Influence of pulse-delay curing on sorption and solubility of a composite resin

Lopes, Lawrence Gonzaga; Jardim Filho, Alfeu da Veiga; Souza, João Batista de; Rabelo, Denilson; Franco, Eduardo Batista; Freitas, Gersinei Carlos de

doi:10.1590/S1678-77572009000100006

Abstract

The purpose of this study was to evaluate the sorption and solubility of a composite resin (TPH³; Dentsply) cured with halogen light due to different storage media and curing modes. The methodology was based on the ISO 4049 standard. Two independent groups were established according to the storage time (7 days-G1; 60 days-G2). A stainless steel mould (2 mm x 8 mm Ø) was used. The selected curing modes were: I (Conventional - C): 40s - 600 mW/cm²; II (Pulse I - PD): 3 s - 200 mW/cm² + 2 min (delay) + 39 s - 600 mW/cm²; III (Pulse II): 10 s - 200 mW/cm² + 2 min (delay) + 37 s - 600 mW/cm²; IV (Pulse III): 3 s- 600 mW/cm² + 2 min (delay) + 37 s -600 mW/cm². The media used were: distilled water, 75% ethanol and 100% chlorophorm. Five repetitions were made for each group. The specimens were placed in a desiccator at 37ºC for 24 h and, after that, at 23ºC for 1 h to be weighed until a constant mass (m1) was obtained. The discs were immersed separately into the 3 media for 7 days (G1) and 60 days (G2), and thereafter reweighed (m2). The reconditioning in the desiccator was done until a constant mass (m3) was obtained. Sorption and solubility were calculated and the data of G1 and the sorption data of G2 were subjected to two-way ANOVA and Tukey's tests (p=0.05). The solubility data of G2 were analyzed by Kruskal-Wallis test (p=0.05). For G1 and G2, no statistically significant differences were found in sorption among curing techniques (p>0.05). The solubility values were negative, which means that there was mass gain. Regarding the storage media, in G2 chlorophorm had the highest sorption values. It may be concluded that the curing modes (C and PD I, II and III) did not affect the sorption of the tested composite resin. However, different storage media influenced sorption behavior. The solubility test demonstrated negative data, masking the real solubility.

Composite resins; Solubility; Solvents

ORIGINAL ARTICLES

Influence of pulse-delay curing on sorption and solubility of a composite resin

Lawrence Gonzaga Lopes^I; Alfeu da Veiga Jardim Filho^I; João Batista de Souza^I; Denilson Rabelo^II; Eduardo Batista Franco^III; Gersinei Carlos de Freitas^I

^IDDS, MSc, PhD, Adjunt Professor, Department of Prevention and Oral Rehabilitation, Dental School, Federal University of Goiás, Goiânia, GO, Brazil

^IIDDS, MSC, PhD, Adjunt Professor, Institute of Chemistry, Federal University of Goiás, Goânia, GO, Brazil

^IIIDDS, MSc, PhD, Professor, Department of Operative Dentistry, Dental Materials and Endodontics, Bauru School of Dentistry, University of São Paulo, Bauru, SP

^{Corresponding address} Corresponding address: Dr. Lawrence G. Lopes Departamento de Prevenção e Reabilitação Oral Faculdade de Odontologia - Universidade Federal de Goiás Praça Universitária, s/n - Faculdade de Odontologia - Setor Universitário 74605-220 - Goiânia, GO - Brasil Phone: +55-62-3209-6050 - Fax: +55-62-3521-1882 e-mail: drlawrenceg@yahoo.com.br

ABSTRACT

The purpose of this study was to evaluate the sorption and solubility of a composite resin (TPH³; Dentsply) cured with halogen light due to different storage media and curing modes. The methodology was based on the ISO 4049 standard. Two independent groups were established according to the storage time (7 days-G1; 60 days-G2). A stainless steel mould (2 mm x 8 mm Ø) was used. The selected curing modes were: I (Conventional - C): 40s - 600 mW/cm²; II (Pulse I - PD): 3 s - 200 mW/cm² + 2 min (delay) + 39 s - 600 mW/cm²; III (Pulse II): 10 s - 200 mW/cm² + 2 min (delay) + 37 s - 600 mW/cm²; IV (Pulse III): 3 s- 600 mW/cm² + 2 min (delay) + 37 s -600 mW/cm². The media used were: distilled water, 75% ethanol and 100% chlorophorm. Five repetitions were made for each group. The specimens were placed in a desiccator at 37ºC for 24 h and, after that, at 23ºC for 1 h to be weighed until a constant mass (m₁) was obtained. The discs were immersed separately into the 3 media for 7 days (G1) and 60 days (G2), and thereafter reweighed (m₂). The reconditioning in the desiccator was done until a constant mass (m₃) was obtained. Sorption and solubility were calculated and the data of G1 and the sorption data of G2 were subjected to two-way ANOVA and Tukey's tests (p=0.05). The solubility data of G2 were analyzed by Kruskal-Wallis test (p=0.05). For G1 and G2, no statistically significant differences were found in sorption among curing techniques (p>0.05). The solubility values were negative, which means that there was mass gain. Regarding the storage media, in G2 chlorophorm had the highest sorption values. It may be concluded that the curing modes (C and PD I, II and III) did not affect the sorption of the tested composite resin. However, different storage media influenced sorption behavior. The solubility test demonstrated negative data, masking the real solubility.

Key words: Composite resins. Solubility. Solvents.

INTRODUCTION

An increasing demand for esthetic restorative materials has occurred greatly in recent years²⁰. Visible light-cured composite resins are widely used in restorative dentistry. Polymerization of the methacrylate monomers in these composite resins leads to a highly crosslinked structure⁵. Traditionally, the manufacture's have recommended high light intensity or power density (PD) to provide a higher degree of monomer conversion to polymer, improving the mechanical properties of composite resins. Unfortunately, the degree of conversion of these materials is always proportionally associated with shrinkage and a high rate of polymerization^2,3,10. In order to reduce the contraction stresses, a slow cure of composite resins can be used, which results from a more extended period of viscous flow in the pre-gel phase of light-activated resins^3,8. A slow cure may be achieved by the so-called soft-start curing technique, where a reduced intensity of curing light is used during the first part of the polymerization period^5,26. Another method is the pulse-delay cure, where the polymerization is initiated by a short flash of light followed by a waiting time of some minutes before the final cure is performed^17,21. Such method does not seem to modify the polymerization mechanisms and the degree of conversion of the monomer¹¹. However, it is important to consider that the different irradiation procedures will lead to different structures of the resulting polymer, even though the degree of conversion of the double bonds is the same⁵.

Ideally, dental polymer should remain stable¹². However, due to their hydrophilic nature, it usually does not occur^12,16. Water sorption may deteriorate polymer mechanical properties¹⁶. This effect is a product of the separation of the polymer chains by a molecule that does not form primary chemical bonds with the chain. The phenomena of sorption and solubility may serve as precursors to a variety of chemical and physical processes that can create biological concerns¹⁴. Thus, the polymer structure quality resulting by photo-activated mode may lead to differences in sorption and solubility. Additionally, as the degree of conversion and crosslink can influence the chemical degradation that is usually caused by oxidation processes and\or hydrolysis²³, the evaluation of composite resin in solvents plays an important role to create scientific evidence for its application in dentistry.

The aim of this study was to investigate the effect of different pulse-delay curing protocols on water sorption and solubility of a composite resin using three solvents. The tested null hypotheses were: (1) there is no difference among curing techniques with respect to sorption and solubility; (2) there is no difference among solvents tested on the sorption and solubility.

MATERIAL AND METHODS

A nanohybrid composite resin (TPH³; Dentsply Ind. e Com. Ltda, Rio de Janeiro, RJ, Brazil; shade A2), which contains BisGMA and BisEMA resins and 75.2% in weight of silanized barium, boro-silicate-aluminium/barium, fluor-aluminium-boro-silicate/silica fillers, and a commercial light-curing unit that allows independent command over time and intensity (VIP; Bisco Inc., Schaumburg, IL, USA) were selected for this study. The 4 light-curing modes evaluated were listed in Table 1. The light energy density, which is critical for polymerization, was kept constant for all curing modes. The light irradiance for each cure mode was checked with the in-built radiometer prior to use to ensure consistency of light output. Three solvents were used: distilled water, 75% ethanol, 100% chloroform. The sorption and solubility test was performed in compliance with ISO 4049:1988¹⁵ standard specifications, except for the specimen dimensions and types of solvent. The specimen dimensions were changed to approximate to the light guide diameter of the light-curing unit. Two independent groups were established according to the storage time (7 days-G1; 60 days-G2). Five disc-shaped composite resin specimens were prepared for each group. The composite material was placed in a stainless steel mould (2 mm thick x 8 mm diameter) and confined between two opposing acetate strips. A 1-mm-thick glass slide was placed on the mould and excess material was extruded by pressure. The composite was irradiated using the different light curing modes. The polymerized specimens were removed from the mould and excesses were eliminated with a scalpel blade.

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Specimens were stored in desiccators at 37ºC containing silica gel. After 24 h, the discs were removed, stored in desiccators at 23ºC for 1 h and were then weighed in an analytical balance (Bioprecisa, Electronic Balance, Curitiba, PR, Brazil) accurate to 0.01 mg. This cycle was repeated until a constant mass (m1) was obtained, i.e. until the mass loss of each specimen was not more than 0.2 mg within a 24-h period. Thereafter, the specimens were stored separately in 5 mL of each solvent (distilled water, 75% ethanol and 100% chlorophorm) at 37ºC. G1 was stored for 7 days and G2 for 60 days. After completing the storage periods, the specimens were weighed again, after being carefully wiped with an absorbent paper until reaching a constant weight (m₂). Thereafter, the specimens were reconditioned in the desiccators until they reached a constant weight (m₃) using the cycle describe for m₁. The thickness and diameter of each specimen were measured at 4 points and at the center of the specimen using a digital electronic caliper (Mitutoyo Corporation, Tokyo, Japan).

The values for sorption and solubility, in micrograms per cubic millimeter, were calculated using the following equations:

where :

m₁is the conditioned mass prior to immersion in the solvent;

m₂is the mass of the specimen after immersion in the solvent;

m₃ is the reconditioned mass;

V is the volume of the specimen.

Sorption and solubility were calculated and the data of G1 (7 days) and the sorption data of G2 (60 days) were subjected to two-way ANOVA and Tukey's tests (p=0.05). The solubility data of G2 were analyzed by Kruskal-Wallis test (p=0.05), since a non-normal data distribution was observed.

RESULTS

Sorption and solubility mean for G1 and G2 are shown in Tables 2 and 3, respectively. Regarding sorption data for 7 days (G1) and 60 days (G2), there were no statistically significant differences (p>0.05) among the curing modes when immersed in the 3 solvents (distilled water, p=0.162; p=0.652, respectively; 75% ethanol, p=0.531; p=0.182, respectively; 100% chloroform, p=0.102; p=0.179). Therefore for sorption data, the first anticipated null hypothesis was accepted. The effect of different solvents showed statistically significant differences (p<0.05) for both evaluation periods. Hence, the second null hypothesis was rejected. For G1, chloroform provided the lowest mean sorption value when PD III curing mode was used (p=0.002). In other experimental variables, there were no statistically significant differences among solvents. For G2, in all curing modes, chloroform provided the highest sorption mean values (p<0.001), while distilled water provided the lowest ones (p<0.001). Ethanol showed intermediate mean values, being statistically different from water and chloroform (p<0.001).

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Regarding solubility data in G1 and G2, the two null hypotheses were partially rejected. For G1 when evaluated in water solvent, the conventional mode was significant different from PD I and II (p=0.030), however similar to PD III (p>0.05). Analyzing the other solvents (ethanol and chloroform), there were no significant differences among curing modes (p>0.05). For G2, there were no significant differences among curing modes in ethanol (p=0.414) and chloroform (p=0.07). In water solvent, the pulse modes (PD I, II and III) were statistically similar (p>0.05), however significantly different from conventional mode (p=0.007).

DISCUSSION

The clinical performance of BisGMA-based materials is to a great extent dependent on their mechanical properties and resistance to chemical degradation by acids and other organic substances found in the oral cavity^20,27. A given degree of conversion may be associated with polymers of structures differing in crosslink density⁵ that can be influenced by photoactivation methods^1,5,6.

The curing modes tested in the present study did not affect the sorption values obtained with 3 solvents and 2 evaluation periods (7 days and 60 days). These findings are in accordance with the results of previous studies that used different curing protocols with similar energy density^19,27. The pulse curing modes used in present study simulated three different conditions with the same energy density. Pulse delay I and II techniques were based on Kanca and Suh¹⁷ (1999) investigations, which introduced this photoactivation mode to reduce the contraction stress of composite resins. Pulse delay III technique with higher initial light energy was tested because PD curing modes with short flash of initial light (PD I and II) can activate only a minor part of the camphoroquinone molecules resulting in few growth centers and a relatively linear polymer structure that can be more susceptible to ethanol degradation^5,24. The susceptibility of the more linear or less crosslink polymer to softening in solvents may be explained by the solvent-polymer interaction and, consequently, by Hoy's solubility parameter for polar forces^16,24. Some studies have shown a significant reduction in mechanical properties, such as flexural modulus and hardness, when composites are photo-cured by PD mode and submitted to solvent action^5,18,24. However, based on the methodology used in the present study and the obtained results, the curing modes had similar behaviors, which can be explained by the energy density used (24 J/cm²). Witzel, et al.²⁷ (2005) described that studies reporting the influence of curing mode in composite properties after ethanol storage used energy densities that were lower than 24 J/cm². Another explanation would be the use of filled composite resins for the test, since studies^4-6 that have reported that the PD mode provides polymers with a linear structure, used unfilled resins for their tests. Water sorption in composite materials is a diffusion-controlled process and occurs mainly in the resin matrix⁹. As most composites have the filler content between 80 and 85% and only 20-25% of organic matrix, this can influence on the different results found in previous studies about curing modes. A lower crosslinking degree will result in a higher degree of swelling²⁴, and hence a larger sorption effect. Therefore, it may be speculated that the absence of influence of solvents sorption due to different curing modes observed in the present study may be the result of the formation of a densely crosslinked polymer network due to the use of a sufficient energy density, compensating for the potentially negative effects of a low curing rate²⁷.

The effect of different solvents was clearly observed in G2 (60 days of storage) where 100% chloroform generated the highest sorption values, followed by 75% ethanol and distilled water, independently of the curing mode. Distilled water is a ISO-recommended solvent for resin-based filling material¹⁵ and simulates the wet intraoral environment provided by saliva and water. 75% ethanol has been the solvent of choice to simulate accelerated ageing of restorations as it has a solubility parameter that matches the one of BisGMA^16,28. The extent of solvent uptake by the polymer is a function of the differences in solubility parameter between the polymer and the solvent, being greatest when this difference is small¹⁴. When ethanol penetrates the polymer network, it causes an expansion of the structure, allowing the release of uncured monomers and causing dissolution of linear polymer chains^13,27. This expansion is facilitated when crosslink density is low, since the solvent can disrupt secondary inter-chain bonds, but not primary crosslink bonds^24,27. Although chloroform is not found in oral environment and has degradation and dissolution effects^7,25 unlike water and ethanol, this solvent was used in the present study to evaluate the composite behavior, when photo-cured by different curing modes. It was observed that the chloroform sorption data in G2 were higher than those of the other solvents. Thus, this solvent allowed for assessing the different curing modes under a more aggressive condition. Even though, the sorption values were also similar for all curing modes tested.

Both groups evaluated in this study (G1-7 days and G2-60 days) were analyzed independently because their specimens were prepared separately. G1's storage period was established based on the ISO 4049:1988 standard¹⁵ specifications, while G2 was designed for an evaluation time longer than 1 week. The specimens were submitted to a longer storage time in order to reach saturation, in accordance with Ortengren, et al.²³ (2001), who reported that most composites evaluated in their study reached saturation within 7 to 60 days. Negative values were detected in solubility data for all tested solvents and periods. This may indicate that the composite resin was more susceptible to water sorption leading to mass gain, which could mask the real solubility. It does not mean that no solubility occurred, but rather that water sorption was greater than solubility¹². This result may be attributed to composite's higher hydrophilicity¹². Some studies^12,22 have also found negative values.

The use of slow-cure methods (pulse curing modes) combined with the interval between two irradiations seem not to interfere with solvent sorption and could be useful for adhesive composite restorations.

CONCLUSION

Under the conditions of this in vitro study, it may be concluded that: 1. The curing modes (C and PD I, II and III) did not influence the sorption of the tested composite resin in the 3 solvents and in the 2 storage periods; 2. For 60 days of evaluation (G2), the storage media influenced sorption behavior; 3. The solubility test demonstrated negative data, masking the real solubility.

ACKNOWLEDGEMENTS

The authors would like to acknowledge Núbia Miranda Ferreira (Dentsply) for supplying the material. The authors are grateful to School of Pharmacy of the Federal University of Goiás for laboratory assistance.

Received: April 28, 2008

Modification: June 04, 2008

Accepted: June 17, 2008

1- Aguiar FHB, Braceiro A, Lima DANL, Ambrosano GMB, Lovadino JR. Effect of light curing modes and light curing time on the microhardness of a hybrid composite resin. J Contemp Dent Pract. 2007;8(6):1-8.
2- Alomari Q, Omar R, Akpata E. Effect of LED curing modes on postoperative sensitivity after Class II resin composite restorations. J Adhes Dent. 2007;9(5):477-81.
3- Asmussen E, Peutzfeldt A. Influence of composition on rate of polymerization contraction of light-curing resin composites. Acta Odontol Scand. 2002;60(3):146-54.
4- Asmussen E, Peutzfeldt A. Influence of pulse-delay curing on softening of polymer structures. J Dent Res. 2001;80(6):1570-3.
5- Asmussen E, Peutzfeldt A. Influence of selected components on crosslink density in polymer structures. Eur J Oral Sci. 2001;109(4):282-5.
6- Asmussen E, Peutzfeldt A. Two-step curing: influence on conversion and softening of a dental polymer. Dent Mater. 2003;19(6):466-70.
7- Asmussen E. Factors affecting the quantity of remaining double bonds in restorative resin polymers. Scand J Dent Res. 1982;90(6):490-6.
8- Bouschlicher MR, Rueggeberg FA. Effect of ramped light intensity on polymerization force and conversion in a photoactivated composite. J Esthet Dent. 2000;12(1):328-39.
9- Braden M, Causton BE, Clarke RL. Diffusion of water in composite filling materials. J Dent Res. 1976;55(5):730-2.
10- Davidson CL, De Gee AJ. Light-curing units, polymerization, and clinical implications. J Adhes Dent. 2000;2(3):167-73.
11- Emami N, Soderholm KJM, Berglund LA. Effect of light power density variations on bulk curing properties of dental composites. J Dent. 2003;31(3):189-96.
12- Fabre HSC, Fabre S, Cefaly DFG, Carrilho MRO, Garcia FCP, Wang L. Water sorption and solubility of dentin bonding agents light-cured with different light sources. J Dent. 2007;35(3):253-8.
13- Ferracane JL. Elution of leachable components from composites. J Oral Rehabil. 1994;21(4):441-52.
14- Ferracane JL. Hygroscopic and hydrolytic effects in dental polymer networks. Dent Mater. 2006;22(3):211-22.
¹⁵
- International Organization for Standization. ISO 4049: dentistry – resin-based filling materials. Geneva: The Organization; 1988.
16- Ito S, Hashimoto M, Wadgaonkar B, Svizero N, Carvalho RM, Yiu C, et al. Effect of resin hydrophilicity on water sorption and changes in modulus of elasticity. Biomaterials. 2005;26(33):6449-59.
17- Kanca J, Suh BI. Pulse activation: reducing resin-based composite contraction stresses at the enamel cavosurface margins. Am J Dent. 1999;12(3):107-12.
18- Lee SY, Huang HM, Lin CY, Shih YH. Leached components from dental composites in oral simulating fluids and the resultant composite strengths. J Oral Rehabil. 1998;25(8):575-88.
19- Lim BS, Ferracane JL, Sakaguchi RL, Condon JR. Reduction of polymerization contraction stress for dental composites by two-step light-activation. Dent Mater. 2002;18(6):436-44.
20- Lopes LG, Cefaly DGF, Franco EB, Mondelli RFL, Lauris JRP, Navarro MFL. Clinical evaluation of two "packable" posterior composite resins: two-year results. Clin Oral Investig. 2003;7(3):123-8.
21- Lopes LG, Franco EB, Pereira JC, Mondelli RFL. Effect of light-curing units and activation mode on polymerization shrinkage and shrinkage stress of composite resins. J Appl Oral Sci. 2008;16(1):35-42.
22- Malacarne J, Carvalho RM, Goes MF, Svizero N, Pashley DH, Tay FR, et al. Water sorption/solubility of dental adhesive resins. Dent Mater. 2006;22(10):973-80.
23- Örtengren U, Wellendorf H, Harlosson S, Ruyter IE. Water sorption and solubility of dental composites and identification of monomers released in an aqueous environment. J Oral Rehabil. 2001;28(12):1106-15.
24- Soh MS, Yap AUJ. Influence of curing modes on crosslink density in polymer structures. J Dent. 2004;32(4):321-6.
25- Suzuki K, Ishikawa K, Sugiyama K, Furuta H, Nishimura F. Content and release of bisphenol a from polycarbonate dental products. Dent Mater J. 2000;19(4):389-95.
26- Uno S, Asmussen E. Marginal adaptation of a restorative resin polymerized at reduced rate. Scand J Dent Res. 1991;99(5):440-4.
27- Witzel MF, Calheiros FC, Gonçalves F, Kawano Y, Braga RR. Influence of photoactivation method on conversion, mechanical properties, degradation in ethanol and contraction stress of resin-based materials. J Dent. 2005;33(9):773-9.
28- Wu W, Mckinney JE. Influence of chemicals on wear of dental composites. J Dent Res. 1982;61(10):1180-3.

Corresponding address:

Dr. Lawrence G. Lopes

Departamento de Prevenção e Reabilitação Oral

Faculdade de Odontologia - Universidade Federal de Goiás

Praça Universitária, s/n - Faculdade de Odontologia - Setor Universitário

74605-220 - Goiânia, GO - Brasil

Phone: +55-62-3209-6050 - Fax: +55-62-3521-1882

e-mail:

drlawrenceg@yahoo.com.br

Publication Dates

Publication in this collection
12 Jan 2009
Date of issue
Feb 2009

History

Reviewed
04 June 2008
Received
28 Apr 2008
Accepted
17 June 2008

This work is licensed under a Creative Commons Attribution 4.0 International License.

[1] 1- Aguiar FHB, Braceiro A, Lima DANL, Ambrosano GMB, Lovadino JR. Effect of light curing modes and light curing time on the microhardness of a hybrid composite resin. J Contemp Dent Pract. 2007;8(6):1-8.

[2] 2- Alomari Q, Omar R, Akpata E. Effect of LED curing modes on postoperative sensitivity after Class II resin composite restorations. J Adhes Dent. 2007;9(5):477-81.

[3] 3- Asmussen E, Peutzfeldt A. Influence of composition on rate of polymerization contraction of light-curing resin composites. Acta Odontol Scand. 2002;60(3):146-54.

[4] 4- Asmussen E, Peutzfeldt A. Influence of pulse-delay curing on softening of polymer structures. J Dent Res. 2001;80(6):1570-3.

[5] 5- Asmussen E, Peutzfeldt A. Influence of selected components on crosslink density in polymer structures. Eur J Oral Sci. 2001;109(4):282-5.

[6] 6- Asmussen E, Peutzfeldt A. Two-step curing: influence on conversion and softening of a dental polymer. Dent Mater. 2003;19(6):466-70.

[7] 7- Asmussen E. Factors affecting the quantity of remaining double bonds in restorative resin polymers. Scand J Dent Res. 1982;90(6):490-6.

[8] 8- Bouschlicher MR, Rueggeberg FA. Effect of ramped light intensity on polymerization force and conversion in a photoactivated composite. J Esthet Dent. 2000;12(1):328-39.

[9] 9- Braden M, Causton BE, Clarke RL. Diffusion of water in composite filling materials. J Dent Res. 1976;55(5):730-2.

[10] 10- Davidson CL, De Gee AJ. Light-curing units, polymerization, and clinical implications. J Adhes Dent. 2000;2(3):167-73.

[11] 11- Emami N, Soderholm KJM, Berglund LA. Effect of light power density variations on bulk curing properties of dental composites. J Dent. 2003;31(3):189-96.

[12] 12- Fabre HSC, Fabre S, Cefaly DFG, Carrilho MRO, Garcia FCP, Wang L. Water sorption and solubility of dentin bonding agents light-cured with different light sources. J Dent. 2007;35(3):253-8.

[13] 13- Ferracane JL. Elution of leachable components from composites. J Oral Rehabil. 1994;21(4):441-52.

[14] 14- Ferracane JL. Hygroscopic and hydrolytic effects in dental polymer networks. Dent Mater. 2006;22(3):211-22.

[15] ¹⁵
- International Organization for Standization. ISO 4049: dentistry – resin-based filling materials. Geneva: The Organization; 1988.

[16] 16- Ito S, Hashimoto M, Wadgaonkar B, Svizero N, Carvalho RM, Yiu C, et al. Effect of resin hydrophilicity on water sorption and changes in modulus of elasticity. Biomaterials. 2005;26(33):6449-59.

[17] 17- Kanca J, Suh BI. Pulse activation: reducing resin-based composite contraction stresses at the enamel cavosurface margins. Am J Dent. 1999;12(3):107-12.

[18] 18- Lee SY, Huang HM, Lin CY, Shih YH. Leached components from dental composites in oral simulating fluids and the resultant composite strengths. J Oral Rehabil. 1998;25(8):575-88.

[19] 19- Lim BS, Ferracane JL, Sakaguchi RL, Condon JR. Reduction of polymerization contraction stress for dental composites by two-step light-activation. Dent Mater. 2002;18(6):436-44.

[20] 20- Lopes LG, Cefaly DGF, Franco EB, Mondelli RFL, Lauris JRP, Navarro MFL. Clinical evaluation of two "packable" posterior composite resins: two-year results. Clin Oral Investig. 2003;7(3):123-8.

[21] 21- Lopes LG, Franco EB, Pereira JC, Mondelli RFL. Effect of light-curing units and activation mode on polymerization shrinkage and shrinkage stress of composite resins. J Appl Oral Sci. 2008;16(1):35-42.

[22] 22- Malacarne J, Carvalho RM, Goes MF, Svizero N, Pashley DH, Tay FR, et al. Water sorption/solubility of dental adhesive resins. Dent Mater. 2006;22(10):973-80.

[23] 23- Örtengren U, Wellendorf H, Harlosson S, Ruyter IE. Water sorption and solubility of dental composites and identification of monomers released in an aqueous environment. J Oral Rehabil. 2001;28(12):1106-15.

[24] 24- Soh MS, Yap AUJ. Influence of curing modes on crosslink density in polymer structures. J Dent. 2004;32(4):321-6.

[25] 25- Suzuki K, Ishikawa K, Sugiyama K, Furuta H, Nishimura F. Content and release of bisphenol a from polycarbonate dental products. Dent Mater J. 2000;19(4):389-95.

[26] 26- Uno S, Asmussen E. Marginal adaptation of a restorative resin polymerized at reduced rate. Scand J Dent Res. 1991;99(5):440-4.

[27] 27- Witzel MF, Calheiros FC, Gonçalves F, Kawano Y, Braga RR. Influence of photoactivation method on conversion, mechanical properties, degradation in ethanol and contraction stress of resin-based materials. J Dent. 2005;33(9):773-9.

[28] 28- Wu W, Mckinney JE. Influence of chemicals on wear of dental composites. J Dent Res. 1982;61(10):1180-3.