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Lasers in Medical Science
Published in: Lasers in Medical Science 6/2017

01-08-2017 | Original Article

Evaluation of irradiation effects of near-infrared free-electron-laser of silver alloy for dental application

Authors: Takao Kuwada-Kusunose, Alisa Kusunose, Masanobu Wakami, Chikako Takebayashi, Haruhiko Goto, Masahiro Aida, Takeshi Sakai, Keisuke Nakao, Kyoko Nogami, Manabu Inagaki, Ken Hayakawa, Kunihiro Suzuki, Toshiro Sakae

Published in: Lasers in Medical Science | Issue 6/2017

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Abstract

In the application of lasers in dentistry, there is a delicate balance between the benefits gained from laser treatment and the heat-related damage arising from laser irradiation. Hence, it is necessary to understand the different processes associated with the irradiation of lasers on dental materials. To obtain insight for the development of a safe and general-purpose laser for dentistry, the present study examines the physical effects associated with the irradiation of a near-infrared free-electron laser (FEL) on the surface of a commonly used silver dental alloy. The irradiation experiments using a 2900-nm FEL confirmed the formation of a pit in the dental alloy. The pit was formed with one macro-pulse of FEL irradiation, therefore, suggesting the possibility of efficient material processing with an FEL. Additionally, there was only a slight increase in the silver alloy temperature (less than 0.9 °C) despite the long duration of FEL irradiation, thus inferring that fixed prostheses in the oral cavity can be processed by FEL without thermal damage to the surrounding tissue. These results indicate that dental hard tissues and dental materials in the oral cavity can be safely and efficiently processed by the irradiation of a laser, which has the high repetition rate of a femtosecond laser pulse with a wavelength around 2900 nm.
Literature
1.
Stern RH, Sognnaes RF (1964) Laser beam effect on dental hard tissue. J Dent Res 43:873
2.
Sharma N, Williams C, Angadi P, Jethlia H (2013) Application of lasers in dentistry. Res Rev J Dent Sci 1:22–25
3.
Siniaeva ML, Siniavsky MN, Pashinin VP, Mamedov AA, Konov VI, Kononenko VV (2009) Laser ablation of dental materials using a microsecond Nd: YAG laser. Laser Phys 19:1056–1060CrossRef
4.
sadat Madani A, Astaneh PA, Shahabi S, Nakhaei MR, Bagheri HG, Chiniforush N (2013) Influence of different power outputs of intraoral Nd:YAG laser on shear bond strength of a resin cement to nickel-chromium dental alloy. Lasers Med Sci 28:229–234CrossRef
5.
Shibuya I, Nishiyama N, Hayakawa T, Koishi I, Nemoto K (2004) Intraoral laser welding—part 1. Effect of laser irradiation on temperature rise. J J Dent Mater 23:495–500 (in Japanese)
6.
Fornaini C, Merigo E, Cernavin I, Lòpez de Castro G, Vescovi P (2012, 2012) Intraoral laser welding (ILW) in implant prosthetic dentistry: case report. Case Rep Dent:939141. doi:10.​1155/​2012/​839141
7.
Ichikawa T, Hayasaki Y, Fujita K, Nagao K, Murata M, Kawano T, Chen J (2006) Femtosecond pulse laser-oriented recording on dental prostheses: a trial introduction. Dent Mater J 25:733–736CrossRefPubMed
8.
Naito Y, Meinar AN, Iwawaki Y, Kashiwabara T, Goto T, Ito T, Sakuma T, Ichikawa T (2013) Recording of individual identification information on dental prostheses using fluorescent material and ultraviolet light. Int J Prosthodont 26:172–174CrossRefPubMed
9.
Zach L, Cohen G (1965) Pulp response to externally applied heat. Oral Surg Oral Med Oral Pathol 19:515–530CrossRefPubMed
10.
Eriksson AR, Albrektsson T (1983) Temperature threshold levels for heat-induced bone tissue injury: a vital-microscopic study in the rabbit. J Prosthet Dent 50:101–107CrossRefPubMed
11.
Eriksson RA, Albrektsson T (1984) The effect of heat on bone regeneration: an experimental study in the rabbit using the bone growth chamber. J Oral Maxillofac Surg 42:705–711CrossRefPubMed
12.
Armengol V, Jean A, Marion D (2000) Temperature rise during Er: YAG and Nd: YAP laser ablation of dentin. J Endodontics 26:138–141CrossRef
13.
Hirota F, Furumoto K (2003) Temperature rise caused by laser (CO 2, Nd: YAG, Er: YAG) irradiation of teeth. Int Congr Ser 1248:301–304CrossRef
14.
Colucci V, do Amaral FL, Pécora JD, Palma-Dibb RG, Corona SA (2009) Water flow on erbium:yttrium-aluminum-garnet laser irradiation: effects on dental tissues. Lasers Med Sci 24:811–818CrossRefPubMed
15.
Geminiani A, Caton JG, Romanos GE (2011) Temperature increase during CO2 and Er:YAG irradiation on implant surfaces. Implant Dent 20:379–382PubMed
16.
Leja C, Geminiani A, Caton J, Romanos GE (2013) Thermodynamic effects of laser irradiation of implants placed in bone: an in vitro study. Lasers Med Sci 28:1435–1440CrossRefPubMed
17.
Ji L, Li L, Devlin H, Liu Z, Jiao J, Whitehead D (2012) Ti: sapphire femtosecond laser ablation of dental enamel, dentine, and cementum. Lasers Med Sci 24:197–204CrossRef
18.
Chichkov BN, Momma C, Nolte S, von Alvensleben F, Tünnermann A (1996) Femtosecond, picosecond and nanosecond laser ablation of solids. Appl Phys A Mater Sci Process 63:109–115CrossRef
19.
Leitz KH, Redlingshöfer B, Reg Y, Otto A, Schmidt M (2011) Metal ablation with short and ultrashort laser pulses. Phys Procedia 12:230–238CrossRef
20.
Nishimura A, Yamaushi T, Minehara E (2004) Demonstration of material processing using JAERI-FEL. In: Minehara EJ, Hajima R, Sawamura M (eds) Free electron lasers 2003. Elsevier, Amsterdam, pp II57–II58CrossRef
21.
Junbiao Z, Yonggui L, Nianqing L, Guoqing Z, Minkai W, Gan W, Xuepin Y, Yuying H, Wei H, Yanmei D, Xuejun G (2001) Primary experimental studies on mid-infrared FEL irradiation on dental substances at BFEL. Nuclear Instr Meth A 475:630–634CrossRef
22.
Spector N, Reinisch L, Spector J, Ellis DL (2002) Free-electron laser and heat-conducting templates: a study of reducing cutaneous lateral thermal damage. Lasers Surg Med 30:117–122CrossRefPubMed
23.
Tanaka T, Hayakawa K, Hayakawa Y, Mori A, Nogami K, Sato I, Yokoyama K (2004) Tunability and power characteristics of the LEBRA infrared FEL. Proc 2004 FEL Conf: 247–250
24.
Nakao K, Hayakawa K, Hayakawa Y, Inagaki M, Nogami K, Sakai T, Tanaka T (2012) Pulse structure measurement of near-infrared FEL in burst-mode operation of LEBRA linac. Proc FEL 2012:472–474
25.
Sakae T, Sato Y, Numata Y, Suwa T, Hayakawa T, Suzuki K, Kuwada T, Hayakawa K, Hayakawa Y, Tanaka T, Sato I (2007) Thermal ablation of FEL irradiation using gypsum as an indicator. Lasers Med Sci 22:15–20CrossRefPubMed
26.
Sakae T, Sato Y, Tanimoto Y, Higa M, Oinuma H, Kozawa Y, Okada H, Yamamoto H, Hayakawa T, Nemoto K, Sakai T, Nogami K, Mori A, Kuwada T, Hayakawa Y, Tanaka T, Hayakawa K, Sato I (2005) Pit formation in human enamel and dentin irradiated using the 2.94 μm LEBRA-free electron laser. Int J Oral Med Sci 4:8–13CrossRef
27.
Nemoto S, Iwai H, Suzuki H, Kamiya N, Iwai H, Iki K, Ikemi T (2010) Increased temperature and morphological change of bovine dentin irradiated by a free electron laser. Jpn J Conserv Dent 53:419–427 (in Japanese)
28.
Nemoto S (2012) Dentin abration with free electron laser. Jpn J Conserv Dent 55:185–194 (in Japanese)
29.
Sakae T, Hayakawa K, Hayakawa Y, Inagaki M, Kuwada T, Nakao K, Nogami K, Sato I, Tanaka T, Kii T, Ohgaki H, Zen H (2012) Pit Formation on Dental Hard Tissues Using Two Different Free Electron Laser Sources, LEBRA-FEL and KU-FEL. Proc FEL 2012:563–565
30.
Stasic J, Trtica M, Gakovic B, Petrovic S, Batani D, Desai T, Panjan P (2009) Surface modifications of AISI 1045 steel created by high intensity 1064 and 532nm picosecond Nd: YAG laser pulses. Appl Surf Sci 255:4474–4478CrossRef
31.
Hashida M, Semerok AF, Gobert O, Petite G, Izawa Y (2002) Ablation threshold dependence on pulse duration for copper. Appl Surf Sci 197:862–867CrossRef
Metadata
Title
Evaluation of irradiation effects of near-infrared free-electron-laser of silver alloy for dental application
Authors
Takao Kuwada-Kusunose
Alisa Kusunose
Masanobu Wakami
Chikako Takebayashi
Haruhiko Goto
Masahiro Aida
Takeshi Sakai
Keisuke Nakao
Kyoko Nogami
Manabu Inagaki
Ken Hayakawa
Kunihiro Suzuki
Toshiro Sakae
Publication date
01-08-2017
Publisher
Springer London
Published in
Lasers in Medical Science / Issue 6/2017
Print ISSN: 0268-8921
Electronic ISSN: 1435-604X
DOI
https://doi.org/10.1007/s10103-017-2251-5

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