Repair of tooth enamel by a biomimetic mineralization frontier ensuring epitaxial growth

Shao, Changyu; Jin, Biao; Zhao, Minshou; Lu, Hao; Zhao, Yueqi; Wu, Zhifang; Yan, Lumiao; Zhang, Zhisen; Zhou, Yanchun; Pan, Haihua; Liu, Zhaoming; Tang, Ruikang

doi:10.1126/sciadv.aaw9569

Cited by 172 publications

(156 citation statements)

References 48 publications

(62 reference statements)

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“…Caries results in the damage of the calcified structure of the dental apatite (tooth enamel). Despite the numerous efforts made by scientists to simulate the biomineralized crystallization–amorphous boundary of hard tissue in nature and to induce the epitaxial growth of enamel with current technology, damage of tooth enamel is irreversible [ 2 , 3 ]. Dental caries is a preventable disease that places a considerable burden on the economy and quality-of-life [ 1 ].…”

Section: Introductionmentioning

confidence: 99%

Isolation and Identification of Potentially Pathogenic Microorganisms Associated with Dental Caries in Human Teeth Biofilms

et al. 2020

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Dental caries is attributed to the predominance of cariogenic microorganisms. Cariogenic microorganisms are pathological factors leading to acidification of the oral microenvironment, which is related to the initiation and progression of caries. The accepted cariogenic microorganism is Streptococcus mutans (S. mutans). However, studies have found that caries could occur in the absence of S. mutans. This study aimed to assess the presence of potentially cariogenic microorganisms in human teeth biofilm. The microorganisms were isolated from human mouth and freshly extracted human maxillary incisors extracted for reasons of caries. The isolates were sorted based on their acidogenic and aciduric properties, and the S. mutans was used as the reference strain. Four potentially cariogenic strains were selected. The selected strains were identified as Streptococcus salivarius (S. salivarius), Streptococcus anginosus (S. anginosus), Leuconostoc mesenteroides (L. mesenteroides), and Lactobacillus sakei (L. sakei) through morphological analysis followed by 16S rRNA gene sequence analysis. The cariogenicity of isolates was analyzed. We show, for the first time, an association between L. sakei (present in fermented food) and dental caries. The data provide useful information on the role of lactic acid bacteria from fermented foods and oral commensal streptococci in dental caries.

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Section: Introductionmentioning

confidence: 99%

Isolation and Identification of Potentially Pathogenic Microorganisms Associated with Dental Caries in Human Teeth Biofilms

et al. 2020

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“…When compared to traditional enamel repair methods, our enamel repair with amorphous ceramics is outstanding (Figure i). Both the Young's modulus and hardness of E‐Amorphous ZrO 2 surpassed the values of enamel repaired by remineralization and with a composite resin, which showed a similar behavior to the E‐Sound samples (Figure i). To the best of our knowledge, the adoption of amorphous ZrO 2 in the fields of enamel repair has not been previously reported, and our enamel repair approach has been proven advantages, indicating great potential for future clinical applications.…”

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confidence: 66%

Enamel Repair with Amorphous Ceramics

et al. 2020

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Developing high‐performance materials in physiological conditions to clinically repair stiff tissue for long lifespan remains a great challenge. Here, an enamel repair strategy is reported by efficiently growing a biocompatible ZrO2 ceramic layer on defective enamel through controllable hydrolysis of Zr4+ in oral‐tolerable conditions. Detailed analysis of the grown layer indicates that the grown ZrO2 ceramic is amorphous without grain boundary and dislocation, which endows the repaired enamel with natural enamel comparable mechanical performance (modulus ≈82.5 GPa and hardness ≈5.2 GPa). Besides, the strong chemical connection between unsaturated coordinated Zr4+ in amorphous structure and PO43− greatly strengthen the crystalline–amorphous interface of the repaired enamel to endure the long‐time mastication damage. Moreover, these ZrO2 ceramics provide hydrophilic, electronegative, and smooth surfaces to resist the adhesion and proliferation of cariogenic bacteria. The hybrid amorphous–crystalline interface design with advantages in biomechanical compatibility would promote the evolution of a variety of cutting‐edge functional materials for medical and engineering application.

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“…例如: 以羟基磷灰石纳米材料构建的人造骨和基于聚合物多肽纳米材料自塑纳米骨浆在骨科临床得到了广泛的应用 [6~8] . 具备原位组装生长的智能纳米补牙材料 [9] , 以及兼具导热性好、强度高和重量轻的齿基托纳米材料等 [10~12] , 在口腔科展现出无可比拟的优点. 高分子纳米复合材料制作的可降解医用导管如心脏导管、腹腔导管等, 可适应临床多样性的需要, 同时在韧性、抗拉力及生物兼容性方面显著优于现有导管材料 [13] .…”

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Application prospect of nanomaterials mediated magnetic technology in the diagnosis and treatment of surgical diseases

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The era of clinical application of gene diagnosis in cardiovascular diseases is coming Chronic Diseases and Translational Medicine 5, 214 (2019); Prospect and application of Internet of Things technology for prevention of SARIs Clinical eHealth 3, 1 (2020); A review of the application of nanoparticles in the diagnosis and treatment of chronic kidney disease Bioactive Materials 5, 732 (2020); Artificial intelligence: The dawn of a new era for cutting-edge technology based diagnosis and treatment for stroke

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Repair of tooth enamel by a biomimetic mineralization frontier ensuring epitaxial growth

Cited by 172 publications

References 48 publications

Isolation and Identification of Potentially Pathogenic Microorganisms Associated with Dental Caries in Human Teeth Biofilms

Isolation and Identification of Potentially Pathogenic Microorganisms Associated with Dental Caries in Human Teeth Biofilms

Enamel Repair with Amorphous Ceramics

Application prospect of nanomaterials mediated magnetic technology in the diagnosis and treatment of surgical diseases

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