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锌掺杂钙黄长石:一种具有增强生物活性、机械强度及细菌研究潜力的骨科应用生物材料。

Zinc Doped Akermanite: A Promising Biomaterial for Orthopedic Application with Enhanced Bioactivity, Mechanical Strength, and Bacterial Study.

作者信息

Kothandam Shobana, V Selvatharani, Vijayakumar Naveensubramaniam, Alex Raveena Ann, Abraham Jayanthi, Maheshwaran Selvarasu, Swamiappan Sasikumar

机构信息

Department of Chemistry, School of Advanced Sciences, Vellore Institute of Technology, Vellore 632014, Tamil Nadu, India.

Microbial Biotechnology Laboratory, School of Bio-Sciences and Technology, VIT University, Vellore 632014, Tamil Nadu, India.

出版信息

ACS Omega. 2025 Jan 10;10(2):1911-1926. doi: 10.1021/acsomega.4c05482. eCollection 2025 Jan 21.

DOI:10.1021/acsomega.4c05482
PMID:39866635
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11755182/
Abstract

Incorporating zinc into biocompatible materials has been identified as a potential strategy for promoting bone regeneration and osteogenic activity during hard tissue regeneration. This work aimed to investigate the impact of zinc doping on the structure of akermanite, which was synthesized using the sol-gel combustion method, with the goal of improving the biological response. Powder XRD and FT-IR analysis confirmed the phase purity and the respective functional groups associated with Zn-doped akermanite. Further XPS analysis confirmed the presence of zinc with the respective binding energies in the akermanite matrix. According to the results obtained from the analysis, the apatite-forming ability of Zn-doped akermanite demonstrated enhanced apatite deposition on the surface of the pellet after 9 days of immersion in the SBF medium. The measured mechanical parameters, including compressive strength (140-189 MPa) and Young's modulus (2505-3599 MPa), fall within the range of human cortical bone. Antimicrobial results showed an improved inhibition rate of the doped ceramics compared to pure akermanite with an inhibition percentage of 87% even at lower concentrations. The hemocompatibility of the materials showed hemolysis of human blood cells within the acceptable range without exhibiting toxicity. Cytotoxicity results demonstrate the biocompatibility of the materials with the MG-63 cell line. Based on the results, akermanite doped with zinc at optimal concentrations was found to be compatible and nontoxic promoting it as a potential alternative for bone regeneration in orthopedic applications.

摘要

将锌掺入生物相容性材料已被确定为在硬组织再生过程中促进骨再生和成骨活性的一种潜在策略。这项工作旨在研究锌掺杂对使用溶胶 - 凝胶燃烧法合成的钙黄长石结构的影响,以改善其生物学反应。粉末XRD和FT - IR分析证实了锌掺杂钙黄长石的相纯度以及各自相关的官能团。进一步的XPS分析证实了钙黄长石基质中具有各自结合能的锌的存在。根据分析结果,锌掺杂钙黄长石的磷灰石形成能力表明,在SBF培养基中浸泡9天后,颗粒表面的磷灰石沉积有所增强。所测量的力学参数,包括抗压强度(140 - 189 MPa)和杨氏模量(2505 - 3599 MPa),落在人体皮质骨的范围内。抗菌结果表明,与纯钙黄长石相比,掺杂陶瓷的抑制率有所提高,即使在较低浓度下抑制率也达到87%。材料的血液相容性表明人体血细胞的溶血在可接受范围内,且未表现出毒性。细胞毒性结果证明了材料与MG - 63细胞系的生物相容性。基于这些结果,发现以最佳浓度掺杂锌的钙黄长石具有相容性且无毒,使其成为骨科应用中骨再生的潜在替代品。

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