of photoactivation selected and the quantity of energy applied 1 . Another factor to consider with relation to degree of conversion is the possibility of composite resins undergoing elution in the oral cavity, with special interest in the release of monomers, due to their potential cytotoxicity 8 . It has been shown that monomer release is inversely proportional to the degree of conversion of monomers into polymers, which is related to exposure time to light, among other factors. Nevertheless, arbitrarily increasing polymerization time with the aim of preventing lack of curing may damage not only the pulp, but also adjacent tissues due to increase in temperature 9-11 . Previous studies have shown that degree of conversion can be measured directly or indirectly. Czasch et al. 12 and Leprince et al. 13 recommend evaluating the degree of conversion directly, while other authors recommend measuring microhardness as an indirect method for determining degree of conversion 14-16 , since there are publications that have reported a good correlation between degree of conversion and microhardness 17-19 . Another method for evaluating degree of curing according to thickness of the material is by evaluating hardness at the surface exposed to the light (top) and the opposite surface (bottom), considering polymerization to be adequate when the ratio between them is 80% or higher.
The aim of this study was to determine Vickers microhardness (HV) in bulk-fill resins at different depths.
MATERIALS AND METHODS
Four bulk-fill composites were used for this study: 1) Filtek Bulk-Fill (3M ESPE), 2) Surefill SDR flow (Dentsply), 3) Fill-UP (COLTENE), and 4) Surefil (Dentsply) (Table 1).
Semi-cylindrical test specimens were prepared in a mold 6 mm in diameter and 4 mm deep (n=5). The flat surface was dismountable to allow microhardness to be determined in the depth of the specimen (Fig. 1). Specimens were cured with a Coltolux LED unit (Coltene) at intensity 1000 mW/cm 2 for 20 s.
An extra-fine indelible marker was used to draw a vertical mark on each specimen to divide it in half and separate the indentations made immediately after light curing (t0) on one side from those made at 24 hours (t24) on the other side (Fig. 2).
Hardness was measured with a Vickers Future Tech FM300 microhardness tester by indenting with 300 g for 8 seconds at depths of 1, 2, 3 and 4 mm. Fig. 3 shows an example of the indentations made. Measurements were recorded and analyzed statistically by ANOVA for repeated measures ad
Tukey’s test. Two-way ANOVA was used to analyze the time variable.
RESULTS
Table 2 shows means and standard deviations of the values recorded.
Table 3 shows the value of the ratio of the hardness measured at 4 and 1 mm depths, according to the formula hardness at 4 mm / hardness at 1 mm. Analysis of variance showed a significant effect of depth and depth-time interaction (p<0.05) when microhardness was measured immediately after polymerization (T0) (Table 4). Tukey’s test described the presence of 3 subsets: 1) Surefill SDR flow, 2) Fill-UP and Filtek Bulk-Fill, and 3) Surefil. At 24 hours (T24), a statistically significant difference was found for depth and not for depth/ material interaction (Table 5). Tukey’s test showed four subsets, with all materials differing significantly from each other.
Taking as a reference the values detected at 4 mm depth, analysis of variance showed the significant effect of the variables time and material (p<001), with no significant difference in the interaction between these two variables (p=0.706). Tukey’s test described the presence of 3 subsets: 1) Surefill SDR flow, 2) Filtek Bulk-Fill and Fill-UP, and 3) Surefil (Table 6).
DISCUSSION
The flowable bulk-fill resins used in this study had lower microhardness values than those of regular consistency, in agreement with previous studies 3,11,16, 20 , possibly due to their low ceramic filler content. In addition, SDR Flow resin is light-curing, while Fill Up resin is dual-curing, which suggests that it may be harder than SDR Flow as a result of the sum of the two forms of activation. It is also important to consider the post-cure factor, since microhardness values measured immediately after curing the composites differed significantly from those measured 24 hours later 11,21, 22 .
Composite resin microhardness is also affected by the thickness of the layer 20 . It was concluded in that study that resin hardness in the area farthest from the curing unit (bottom) differed significantly from hardness at the top in specimens 4 or 5 mm thick. Lower microhardness values at 4 mm thickness agree with results of other studies 23 .
Regarding the evaluation of microhardness in depth, some studies have determined top and bottom hardness of specimens of different thicknesses of light-cured composite resin to define its curing depth. Kim et al. 20 evaluated Vickers microhardness only at top and bottom of different specimens 2, 3 and 4 mm thick, using a load of 200 grams with a 10-second dwell time, finding that hardness decreases with increasing depth, though the decrease is less in bulk-fill composites. They conclude that there is statistically significant difference in microhardness according to type and thickness of the material, and the interaction between them, in agreement with the results found in the current study, even though a different measuring method was used. Another variable considered in the literature is the uniformity of polymerization throughout the thickness of the material, e.g., the study by Fronza et al. 16 showing that degree of conversion is not uniform in specimens thicker than 4mm. In that study, only SDR and FBF showed uniform polymerization throughout the restoration. It is therefore necessary to evalúate microhardness not only at the surface, but also at different depths. Our study took measurements at different depths in each specimen to minimize the factors that could influence results. This methodology was also used by Comba et al. 24 , who evaluated Vickers microhardness not only by means of the bottom/top ratio, but also at each millimeter in depth in specimens 6 mm thick. Considering surface microhardness values as reference points, the regression analysis showed that SDR had a significant difference at 2 mm depth, and X-tra Base and Filtek Bulk Fill showed a significant difference at 3 mm depth, with values lower than those recommended by the manufacturer. They also found that SDR had the lowest microhardness values, attributable to its low percentage of ceramic filler. According to the authors, other materials such as Filtek Bulk Fill, showed a low percentage in filler content by volume, but higher microhardness values, which may also be attributed to other factors unrelated to filler content, but strictly associated to the composition of the matrix.
Although the results showed statistically significant differences at different depths, analysis ofthe general behavior shows that the level of polymerization was acceptable at the depths suggested by the manufacturers, considering that the ratio between hardness measured at depths of 4 and 1 mm was greater than 80% for all materials. A bottom/top hardness ratio higher than 80% is usually used as a minimum clinically acceptable threshold for degree of conversion. Although our study did not directly evaluate top and bottom microhardness, but measured it instead at each millimeter of depth, the hardness ratio between mm 1 and mm 4 was 80% or more for the bulk-fill composites used. This means that the study materials can be adequately placed and cured in thicknesses of 4 mm, with statistically significant differences at the depths evaluated. These results agree with Kim et al. 20 and Rizzante et al. 3 , who concluded that the bottom/top ratio was higher than 80% down to depths of 4.0 and 4.5 mm in all Bulk-Fill composites.
It would be advisable to conduct further studies to evaluate the degree of cytotoxicity of this type of bulk-fill resins in order to securer a more complete evaluation of their characteristics.