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Lasers in Medical Science
Published in: Lasers in Medical Science 1/2013

01-01-2013 | Original Article

Influence of the hydration state on the ultrashort laser ablation of dental hard tissues

Authors: Francisco de Assis M. G. Rego Filho, Maristela Dutra-Corrêa, Gustavo Nicolodelli, Vanderlei S. Bagnato, Maria Tereza de Araujo

Published in: Lasers in Medical Science | Issue 1/2013

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Abstract

Since about 40 years, laser-based surgical tools have been used in medicine and dentistry to improve clinical protocols. In dentistry, femtosecond lasers have been claimed to be a potential ablation tool. It would, however, be good to perform a more fundamental investigation to understand ablation interaction mechanisms and possible side effects, depending on different specific components of the target tissue. The goal of this study is to show the changes of ablation characteristics in the femtosecond regime at different levels of structural water within dental hard tissues. Thirty human teeth samples were split into three hydration groups and subdivided into dentin and enamel groups (n = 5). The specimens were irradiated using a 70-fs Ti:sapphire laser (with a 1-kHz repetition rate and a 801-nm wavelength output). Ablation was performed using five different power levels and three exposure times. The results clearly show an inversely proportional dependence of the ablation threshold to the hydration level of the tissues. A known mathematical model was adapted in order to include the influence of the changes on the relative fractional composition of dental hard tissues. This analysis was consistent with the experimental results regarding the ablation threshold. High thermal and mechanical damages were observed as a high repetition rate had been applied. Macroscopic images and scanning electron microscopy images were used to preliminarily analyze both the thermal and mechanical damage thresholds, and their variations according to the hydration level present. By manipulating the hydration states, the modifications in the proportions of the molecules that build dental hard tissues clearly shift, and therefore, the characteristics of a plasma-induced ablation change.
Literature
1.
Goldman L, Hornby P, Meyer R, Goldman B (1964) Impact of the laser on dental caries. Nature 203:417–417
2.
Stern RH, Sognnaes RF (1964) Laser beam effect on dental hard tissues. J Dent Res 43:873–873
3.
Hsu PJ, Chen JH, Chuang FH, Roan RT (2006) The combined occluding effects of fluoride-containing dentin desensitizer and Nd–Yag laser irradiation on human dentinal tubules: an in vitro study. Kaohsiung J Med Sci 22:24–29PubMedCrossRef
4.
Porto ICCM, Andrade AKM, Montes MAJR (2009) Diagnosis and treatment of dentinal hypersensitivity. J Oral Sci 51:323–332PubMedCrossRef
5.
Moriyama EH, Zângaro RA, Villaverde AB, Lobo PD, Munin E, Watanabe IS, Júnior DR, Pacheco MT (2004) Dentin evaluation after Nd:YAG laser irradiation using short and long pulses. J Clin Laser Med Surg 22:43–50PubMedCrossRef
6.
Zach L, Cohen G (1965) Pulp response to externally applied heat. Oral Surg Oral Med Oral Pathol 19:515–530PubMedCrossRef
7.
Hibst R, Keller U (1989) Experimental studies of the application of the Er:YAG laser on dental hard substances. Laser Surg Med 9:338–344CrossRef
8.
Walsh LJ, Perham S (1991) Enamel fusion using a carbon dioxide laser: a technique for sealing pits and fissures. Clin Prev Dent 13:16–20PubMed
9.
Altundasar E, Özçelik B, Cehreli ZC, Matsumoto K (2006) Ultramorphological and histochemical changes after ER, CR:YSGG laser irradiation and two different irrigation regimes. J Endodontics 32:465–468CrossRef
10.
Mir M, Gutknecht N, Poprawe R, Vanweersch L, Lampert F (2009) Visualising the procedures in the influence of water on the ablation of dental hard tissue with erbium:yttrium-aluminium-garnet and erbium, chromium:yttrium–scandium–gallium–garnet laser pulses. Lasers Med Sci 24(3):365–374PubMedCrossRef
11.
Burkes EJ Jr, Hoke J, Gomes E, Wolbarsht M (1992) Wet versus dry enamel ablation by Er:YAG laser. J Prosthet Dent 67:847–851PubMedCrossRef
12.
Tsai C-L, Lin Y-T, Huang S-T, Chang H-W (2002) In vitro acid resistance of CO2 and Nd:YAG laser-treated human tooth enamel. Caries Res 36:423–429PubMedCrossRef
13.
Perry MD, Stuart BC, Banks PS, Feit MD, Yvanovsky V, Rubenchik AM (1999) Ultrashort-pulse laser machining of dielectric materials. J Appl Phys 85:6803–6810CrossRef
14.
Neev J, Da Silva LB, Feit MD, Perry MD, Rubenchik AM, Stuart BC (1996) Ultrashort pulse lasers for hard tissue ablation. IEEE J Sel Top Quant Electron 2(4):790–800CrossRef
15.
Rode AV, Gamaly EG, Luther-Davis B, Taylor BT, Dawes J, Chan A, Lowe RM, Hannaford P (2002) Subpicosecond laser ablation of dental enamel. J Appl Phys 92(4):2153–2158CrossRef
16.
Dumitru G, Romano V, Weber HP, Sentis M, Marine W (2002) Femtosecond ablation of ultrahard materials. Appl Phys A 74(6):729–739CrossRef
17.
Dong Y, Molian P (2003) Femtosecond pulsed laser ablation of 3C–SiC thin film on silicon. Appl Phys A 77:839–846CrossRef
18.
Liu JM (1982) Simple technique for measurements of pulsed Gaussian-beam spot sizes. Opt Lett 7(5):196–198PubMedCrossRef
19.
Dutra-Correa M, Rodrigues JR, Moriyama LT, Lizarelli RFZ, Bagnato VS (2005) Avaliação das Propriedades Térmicas. Químicas e Mecânicas Comparando Dente Bovino e Dente Humano. Braz Oral Res 19:184
20.
Dutra-Correa M, Rodrigues JR, Nicolodelli G, Kurachi C, Bagnato VS (2010) Femtosecond LASER ablation of bovine and human hard dental tissues: comparative morphological and physicochemical analysis. J Bras Laser 2:25–32
21.
Lizarelli RFZ, Kurachi C, Misoguti L, Bagnato VS (1999) Characterization of enamel and dentin response to Nd:YAG picosecond laser ablation. J Clin Laser Med Surg 17(3):127–131PubMed
22.
Niemz MH (2003) In: Niemz MH (ed) Laser tissue interactions: fundamentals and applications. Springer, New York, p 328
23.
Niemz MH (1995) Theshold dependance of laser-induced optical breakdown on pulse duration. Appl Phys Lett 66:1181–1183CrossRef
24.
Lossel FH, Niemz MH, Bille JF, Juhasz T (1996) Laser-induced optical breakdown on hard and soft tissues and its dependence on the pulse duration: experiment and model. IEEE J Quantum Electron 32(10):1717–1722CrossRef
25.
Holcomb DW, Young RA (1980) Thermal decomposition of human tooth enamel. Calcif Tissue Int 31:189–201PubMedCrossRef
26.
Little MF, Casciani FS (1966) The nature of water in sound human enamel: a preliminary study. Arch Oral Biol 11(6):565–571PubMedCrossRef
27.
LeGeros RZ, Bonel G, Legros R (1978) Types of H2O in human enamel and in precipitated apatites. Calcif Tissue Int 26:111–118CrossRef
28.
Ladieu F, Martin Ph, Guizard S (2002) Measuring thermal effects in femtosecond laser-induced breakdown of dielectrics. Appl Phys Lett 81(6):957–959CrossRef
29.
Dry ME, Beebe RA (1960) Adsorption studies on bone mineral and synthetic hydroxyapatite. J Phys Chem B 64(9):1300–1304CrossRef
30.
Baratieri LN, Baratieri LN (2001) Odontologia Restauradora: fundamentos e possibilidades. Santos, São Paulo, p 740
31.
Katchburian E, Arana-Chavez VE (1999) In: Katchburian E, Arana-Chavez VE (eds) Histologia e embriologia oral. Médica Panamericana, São Paulo, p 381
32.
Bachmann L, Zezell DM (2005) Estrutura e Composição do Esmalte e da Dentina: tratamento térmico e irradiação Laser. Livraria da Física, São Paulo, p 298
33.
Krüger J, Kautek W, Newesely H (1999) Femtosecond-pulse laser ablation of dental hydroxyapatite and single-crystalline fluoroapatite. Appl Phys A 69:403–407CrossRef
34.
Paghdiwala AF (1991) Does the laser work on hard dental tissue? J Am Dent Assoc 122:79–80PubMed
Metadata
Title
Influence of the hydration state on the ultrashort laser ablation of dental hard tissues
Authors
Francisco de Assis M. G. Rego Filho
Maristela Dutra-Corrêa
Gustavo Nicolodelli
Vanderlei S. Bagnato
Maria Tereza de Araujo
Publication date
01-01-2013
Publisher
Springer-Verlag
Published in
Lasers in Medical Science / Issue 1/2013
Print ISSN: 0268-8921
Electronic ISSN: 1435-604X
DOI
https://doi.org/10.1007/s10103-012-1118-z

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