Observations on structural features and characteristics of biological apatite crystals. 6. Observation on lattice imperfection of human tooth and bone crystals. I.

T Ichijo, Y Yamashita, T Terashima
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Abstract

In a series of studies to investigate the basic structural features and characteristics of the biological apatite crystals, using an electron microscope, we examined the ultrastructure of the human enamel, dentin, and bone crystals at near atomic resolution and showed the configuration of the hydroxyapatite structure through the cross and longitudinal sections of the crystals. Subsequently, based on the results of the observations by the authors of the ultrastructure of the tooth and bone, using the same approach, we have been able to directly examine the images of the lattice imperfections in the human enamel, dentin, and bone crystals, such as the point defect structures and dislocations in the crystals. In this report, we describe the image of the point defect structures and line defect structures obtained, using the same approach from the sections of the human enamel, dentin, and bone crystals. The materials used for this study were the noncarious enamel and dentin from the freshly extracted human erupted lower first molars, and bone tissue obtained from the alveolar compact bone. The small cubes of the material were fixed in glutaraldehyde and osmium tetroxide and embedded in epoxy resin using the routine methods. The ultrathin sections were cut with a diamond knife without decalcification. The sections were examined with the HITACHI H-800 H and H-9000 types of transmission electron microscopes operated at 200 kV and 300 kV. Each crystal was observed at the initial magnification of 300,000-500,000 times and at the final magnification of 10,000,000 times and over. We sincerely believe that the electron micrographs shown in this report are the first to show the images of the lattice imperfections in the human enamel, dentin, and bone crystals, such as the point defect and line defect structures, at near atomic resolution.

生物磷灰石晶体结构特征及特性观察。6. 人牙、骨晶体晶格缺陷的观察。我。
为了研究生物磷灰石晶体的基本结构特征和特征,我们利用电子显微镜,在近原子分辨率下观察了人类牙釉质、牙本质和骨晶体的超微结构,并通过晶体的横切面和纵切面显示了羟基磷灰石结构的构型。随后,基于作者对牙齿和骨骼超微结构的观察结果,使用相同的方法,我们已经能够直接检查人类牙釉质,牙本质和骨晶体中的晶格缺陷图像,例如晶体中的点缺陷结构和位错。在本报告中,我们描述了点缺陷结构和线缺陷结构的图像,使用相同的方法从人类牙釉质,牙本质和骨晶体的切片中获得。本研究使用的材料是新鲜提取的人类下第一磨牙的无龋牙釉质和牙本质,以及从牙槽致密骨中获得的骨组织。用常规方法将材料的小立方体固定在戊二醛和四氧化二锇中,并包埋在环氧树脂中。超薄切片用金刚石刀切割,不脱钙。用日立H-800 H和H-9000型透射电子显微镜在200千伏和300千伏下对切片进行检查。每个晶体在初始放大30 -50万倍时观察,在最终放大1000万倍以上时观察。我们真诚地相信,本报告中所展示的电子显微照片是第一个以近原子分辨率显示人类牙釉质,牙本质和骨晶体晶格缺陷的图像,如点缺陷和线缺陷结构。
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