Formation of Stable Zinc-Rich Amorphous Calcium Phosphate

IF 3.2 2区化学 Q2 CHEMISTRY, MULTIDISCIPLINARY Crystal Growth & Design Pub Date : 2024-11-04 DOI:10.1021/acs.cgd.4c0094110.1021/acs.cgd.4c00941

Jia-hua Liu, Haidong Bian, Yibo Zhang, Yunchen Long, Chuan Li, Rong Zhang, Zhengyi Mao, Haikun Wu, Bo Li, Chunyi Zhi, Jian Lu* and Yang Yang Li*,

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Abstract

Metal ion-rich amorphous calcium phosphate (ACP) is an essential mineral component in biogenic hard tissues, such as bones and teeth. However, the formation mechanism of ion-doped ACP and the role of metal ions in this process remain elusive. Herein, taking Zn as an example, we develop a series of Zn-substituted calcium phosphate materials that serve as models for investigating the formation process of Zn-ACP. It is found that entirely pure Zn-ACP can be successfully achieved when the precursor Zn/Ca ratio is maintained between 0.1 and 0.2. The resulting Zn-ACP nanoparticles exhibit a homogeneous distribution of Zn at the nanoscale, excellent cytocompatibility, and exceptionally high amorphous stability in aqueous media, including water and simulated body fluid. Furthermore, we fabricate monolithic Zn-ACP bioceramics through the application of pressure, resulting in remarkable hardness (1.7 GPa) and modulus (25.5 GPa) that exceed those of human bones. This work presents a novel approach to producing Zn-ACP monoliths and advances our understanding of the biomineralization processes involving Zn and ACP, thus opening potential applications in biomedicine.

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形成稳定的富锌无定形磷酸钙

富含金属离子的无定形磷酸钙（ACP）是骨骼和牙齿等生物硬组织的重要矿物成分。然而，离子掺杂的 ACP 的形成机制以及金属离子在这一过程中的作用仍然难以捉摸。在此，我们以 Zn 为例，开发了一系列 Zn 取代的磷酸钙材料，作为研究 Zn-ACP 形成过程的模型。研究发现，当前驱体中 Zn/Ca 的比例保持在 0.1 和 0.2 之间时，可以成功地获得完全纯净的 Zn-ACP。所制备的 Zn-ACP 纳米粒子在纳米尺度上呈现出均匀的锌分布，细胞相容性极佳，在水介质（包括水和模拟体液）中具有极高的无定形稳定性。此外，我们还通过施加压力制造出了整体 Zn-ACP 生物陶瓷，其硬度（1.7 GPa）和模量（25.5 GPa）均超过了人类骨骼。这项研究提出了一种生产 Zn-ACP 整体的新方法，并加深了我们对涉及 Zn 和 ACP 的生物矿化过程的理解，从而为生物医学的应用提供了可能。

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来源期刊

Crystal Growth & Design 化学-材料科学：综合

CiteScore

6.30

自引率

10.50%

发文量

650

审稿时长

1.9 months

期刊介绍： The aim of Crystal Growth & Design is to stimulate crossfertilization of knowledge among scientists and engineers working in the fields of crystal growth, crystal engineering, and the industrial application of crystalline materials. Crystal Growth & Design publishes theoretical and experimental studies of the physical, chemical, and biological phenomena and processes related to the design, growth, and application of crystalline materials. Synergistic approaches originating from different disciplines and technologies and integrating the fields of crystal growth, crystal engineering, intermolecular interactions, and industrial application are encouraged.