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      Organic-Mineral Interaction between Biomimetic Materials and Hard Dental Tissues

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          Abstract

          The aim of the investigation was to study the integration between native human dental tissue and new-generation biomimetic materials replicating the mineral-organic complex of dentin and enamel using IR microspectroscopy for multidimensional visualization and analysis.

          Materials and Methods

          The conditions for stable integration at the interface between biomimetic material and natural hard tissue were identified using a biocomposite buffer system of nanocrystalline carbonate-substituted calcium hydroxyapatite corresponding in its total characteristics to human dentin-enamel apatite and a number of amino acids present in the organic matrix of dentin and enamel: L-histidine, L-lysine hydrochloride, L-arginine hydrochloride, and hyaluronic acid. The finished samples were studied using IR microspectroscopy on IRM channel equipment (The Australian Synchrotron, Melbourne, Australia).

          Results

          The characteristic features of the biomimetic buffer layer at the interface between the enamel and dental material were revealed and visualized based on IR mapping of absorption intensity for particular functional molecular groups with the use of synchrotron radiation, location of the functional groups involved in the processes of biomimetic composite integration was identified.

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          Most cited references43

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          Biomimetic remineralization of dentin.

          Remineralization of demineralized dentin is important for improving dentin bonding stability and controlling primary and secondary caries. Nevertheless, conventional dentin remineralization strategy is not suitable for remineralizing completely demineralized dentin within hybrid layers created by etch-and-rinse and moderately aggressive self-etch adhesive systems, or the superficial part of a caries-affected dentin lesion left behind after minimally invasive caries removal. Biomimetic remineralization represents a different approach to this problem by attempting to backfill the demineralized dentin collagen with liquid-like amorphous calcium phosphate nanoprecursor particles that are stabilized by biomimetic analogs of noncollagenous proteins.
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            Oriented and Ordered Biomimetic Remineralization of the Surface of Demineralized Dental Enamel Using HAP@ACP Nanoparticles Guided by Glycine

            Achieving oriented and ordered remineralization on the surface of demineralized dental enamel, thereby restoring the satisfactory mechanical properties approaching those of sound enamel, is still a challenge for dentists. To mimic the natural biomineralization approach for enamel remineralization, the biological process of enamel development proteins, such as amelogenin, was simulated in this study. In this work, carboxymethyl chitosan (CMC) conjugated with alendronate (ALN) was applied to stabilize amorphous calcium phosphate (ACP) to form CMC/ACP nanoparticles. Sodium hypochlorite (NaClO) functioned as the protease which decompose amelogenin in vivo to degrade the CMC-ALN matrix and generate HAP@ACP core-shell nanoparticles. Finally, when guided by 10 mM glycine (Gly), HAP@ACP nanoparticles can arrange orderly and subsequently transform from an amorphous phase to well-ordered rod-like apatite crystals to achieve oriented and ordered biomimetic remineralization on acid-etched enamel surfaces. This biomimetic remineralization process is achieved through the oriented attachment (OA) of nanoparticles based on non-classical crystallization theory. These results indicate that finding and developing analogues of natural proteins such as amelogenin involved in the biomineralization by natural macromolecular polymers and imitating the process of biomineralization would be an effective strategy for enamel remineralization. Furthermore, this method represents a promising method for the management of early caries in minimal invasive dentistry (MID).
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              An amelogenin-chitosan matrix promotes assembly of an enamel-like layer with a dense interface.

              Biomimetic reconstruction of tooth enamel is a significant topic of study in materials science and dentistry as a novel approach to the prevention, restoration, and treatment of defective enamel. We have developed a new amelogenin-containing chitosan hydrogel for enamel reconstruction that works through amelogenin supramolecular assembly, stabilizing Ca-P clusters and guiding their arrangement into linear chains. These amelogenin Ca-P composite chains further fuse with enamel crystals and eventually evolve into enamel-like co-aligned crystals, anchored to the natural enamel substrate through a cluster growth process. A dense interface between the newly grown layer and natural enamel was formed and the enamel-like layer improved the hardness and elastic modulus compared with etched enamel. We anticipate that this chitosan hydrogel will provide effective protection against secondary caries because of its pH-responsive and antimicrobial properties. Our studies introduce an amelogenin-containing chitosan hydrogel as a promising biomaterial for enamel repair and demonstrate the potential of applying protein-directed assembly to biomimetic reconstruction of complex biomaterials.
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                Author and article information

                Journal
                Sovrem Tekhnologii Med
                Sovrem Tekhnologii Med
                stm
                Modern Technologies in Medicine
                Privolzhsky Research Medical University (Russia )
                2076-4243
                2309-995X
                2020
                2020
                : 12
                : 1
                : 43-50
                Affiliations
                [1]Senior Researcher, Department of Solid State Physics and Nanostructures, Voronezh State University, 1 University Square, Voronezh, 394018, Russia
                [2]Associate Professor, Head of the Department of Therapeutic Dentistry, Privolzhsky Research Medical University, 10/1 Minin and Pozharsky Square, Nizhny Novgorod, 603005, Russia
                [3]Leading Engineer, Department of Solid State Physics and Nanostructures, Voronezh State University, 1 University Square, Voronezh, 394018, Russia
                [4]Tutor, Department of Pediatric Dentistry and Orthodontics, Voronezh State Medical University named after N.N. Burdenko, 10 Studencheskaya St., Voronezh, 394036, Russia
                [5]Beamline Scientist, IR Microspectroscopy, The Australian Synchrotron (Synchrotron Light Source Australia Pty LTD), 800 Blackburn Rd., Clayton VIC 3168, Melbourne, Australia
                [6]Professor, Head of the Department of Pediatric Dentistry and Orthodontics, Voronezh State Medical University named after N.N. Burdenko, 10 Studencheskaya St., Voronezh, 394036, Russia
                Author notes
                Yury A. Ippolitov, e-mail: dsvgma@ 123456mail.ru

                Study funding. The study was supported by the Russian Foundation for Basic Research (grant 18-29-11008 мк).

                Conflict of interests. The authors declare no apparent or potential conflicts of interest related to the publication of this article.

                Article
                10.17691/stm2020.12.1.05
                8353705
                191357c2-aa73-452f-a466-ca2473a3eb8d

                This is an open access article under the CC BY 4.0 license ( https://creativecommons.org/licenses/by/4.0/).

                History
                : 25 June 2019
                Categories
                Biotechnologies

                biomimetic materials,native human hard dental tissue,ir microspectroscopy,synchrotron radiation

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