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通过声沉淀法合成羟基磷灰石。

Synthesis of HAp by Means of Sonoprecipitation Method.

作者信息

Stec Magdalena, Synowiec Piotr Maria, Stolarczyk Agnieszka

机构信息

Department of Chemical Engineering and Process Design, Faculty of Chemistry, Silesian University of Technology, 44-100 Gliwice, Poland.

Inorganic Chemistry Research Group, New Chemical Syntheses Institute, Łukasiewicz Research Network, 44-100 Gliwice, Poland.

出版信息

Materials (Basel). 2024 Jul 2;17(13):3240. doi: 10.3390/ma17133240.

DOI:10.3390/ma17133240
PMID:38998323
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11242516/
Abstract

Biomaterials, like hydroxyapatite (HAp), are the subject of many scientific investigations. Their specific application, however, is determined by the form and some characteristic features of the resulting material. Synthesis methods and optimization procedures leading to a product of predetermined characteristics are therefore of great interest. To broaden the existing knowledge, sonoprecipitation was investigated as a potential method for the production of nanosized HAp particles. The research was carried out in a static mixer (STM) immersed in the ultrasonic bath. The influence of operating conditions, e.g., ultrasonic power (), ultrasonic frequency (f), and unit mixing power (), was investigated in terms of nucleation intensity, product quality, and characteristics (particle size distribution (), mean size, shape, etc.). As a result, the optimal conditions for the HAp nanoparticles synthesis (mean size: 150 nm; length: ~250 nm; width: ~80 nm) in the form of needles/whiskers/rods-similar to the shape of the HAp present in natural human bones, free from agglomerates, with negligible signs of particle destruction-were determined. The formation of HAp of smaller sizes ( ≤ 100 nm) and more compact shapes (155 nm, ~90 nm), useful in bone regeneration processes, was also discussed.

摘要

生物材料,如羟基磷灰石(HAp),是许多科学研究的对象。然而,它们的具体应用取决于所得材料的形式和一些特征。因此,能够产生具有预定特性产品的合成方法和优化程序备受关注。为了拓宽现有知识,研究了声沉淀法作为生产纳米级HAp颗粒的潜在方法。该研究在浸没于超声浴中的静态混合器(STM)中进行。从成核强度、产品质量和特性(粒度分布()、平均尺寸、形状等)方面研究了操作条件的影响,如超声功率()、超声频率(f)和单位混合功率()。结果,确定了以针状/晶须状/棒状形式合成HAp纳米颗粒的最佳条件(平均尺寸:约150nm;长度:约250nm;宽度:约80nm),类似于天然人骨中存在的HAp形状,无团聚,颗粒破坏迹象可忽略不计。还讨论了尺寸较小(≤100nm)且形状更紧凑(约155nm,约90nm)的HAp的形成,其在骨再生过程中有用。

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