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Abstract

Objective:

The purpose of this study is to investigate the crystal structure of bacteria-contaminated bovine dentin after Er:YAG laser irradiation at various energy densities from macroscale, microscale, and nanoscale.

Background:

Er:YAG laser can change the morphology and chemical components of dentin. Few preliminary researchers investigate the laser effect on crystal in dentin tissue.

Methods:

Twenty dentin specimens from bovine incisors were cocultured with S. mutans (UA 159) and divided into four groups with diverse Er:YAG laser irradiation energy (0, 6.37, 12.73, 19.11 J/cm²). The ultrastructure of dentin before and after laser irradiation was investigated with nanoanalytical electron microscopy. X-ray diffraction provided the information of lattice parameters in dentin. The morphology of dentin was observed by scanning electron microscopy. High-resolution transmission electron microscope images and selected-area electron diffraction patterns were obtained for characterizing crystal domain size, structure, and microenvironment of dentin.

Results:

The combination of these methods disclosed that there exist mineralized, demineralized, and remineralized dentin in the bacteria-invaded dentin and can be feasibly recognized using morphological features. Laser treatments influence hydroxyapatite (HAp) crystals in dentin tissue in different ways: needle HAp in mineralized dentin tissue keeps intact with laser irradiation of no higher than 19.11 J/cm²; laser irradiation improves the crystallinity of lamella HAp by domain growth and rearranges its growth orientations.

Conclusions:

We report an unprecedented presence of remineralization zone consisting of lamella HAp crystals with distinct high-index planes. These findings have broad implications on the role of laser operation in driving biomineralization and shed new insights into a possible relationship between laser irradiation and remineralization.

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References

Bawaskar

, Bawaskar

. Oral diseases: a global public health challenge. Lancet, 2020; 395:185–186.

Montedori

, Abraha

, Orso

, D'Errico

, Pagano

, Lombardo

. Lasers for caries removal in deciduous and permanent teeth. Cochrane Database Syst Rev, 2016; 9:CD010229.

Cozean

, Arcoria

, Pelagalli

, Powell

. Dentistry for the 21st century? Erbium:YAG laser for teeth. J Am Dent Assoc, 1997; 128:1080–1087.

Olivi

, Caprioglio

, Olivi

, Genovese

. Paediatric laser dentistry. Part 2: hard tissue laser applications. Eur J Paediatr Dent, 2017; 18:163–166.

Olivi

, Genovese

. Laser restorative dentistry in children and adolescents. Eur Arch Paediatr Dent, 2011; 12:68–78.

, Ge

, Zhang

. Effects of erbium:yttrium-aluminum-garnet laser irradiation on bovine dentin contaminated by cariogenic bacteria. Photobiomodul Photomed Laser Surg, 2019; 37:305–311.

Rohanizadeh

, LeGeros

, Fan

, Jean

, Daculsi

. Ultrastructural properties of laser-irradiated and heat-treated dentin. J Dent Res, 1999; 78:1829–1835.

Kinney

, Haupt

, Balooch

, et al. The threshold effects of Nd and Ho: YAG laser-induced surface modification on demineralization of dentin surfaces. J Dent Res, 1996; 75:1388–1395.

Lee

, Lin

, Hung

, Lan

. Structural changes of Er:YAG laser-irradiated human dentin. Photomed Laser Surg, 2004; 22:330–334.

10.

Bakry

, Sadr

, Takahashi

, Otsuki

, Tagami

. Analysis of Er:YAG lased dentin using attenuated total reflectance Fourier transform infrared and X-ray diffraction techniques. Dent Mater J, 2007; 26:422–428.

11.

Botta

, Ana

, de Sa Teixeira

, da Silveira Salvadori

, Matos

. Relationship between surface topography and energy density distribution of Er,Cr:YSGG beam on irradiated dentin: an atomic force microscopy study. Photomed Laser Surg, 2011; 29:261–269.

12.

Mei

, Ito

, Chu

, Lo

, Zhang

. Prevention of dentine caries using silver diamine fluoride application followed by Er:YAG laser irradiation: an in vitro study. Lasers Med Sci, 2014; 29:1785–1791.

13.

Ramalho

, Hsu

, de Freitas

, et al. Erbium lasers for the prevention of enamel and dentin demineralization: a literature review. Photomed Laser Surg, 2015; 33:301–319.

14.

Patterson

. The Scherrer formula for X-ray particle size determination. Phys Rev, 1939; 56:305–311.

15.

Takahashi

, Nyvad

. The role of bacteria in the caries process: ecological perspectives. J Dent Res, 2011; 90:294–303.

16.

Takahashi

, Nyvad

. Ecological hypothesis of dentin and root caries. Caries Res, 2016; 50:422–431.

17.

Frank

. Structural events in the caries process in enamel, cementum, and dentin. J Dent Res, 1990; 69 Spec No:559–636.

18.

Pugach

, Strother

, Darling

, et al. Dentin caries zones: mineral, structure, and properties. J Dent Res, 2009; 88:71–76.

19.

Fusayama

, Terashima

. Differentiation of two layers of carious dentin by staining. Bull Tokyo Med Dent Univ, 1972; 19:83–92.

20.

Ogushi

, Fusayama

. Electron microscopic structure of the two layers of carious dentin. J Dent Res, 1975; 54:1019–1026.

21.

Lester

, Boyde

. Some preliminary observations on caries (“remineralization”) crystals in enamel and dentine by surface electron microscopy. Virchows Arch Pathol Anat Physiol Klin Med, 1967; 344:196–212.

22.

Ogawa

, Yamashita

, Ichijo

, Fusayama

. The ultrastructure and hardness of the transparent layer of human carious dentin. J Dent Res, 1983; 62:7–10.

23.

Frank

, Voegel

. Ultrastructure of the human odontoblast process and its mineralisation during dental caries. Caries Res, 1980; 14:367–380.

24.

Daculsi

, LeGeros

, Jean

, Kerebel

. Possible physico-chemical processes in human dentin caries. J Dent Res, 1987; 66:1356–1359.

25.

Zavgorodniy

, Rohanizadeh

, Swain

. Ultrastructure of dentine carious lesions. Arch Oral Biol, 2008; 53:124–132.

26.

Zavgorodniy

, Rohanizadeh

, Bulcock

, Swain

. Ultrastructural observations and growth of occluding crystals in carious dentine. Acta Biomater, 2008; 4:1427–1439.

27.

Yoshihara

, Nagaoka

, Nakamura

, et al. Three-dimensional observation and analysis of remineralization in dentinal caries lesions. Sci Rep, 2020; 10:4387.

28.

Moghaddas

, Moosavi

, Yaghoubirad

, Chiniforush

. The effect of the bioactive glass and the Er:YAG laser on the remineralization of the affected dentin: a comparative in vitro study. J Lasers Med Sci, 2020; 11:160–166.

29.

Moosavi

, Ghorbanzadeh

, Ahrari

. Structural and morphological changes in human dentin after ablative and subablative Er:YAG laser irradiation. J Lasers Med Sci, 2016; 7:86–91.

30.

Moritz

, Schoop

, Goharkhay

, et al. Procedures for enamel and dentin conditioning: a comparison of conventional and innovative methods. J Esthet Dent, 1998; 10:84–93.

31.

Ramos

, Ramos-Oliveira

, de Freitas

, et al. Effects of Er:YAG and Er,Cr:YSGG laser irradiation on the adhesion to eroded dentin. Lasers Med Sci, 2015; 30:17–26.

32.

Nahas

, Zeinoun

, Majzoub

, Corbani

, Nammour

. The effect of energy densities on the shear bond strength of self-adhering flowable composite to Er:YAG pretreated dentin. Biomed Res Int, 2016; 2016:6507924.

33.

Nurrohman

, Nikaido

, Takagaki

, Sadr

, Ichinose

, Tagami

. Apatite crystal protection against acid-attack beneath resin-dentin interface with four adhesives: TEM and crystallography evidence. Dent Mater, 2012; 28:e89–e98.

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Ultrastructural Analysis of Er:YAG Lased Bovine Dentin Contaminated by Cariogenic Bacteria