Fernando Luis Esteban Florez1, Rochelle Denise Hiers2, Preston Larson3, Matthew Johnson4, Edgar O'Rear5, Adam J Rondinone6, Sharukh Soli Khajotia7. 1. The University of Oklahoma Health Sciences Center, Department of Restorative Sciences, Division of Dental Biomaterials College of Dentistry, 1201 North Stonewall Avenue, Room 146, Oklahoma City, OK 73117, USA. Electronic address: fernando-esteban-florez@ouhsc.edu. 2. The University of Oklahoma Health Sciences Center, Department of Restorative Sciences, Division of Dental Biomaterials College of Dentistry, 1201 North Stonewall Avenue, Room 146, Oklahoma City, OK 73117, USA. Electronic address: shelley-hiers@ouhsc.edu. 3. The University of Oklahoma, Samuel Roberts Noble Microscopy Laboratory, 770 Van Vleet Oval, Norman, OK 73019, USA. Electronic address: plarson@ou.edu. 4. The University of Oklahoma, Department of Physics and Astronomy, 440 West Brooks Street, Room 129, Norman, OK 73019, USA. 5. The University of Oklahoma, School of Chemical, Biological and Materials Engineering, 100 East Boyd, T-301, Sarkeys Energy Center, Norman, OK 73019, USA. Electronic address: eorear@ou.edu. 6. Oak Ridge National Laboratory, Center for Nanophase Materials Sciences, Oak Ridge, TN 37831, USA. Electronic address: rondinoneaj@ornl.gov. 7. The University of Oklahoma Health Sciences Center, Department of Restorative Sciences, Division of Dental Biomaterials College of Dentistry, 1201 North Stonewall Avenue, Room 146, Oklahoma City, OK 73117, USA. Electronic address: sharukh-khajotia@ouhsc.edu.
Abstract
The development of dental adhesive resins with long-lasting antibacterial properties is a possible solution to overcome the problem of secondary caries in modern adhesive dentistry. OBJECTIVES: (i) Synthesis and characterization of nitrogen-doped titanium dioxide nanoparticles (N_TiO2), (ii) topographical, compositional and wettability characterization of thin-films (unaltered and experimental) and, (iii) antibacterial efficacy of N_TiO2-containing dental adhesives against Streptococcus mutans biofilms. MATERIALS AND METHODS: Nanoparticles were synthesized and characterized using different techniques. Specimens (diameter = 12 mm, thickness ≅ 15 μm) of OptiBond Solo Plus (Kerr Corp., USA) and experimental adhesives [50, 67 and 80% (v/v)] were fabricated, photopolymerized (1000 mW/cm2, 1 min) and UV-sterilized (254 nm, 800,000 μJ/cm2) for microscopy, spectroscopy, wettability and antibacterial testing. Wettability was assessed with a contact angle goniometer by dispensing water droplets (2 μL) onto four random locations of each specimen (16 drops/group). Drop profiles were recorded (1 min, 25 frames/s, 37 °C) and contact angles were calculated at time = 0 s (θINITIAL) and time = 59 s (θFINAL). Antibacterial testing was performed by growing S. mutans (UA159-ldh, JM10) biofilms for either 3 or 24 h (anaerobic conditions, 37 °C) with or without continuous light irradiation (410 ± 10 nm, 3 h = 38.75 J/cm2, 24 h = 310.07 J/cm2) against the surfaces of sterile specimens. RESULTS: N_TiO2 was successfully prepared using solvothermal methods. Doped-nanoparticles displayed higher light absorption levels when compared to undoped titania. Experimental adhesives demonstrated superior antibacterial efficacy in dark conditions. CONCLUSIONS: The findings presented herein suggest that N_TiO2 is a feasible antibacterial agent against cariogenic biofilms.
The development of dental adhesive resins with long-lasting antibacterial properties is a possible solution to overcome the problem of secondary caries in modern adhesive dentistry. OBJECTIVES: (i) Synthesis and characterization of nitrogen-doped titanium dioxide nanoparticles (N_TiO2), (ii) topographical, compositional and wettability characterization of thin-films (unaltered and experimental) and, (iii) antibacterial efficacy of N_TiO2-containing dental adhesives against Streptococcus mutans biofilms. MATERIALS AND METHODS: Nanoparticles were synthesized and characterized using different techniques. Specimens (diameter = 12 mm, thickness ≅ 15 μm) of OptiBond Solo Plus (Kerr Corp., USA) and experimental adhesives [50, 67 and 80% (v/v)] were fabricated, photopolymerized (1000 mW/cm2, 1 min) and UV-sterilized (254 nm, 800,000 μJ/cm2) for microscopy, spectroscopy, wettability and antibacterial testing. Wettability was assessed with a contact angle goniometer by dispensing waterdroplets (2 μL) onto four random locations of each specimen (16 drops/group). Drop profiles were recorded (1 min, 25 frames/s, 37 °C) and contact angles were calculated at time = 0 s (θINITIAL) and time = 59 s (θFINAL). Antibacterial testing was performed by growing S. mutans (UA159-ldh, JM10) biofilms for either 3 or 24 h (anaerobic conditions, 37 °C) with or without continuous light irradiation (410 ± 10 nm, 3 h = 38.75 J/cm2, 24 h = 310.07 J/cm2) against the surfaces of sterile specimens. RESULTS:N_TiO2 was successfully prepared using solvothermal methods. Doped-nanoparticles displayed higher light absorption levels when compared to undoped titania. Experimental adhesives demonstrated superior antibacterial efficacy in dark conditions. CONCLUSIONS: The findings presented herein suggest that N_TiO2 is a feasible antibacterial agent against cariogenic biofilms.
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