Synchrotron IR-microspectroscopy-based visualization of molecular and chemical interactions between dental cement, biomimetic composite and native dental tissue

Exosomes and microvesicles Pub Date : 2019-08-01 DOI:10.24075/brsmu.2019.047

D. Goloshchapov, V. Kashkarov, Y. Ippolitov, I. Ippolitov, J. Vongsvivut, P. Seredin

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引用次数: 2

Abstract

The low affinity of composite materials for the hard tissue of human teeth poses a challenge to restorative dentists. This study was undertaken to explore molecular and chemical characteristics of the interface between the dental cement, the buffer layer formed from a next generation biomimetic material that mimics the organic mineral composition of human enamel and dentin, and the intact native hard dental tissue. Seven plane-parallel dental slices were analyzed using synchrotron IR microspectroscopy. The obtained absorption spectra of functional molecular groups were organized into cluster maps. This allowed us to identify the intact tissue, the adhesive agent and the biomimetic layer at their interface and to localize and measure concentrations of functional groups involved in the integration of the biomimetic composite into the hard tissue of the human tooth. The proposed biomimetic material is based on nanocrystal carbonate-substituted calcium hydroxyapatite synthesized from a biogenic calcium source and a complex of basic polar amino acids copying the composition of the human tooth and can form a functional bond with hard dental tissue.

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基于同步加速器红外显微光谱的牙水泥、仿生复合材料和原生牙组织之间分子和化学相互作用的可视化研究

复合材料对人类牙齿硬组织的亲和力较低，对修复牙医提出了挑战。本研究旨在探索牙水泥、下一代仿生材料(模仿人类牙釉质和牙本质的有机矿物成分)形成的缓冲层与完整的天然硬牙组织之间界面的分子和化学特性。采用同步红外显微光谱技术对7片平面平行牙片进行了分析。得到的官能团吸收光谱被组织成簇状图。这使我们能够在界面处识别完整的组织、粘合剂和仿生层，并定位和测量参与将仿生复合材料整合到人类牙齿硬组织中的官能团的浓度。拟制的仿生材料是基于纳米晶碳酸盐取代的钙羟基磷灰石，由生物钙源和复制人类牙齿组成的碱性极性氨基酸复合物合成，可以与硬牙组织形成功能键。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Exosomes and microvesicles

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