Braz Oral Res. 2010 Jul-Sep;24(3):303-8 303 Maxillofacial Prosthesis Marcelo Coelho Goiato(a) Marcela Filié Haddad(b) Daniela Micheline dos Santos(a) Aldiéris Alves Pesqueira(b) Amália Moreno(b) (a) Associate Professor; (b) Graduate Student – Department of Dental Materials and Prosthodontics, Araçatuba Dental School, São Paulo State University (UNESP), Araçatuba, São Paulo, Brazil. Maxillofacial Prosthesis Corresponding author: Marcelo Coelho Goiato Faculdade de Odontologia de Araçatuba – UNESP Departamento de Materiais Odontológicos e Prótese Rua José Bonifácio, 1193, Vila Mendonça Araçatuba - SP - Brazil E-mail: goiato@foa.unesp.br Received for publication on Apr 29, 2010 Accepted for publication on Jun 06, 2010 Hardness evaluation of prosthetic silicones containing opacifiers following chemical disinfection and accelerated aging Abstract: We evaluated the effects of disinfection and aging on the hard- ness of silicones containing opacifiers and intended for use in facial pros- thetics. A total of 90 samples were produced using a cylindrical metal mold 3 mm in height and 30 mm in diameter. The samples were fabricat- ed from Silastic MDX 4-4210 silicone in three groups: GI contained no opacifier, GII contained barium sulfate (Ba), and GIII contained titanium dioxide (Ti). The samples were disinfected using effervescent tablets (Ef), neutral soap (Ns), or 4% chlorhexidine (Cl) 3 times a week for 60 days. After this period the samples underwent 1,008 hours of accelerated ag- ing. The hardness was measured using a durometer immediately follow- ing the disinfection period and after 252, 504, and 1,008 hours of aging. The data were statistically analyzed using 3-way ANOVA and the Tukey test (p < .05). The GIII group exhibited the greatest variation in hardness regardless of elapsed time. All groups displayed greater hardness after 1,008 hours of accelerated aging independent of disinfectant type. All of the hardness values were within the clinically acceptable range. Descriptors: Maxillofacial prosthesis; Disinfection; Hardness. Introduction Deformities in the maxillofacial area can cause embarrassment for patients.1 Plastic surgery is the first choice of treatment, but when surgery is inadvisable due to unfavorable conditions, rehabilitation with maxil- lofacial prostheses provides a means of improving patient aesthetics and self-esteem and facilitating their return to society.1,2 Silicone is the most common material used to fabricate maxillofacial prostheses because of its texture, strength, durability, ease in handling and coloring, and patient comfort.2,3 However, silicone suffers from a rapid deterioration of physical properties and color instability and is dif- ficult to repair, limiting its use in maxillofacial prostheses. After a few months of insertion, the prosthesis becomes unpleasant,4-6 and microor- ganisms colonizing the silicone7,8 may promote infection of surrounding tissues.1,2 A recent method of silicone pigmentation involves adding opacifi- ers to the base material.9-10 This method reduces color instability11-13 by blocking ultraviolet rays.9-10 However, changes to the physical properties Hardness evaluation of prosthetic silicones containing opacifiers following chemical disinfection and accelerated aging Braz Oral Res. 2010 Jul-Sep;24(3):303-8304 (such as hardness) resulting from addition of these materials have not been investigated. We examined the effects of barium sulfate and titanium dioxide opacifiers on the hardness of Silastic MDX4-4210 following chemical disinfection and accelerated ag- ing. Our hypothesis was that the opacifiers did not affect the physical properties of the silicone. Material and Methods The samples were fabricated by filling 30 mm di- ameter x 3 mm thick cylindrical metal molds6 with Silastic MDX4-4210 (Dow Corning Corporation, Midland, MI, USA). Barium sulfate (Wako, Osa- ka, Osaka, Japan) or titanium dioxide (Homeofar, Catanduva, SP, Brazil) were added to some of the samples as opacifiers. A total of 90 samples were fabricated in three groups (n = 30): the GI group contained no opacifier, the GII group was pigment- ed with 0.2 wt% barium sulfate (Ba), and the GIII group was pigmented with 0.2 wt% titanium diox- ide (Ti). Both the pigments and the silicones were weighed using a precision digital scale (BEL Equi- pamentos Analítico, Piracicaba, SP, Brazil).4,14,15 The silicone was mixed according to the manufacturer’s instructions. The opacifiers were mixed with the silicone and the mixture was placed in the mold. Excess material was removed to maintain a uniform thickness. The samples were cured in the molds for 3 days with the external surface left exposed.2,6,14,16 After curing, an initial Shore A hardness test was performed on all samples using a digital durometer (Teclock, Osaka, Osaka, Japan) according to ASTM procedures.17 The potency of the measurement was established between 0 and 100 Shore A, with ± 1% of tolerance. The sample loading was 12.5 N for 10 seconds. Shore A hardness is a measure of material texture and flexibility and should be between 25 and 35 units for maxillofacial prosthetic materials.2,18-19 The samples were disinfected 3 times a week for 60 days.6,16,20-21 Within each group, 10 samples were disinfected with Efferdent (Ef - Pfizer Consumer Health, Morris Plains, NJ, USA),6,20 10 with neutral pH soap (Ns - Johnson & Johnson, São José dos Campos, SP, Brazil),6,20 and ten with 4% gluconate chlorhexidine (Cl - Naturativa, Araçatuba, SP, Bra- zil).2,21,22 After disinfection, the samples were again tested for hardness. Accelerated aging tests were carried out using an aging chamber (Equilam, Diadema, SP, Brazil).6 The samples were subjected to alternating periods of exposure to ultraviolet light and distilled water.4,14 Hardness tests were repeated after 252, 504, and 1,008 hours of aging.8 The hardness values were analyzed using 3-way ANOVA and the means were compared using the Tukey test (p < .05). Results The mean hardness values are presented in Ta- bles 1 and 2 and Graphs 1-3. The opacifier, disinfection, and aging treatments were statistically significant with respect to hard- ness (p < .05). The GI and GII groups increased in hardness throughout the experiment. On the other Source df SS MS F P Disinfectant 2 9.204 4.602 3.870 .025* Opacifier 2 129.391 64.696 54.406 < .0001* Disinf X Opac 4 17.582 4.396 3.696 .008* Between subjects 81 96.320 1.189 Aging 4 900.476 225.119 442.911 < .0001* Aging X Disinf 8 56.484 7.061 13.891 < .0001* Aging X Opac 8 320.831 40.104 78.902 < .0001* Aging X Disinf X Opac 16 69.929 4.371 8.599 < .0001* Within subjects 324 164.680 0.508 *p < .05 denotes statistically significant difference. df: degrees of freedom, SS: sum of squares, MS: mean square. Table 1 - ANOVA results for hardness tests. Goiato MC, Haddad MF, Santos DM, Pesqueira AA, Moreno A Braz Oral Res. 2010 Jul-Sep;24(3):303-8 305 hand, GIII exhibited a significant decrease in hard- ness following disinfection and after 252 hours of accelerated aging (Graphs 1-3), except for samples disinfected with chlorhexidine. After 1,008 hours of aging, the hardness of the GIII samples increased in- dependent of the disinfectant used (Graphs 1-3). After 60 days of Ef disinfection, the GII and GIII samples exhibited lower hardness values than the GI group (Table 2). The hardness values of the GIII samples were lower than the GI and GII sam- ples after 252 and 504 hours of aging regardless of disinfection procedure (Table 2). However, the GIII samples had the highest hardness after 1,008 hours (Table 2). Chemical disinfection and accelerated aging did not statistically influence the mean hardness of the GI group, but when an opacifier was added both dis- infection and accelerated aging produced significant changes in hardness (Table 2). Discussion All values obtained in the present study were within the acceptable range described in the litera- ture (25-35 units)2,6,18,23 regardless of opacifier ad- dition, disinfection, or aging (table 2). However, the hypothesis of the present study was rejected because when an opacifier was added both disinfection and accelerated aging produced significant changes in silicone hardness (Table 2). In the present study, an increase in hardness was observed in the GI and GII groups both after dis- infection and accelerated aging. The increases were only statistically significant after disinfection with neutral soup and accelerated aging (Graphs 1-3 and table 2), and could be the result of ongoing silicone polymerization with volatilization of formalde- hyde,24 which occurs during the aging process. The cross-linking system used in this material produces high temperatures, increasing the conversion rate, cross-linking density, and molecular weight of the silicone polymer6,25 to improve the hardness of the material. It is likely that Ba does not alter the silicone ma- trix since the behavior exhibited by Ba-containing samples was similar to the unmodified samples. In addition, Ba particles are capable of strongly asso- ciating with silicone chains even after disinfection. If the barium sulfate particles were removed during Period Disinfec Groups GI GII GIII Initial Ef 28.7 (0.82) ABa 28.6 (0.52) ABCa 29.6 (0.7) ABCa Ns 28.2 (0.79) Aa 28.2 (0.79) Aa 29.3 (0.48) ABCa Cl 29 (0.47) ABCa 28.5 (0.53) Aa 29.2 (0.63) ABa 60 days Ef 29.8 (0.42) BCDa 28.7 (0.7) Aa 28.7 (0.48) ADa Ns 30.4 (0.52) CDEFa 30.7 (1.16) CDEa 28.7 (0.95) ADb Cl 30.1 (0.57) BCDEa 29.1 (0.57) ABa 27.6 (0.52) CDEb 252 hours Ef 30.3 (0.95) CDEFa 29.3 (1.16) ABa 27.4 (0.52) DEb Ns 30.7 (0.95) DEFa 31.3 (1.06) DEFGa 27.5 (0.71) DEb Cl 30.4 (1.17) CDEFa 30.6 (0.97) CDEa 30.3 (0.7) Ba 504 hours Ef 30.9 (0.88) EFGa 30.2 (0.92) BCDa 27.4 (0.7) DEb Ns 31.7 (0.95) FGHIa 31.7 (1.16) EFGa 27 (0.47) Eb Cl 31.5 (1.08) EFGHa 30.8 (1.03) CDEFa 27.6 (0.95) DEb 1,008 hours Ef 33 (0.82) Ia 32.7 (0.82) Ga 33.1 (0.74) Fa Ns 32.4 (0.84) HIa 32.4 (0.7) Ga 33.5 (0.71) Fa Cl 32.2 (0.92) GHIa 32.7 (0.67) Ga 34 (0.67) Fa Means followed by the same capital letter in column and same lowercase letter in line exhibit no statistical dif- ference (p < 0.05) by Tukey test. Ef: Efferdent, Ns: neutral pH soap, Cl: chlorhexidine. Table 2 - Mean hardness values (SD) for Silastic silicones between chemical disinfectant groups. Hardness evaluation of prosthetic silicones containing opacifiers following chemical disinfection and accelerated aging Braz Oral Res. 2010 Jul-Sep;24(3):303-8306 disinfection, an increase in porosity and reduced hardness would be expected.6 The GIII group displayed a decrease in hardness after 252 hours of accelerated aging, except for sam- ples disinfected with chlorhexidine, and a significant increase in hardness after 1008 hours, regardless of the disinfection procedure. After 60 days of disinfection with Ef, the GII and GIII groups exhibited lower hardness values than the GI group (Graph 1, table 2). The hardness values of the GIII samples were also lower than the GI and GII groups after 252 and 504 hours of ac- celerated aging independent of the disinfection pro- cedure (Graphs 1-3, Table 2). Both the high hardness values in the initial pe- riod and the low hardness values after disinfection and accelerated aging (252 and 504 hours) are prob- ably due to continuous polymerization of the sili- cone.4,6,19 The polymerization process can be slowed by reaction between the disinfection products and the titanium dioxide opacifier. If the titanium dioxide particles are smaller than the barium sulfate parti- cles, a portion of the titanium opacifier could have been removed during disinfection, resulting in more porous and softer samples.6,19 One reason for the significantly lower hardness value observed in the GIII group after chlorhexidine treatment (Graph 3, Table 2) is absorption of the disinfection solution. The samples were immersed in Cl during the disinfection procedure, so a porous structure may have been formed. Mancuso et al.19 stated that additives to silicone materials may pro- mote water absorption and lead to reduced hard- ness. After 1,008 hours of accelerated aging, the hard- ness values of the GIII group were higher than those of the other groups (Table 2), suggesting that at the Graph 1 - Mean hardness values of Silastic disinfected with Efferdent. Sh or e A H ar dn es s Initial 28 29.6 29.8 27.4 27.4 30.3 29.3 30.9 30.2 33.1 33 30 32 34 Time 60 days 252 h 504 h 1,008 h Hardness GIII Hardness GII Hardness GI 28.6 28.7 32.7 Graph 2 - Mean hardness values of Silastic disinfected with neutral soap. Sh or e A H ar dn es s Initial 28 30.7 27.5 27 31.7 33.5 30 32 34 Time 60 days 252 h 504 h 1,008 h Hardness GIII Hardness GII Hardness GI 28.2 28.7 32.4 30.429.3 31.3 30.7 Graph 3 - Mean hardness values of Silastic disinfected with chlorhexidine. Sh or e A H ar dn es s Initial 28 30.1 30.3 27.6 30.8 27.6 30 32 34 Time 60 days 252 h 504 h 1,008 h Hardness GIII Hardness GII Hardness GI 28.5 32.2 32.7 29.1 29 29.2 30.6 30.4 31.5 34 Goiato MC, Haddad MF, Santos DM, Pesqueira AA, Moreno A Braz Oral Res. 2010 Jul-Sep;24(3):303-8 307 end of the aging period the material reached a high- er degree of polymerization for all samples.6,19 Although hygiene is important in maxillofacial prostheses, there is no universally effective method for performing this maintenance. Brushing is not advisable because repeated washing may dissolve and remove some surface pigments. Rinsing with tap water is ineffective against calculus buildup and stains.6 Chemical soaking is the primary method of choice to disinfect maxillofacial elastomers. Patients are advised not to clean the prosthesis using solvents, such as isopropyl alcohol since this could cause dis- solution of the pigments. The methods used in the present study included Efferdent tablets that employ saturation and oxidation using peroxides, neutral soap that acts through digital friction and is chemi- cally inert,6 and 4% chlorhexidine, also chemically inert and acting through saturation.22 None of the disinfectants used in the present study statistically affected the hardness value of the MDX4-4210 silicone, but when an opacifier was added, both the disinfection method and the aging process produced statistically significant changes in the material hardness. Only the GII samples disin- fected with neutral soap experienced a significant increase in hardness. This result reinforces our pre- vious supposition that the opacifier forms a strong link with the silicone chains, and this association is not broken even with digital friction during the dis- infection procedure.6 The lower hardness values ob- served in the GII and GIII groups disinfected with Cl (Table 2) can be explained by the disinfection method (immersion). According to the literature, long-term storage of silicone materials can promote water absorption, and the degree of absorption is dependent on the filler material (opacifiers) and the low level of adhesion between silicone polymers.26 This trend was not observed in the GII and GIII samples disinfected with Ef (Table 2), which also acts by immersion. Prostheses disinfected with Ef have a tendency to change color because of the al- kaline peroxides in the Ef tablets, which oxidize organic materials when released in solution. This tends to make the silicone more porous and conse- quently reduces the hardness.20 Since the opacifiers used in this study were inorganic, the oxygen discol- oration did not occur and the initial hardness was maintained. According to the results of the present study, hardness values did not significantly differ with re- gard to disinfection process (Table 2), and all hard- ness values were within the acceptable clinical range (25 to 35 units).2,6,18-19 The samples were subjected to 1,008 hours of accelerated aging, equivalent to 1 year of clinical use.14 Conclusion Within the limitations of this in vitro study, it can be concluded that the use of opacifiers and dis- infection procedures in Silastic silicone prostheses is acceptable. References 1. Goiato MC, Pesqueira AA, Ramos da Silva C, Gennari-Filho H, Micheline dos Santos D. Patient satisfaction with maxil- lofacial prosthesis: literature review. J Plast Reconstr Aesthet Surg. 2009 Feb;62(2):175-80. 2. Guiotti AM, Goiato MC, dos Santos DM. Evaluation of the Shore A hardness a silicone for facial prosthesis as to the effect of storage period and chemical disinfection. J Craniofac Surg. 2010 Mar;21(2):323-7. 3. Dootz ER, Koran A 3rd, Craig RG. Physical properties of three maxillofacial materials as a function of accelerated aging. J Prosthet Dent. 1994 Apr;71(4):379-83. 4. Mancuso DN, Goiato MC, Santos DM. Color stability after accelerated aging of two silicones, pigmented or not, for use in facial prostheses. Braz Oral Res. 2009 Apr-Jun;23(2):144- 8. 5. Aziz T, Waters M, Jagger R. Development of a new poly(dimethylsiloxane) maxillofacial prosthetic material. J Biomed Mater Res B Appl Biomater. 2003 May;65(2):252- 61. 6. Goiato MC, Pesqueira AA, dos Santos DM, Dekon SF. Evalu- ation of hardness and surface roughness of two maxillofacial silicones following disinfection. Braz Oral Res. 2009 Jan- Mar;23(1):49-53. 7. Nikawa H, Jin C, Hamada T, Makihira S, Polyzois G. Candida albicans growth on thermal cycled materials for maxillofacial prosthesis in vitro. J Oral Rehabil. 2001 Aug;28(8):755-65. Hardness evaluation of prosthetic silicones containing opacifiers following chemical disinfection and accelerated aging Braz Oral Res. 2010 Jul-Sep;24(3):303-8308 8. Taylor RL, Liauw CM, Maryan C. The effect of resin/cross- linker ratio on the mechanical properties and fungal deteriora- tion of a maxillofacial silicone elastomer. J Mater Sci Mater Med. 2003 Jun;14(6):497-502. 9. Gasparro FP, Mitchnick M, Nash JF. A review of sunscreen safety an efficacy. Photochem Photobiol. 1998;68(3):243- 56. 10. Lowe NJ, Shaath MA, Pathak MA. Sunscreen development, evaluation and regulatory aspects, New York: Marcel Dekker; 1997 11. Kiat-amnuay S, Beerbower M, Powers J, Paravina RD. Influ- ence of pigments and opacifiers on color stability of silicone maxillofacial elastomer. J Dent. 2009;37 Supplç 1:e45-50. 12. Santos DM, Goiato MC, Moreno A, Pesqueira AA, Haddad MF. Influence of pigments and opacifiers on color stability of a facial silicone submitted to accelerated aging. J Prosthodont. 2010 (In press). 13. Kiat-Amnuay S, Mekayarajjananonth T, Powers JM, Cham- bers MS, Lemon JC. Interactions of pigments and opacifiers on color stability of MDX4-4210/type A maxillofacial elas- tomers subjected to artificial aging. J Prosthet Dent. 2006 Mar;95(3):249-57. 14. Mancuso DN, Goiato MC, Dekon SFC, Gennari-Filho H. Visual evaluation of color stability after accelerated aging of pigmented and nonpigmented silicones to be used in facial prostheses. Indian J Dent Res. 2009 Jan-Mar;20(1):77-80. 15. Yu R, Koran 3rd, Craig RG. Physical properties of a pigmented silicone maxillofacial material as a function of accelerated aging. J Dent Res. 1980 Jul; 59(7):1141-8. 16. Goiato MC, Pesqueira AA, dos Santos DM, Falcón-Antenucci RM, Ribeiro PP. Evaluation of dimensional change and detail reproduction in silicones for facial prostheses. Acta Odontol Latinoam. 2008; 21(1):85-8. 17. American Society for Testing and Materials. Annual book of ASTM standards. Philadelphia: American Society for Testing and Materials; 1988. Designation D 2240-81: standard test method for rubber properties – Durometer hardness; 332- 35. 18. Lewis DH, Castleberry DJ. An assessment of recent advanc- es in external maxillofacial materials. J Prosthet Dent.1980 Apr;43(4):426-32. 19. Mancuso DN, Goiato MC, Zuccolotti BC, Moreno A, dos San- tos DM. Evaluation of hardness and color change of soft liners after accelerated ageing. Prim Dent Care. 2009 Jul;16(3):127- 30. 20. Goiato MC, Pesqueira AA, dos Santos DM, Zavanelli AC, Ri- beiro PP. Color stability comparison of silicone facial prosthe- ses following disinfection. J Prosthodont. 2009 Apr;18(3):242- 4. 21. Goiato MC, Santos DM, Gennari Filho H, Zavanelli AC, Dekon SFC, Mancuso DN. Influence of investment, disin- fection, and storage on the microhardness of ocular resins. J Prosthodont. 2009 Jan;18(1):32–5. 22. Pavarina AC, Pizzolitto AZ, Machado AL, Vergani CE, Gi- ampaolo ET. An infection control protocol: effectiveness of immersion solutions to reduce the microbial growth on dental prostheses. J Oral Rehabil. 2003 May;30(5):532-6. 23. May PD. Maxillofacial prostheses of chlorinated polyethylene. J Biomed Mater Res.1978 May;12(3):421-31. 24. Anusavice K J. Phillips’ Science of Dental Materials. 11th ed. St Louis: Elsevier; 2003, 832 p. 25. Aziz T, Watersa M, Jagger R. Analysis of the properties of silicone rubber maxillofacial prosthetic materials. J Dent. 2003 Jan;31(1):67-74. 26. Qudah S, Hugget R, Harisan A. The effect of thermocycling on the hardness of soft lining materials. Quintessence Int. 1991 Jul;22(7):575-80.