The aim of this study was to develop a new antimicrobial tissue conditioner containing silver nanoparticles (Ag?) and to evaluate its biological performance. Samples of tissue conditioner (Coe-soft, GC cooperation, Tokyo, Japan) containing Ag? with the concentrations of 0 (control), 0.1, 0.5, 1.0, 2.0% were fabricated as 20 x 2.0 (diameter x thickness) ㎜ in size for present experiments. In antimicrobial assay, samples were placed on separate culture plate and microbial suspensions (180 μL) of three tested strains (Staphylococcus aureus, Candida albicans and Escherichia coli) were inoculated. Microbial growth was verified at 24 hours and extended to 72 hours and the antimicrobial effects of samples were evaluated as a percentage of viable cells in withdrawn suspension (100 μL). The borderline of the antimicrobial effect was determined at 99.9 % of microbial reduction. To test the cytotoxicity of the modified tissue conditioner loaded with Ag?, the extracts from experimental samples were prepared according to concentration of Ag? (0, 0.1, 0.5, 1.0, and 2.0%) and incubated at 2, 8, 24 and 72 hours. The cytotoxic effects of the extracts to cultured human gingival fibroblast (HGF) were measured by MTT assay. Samples combined with 0.5, 1.0 and 2.0% Ag? displayed bactericidal effect against three tested strains in 24 and 72 hour incubation time without statistical difference between two incubating periods (p > 0.01). While 0, 0.1 and 0.5% Ag? showed no cytotoxic effect at all of incubating times, significantly high cytotoxic effect (less than 25% cell viability) was revealed at 2.0% Ag? in 24 and 72 hours respectively (p < 0.01) and significantly moderate cytotoxic effect (between 25-50% cell viability) was observed at 1.0% Ag? in 24 and 72 hours respectively and 2.0% at 8 hours (p < 0.01). Within the limitation of this study in vitro, the results suggest that 0.5% Ag? loaded tissue conditioner could be a possible candidate for a novel antimicrobial tissue conditioner with uncompromised cytotoxicity.

1 이철재, "은나노 입자가 침착된활성탄의 항균특성에 관한 연구" 18 (18): 396-399, 2007

2 윤제용, "은 이온과의 비교를 통한 나노 은 입자의 항균 특성 연구(050607-050720)" 대한환경공학회 27 (27): 771-776, 2005

3 Chang DS, "The inhibiting effect of tissue conditioners combined with antifungal agents on the growth of Candida albicans" 23 : 268-280, 1985

4 Thomas CJ, "The in vitro fungicidal properties of Visco-gel, alone and combined with nystatin and amphotericin B" 5 : 167-172, 1978

5 Bruns W, "Suppression of intrinsic resistance to penicillins in Staphylococcus aureus, by polidocanol, a dodecyl polyethyleneoxid ether" 27 : 632-639, 1985

6 Ramage G, "Standardized method for in vitro antifungalsusceptibility testing of Candida albicans biofilms" 45 : 2475-2479, 2001

7 Kim TH, "Size dependent cellular toxicity of silver nanoparticles" 100 : 1033-1043, 2012

8 Sondi I, "Silver nanoparticles as antimicrobial agent: a case study on E. coli as a model for gram-negative bacteria" 275 : 177-182, 2004

9 Welker WA, "Prosthodontic treatment of abused oral tissue" 37 : 259-, 1977

10 Matsuura T, "Prolonged antimicrobial effect of tissue conditioners containing silver- zeolite" 25 : 373-377, 1997

11 Ivask A, "Profiling of the reactive oxygene species-realated ecotoxicity of CuO, ZnO, TiO2, silverand fullerene nanoparticles using a set ofrecombinant luminescent Escherichia coli strains:differentiating the impact of particles and solubilizedmetals" 398 : 701-716, 2010

12 Samuel U, "Prevention of catheter-related infections: The potential of a new nano-silver impregnated catheter" 23 : 75-78, 2004

13 Petering HG, "Pharmacology and toxicology of heavy metals: silver" 1 : 127-130, 1976

14 Petering HG, "Pharmacology and toxicology of heavy metals: silver" 1 : 127-130, 1976

15 Douglas WH, "Nystatin in denture liners-An alternative treatment of denture stomatitis" 135 : 55-59, 1973

16 Lubick N, "Nanosilver toxicity: ions, nanoparticles or both?" 42 : 8617-, 2008

17 Bouillaguet S, "Long-term cytotoxicity of resin-based dental restorative materials" 29 : 7-13, 2002

18 Okita N, "In vivo and in vitro studies on soft denture materials: microbial adhesion and tests for antibacterial activity" 7 : 155-160, 1991

19 Ciapetti G, "In vitro evaluation of cell/biomaterial interaction by MTT assay" 14 : 359-364, 1993

20 Braydich-Stolle L, "In vitro cytotoxicity of nanoparticles in mammalian germ line stem cells" 88 : 412-, 2005

21 Dahl JE, "In vitro biocompatibility of denture relining materials" 23 : 17-22, 2006

22 Pesci-Bardon C, "In vitro antiseptic properties of an ammoniumcompound combined with denture baseacrylic resin" 23 : 111-116, 2006

23 Singh N, "In situ synthesis of silver nano-particles in polymethylmethacrylate" 104 : 367-372, 2007

24 Ozdemir KG, "In Vitro Evaluation of Cytotoxicity of Soft Lining Materials on L929 Cells by MTT Assay" 90 : 82-86, 2009

25 ISO, "ISO 10993-1:1992"

26 Gruber RG, "Fungus growth on tissue conditioners and soft denture liners" 73 : 641-643, 1966

27 Rungby J, "Effects of selenium on toxicity and ultrastructural localization of silver in cultured macrophages" 61 : 40-45, 1987

28 Olsen I, "Denture stomatitis : Effects of chlorhexidine and amphotericin B on the mycotic flora" 33 : 41-46, 1975

29 Gristina AG, "Comparative in vitro antibiotic resistance of surface-colonizing coagulase-negativestaphylococci" 33 : 813-816, 1989

30 Haase A, "Arch Toxicol A novel type of silver nanoparticles and their advantages in toxicity testing in cell culture systems Mar 29" 2012

31 Russell AD, "Antimicrobial activity and action of silver" 31 : 351-370, 1994

32 Nikawa H, "Antifungal effect of zeolite-incorporated tissues conditioner against Candida albicans growth and/or acid production" 24 : 350-357, 1997

33 Imazato S, "Antibacterial activity of bactericide- immobilized filler for resin-based restoratives" 24 : 3605-3609, 2003