One-step solid phase reaction-induced hydroxyapatite/magnesian whitlockite bioceramics for enhanced bone regeneration

IF 9.6 1区医学 Q1 ENGINEERING, BIOMEDICAL

Acta Biomaterialia Pub Date : 2025-10-01 DOI:10.1016/j.actbio.2025.08.058

Ruiqi Mao , Yu Yang , Dongxuan Li , Yawen Huang , Fengxiong Luo , Xiang Ge , Fuzeng Ren , Qing Jiang , Kefeng Wang , Yujiang Fan , Xingdong Zhang

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引用次数: 0

Abstract

Regenerative bioceramics for bone repair require an optimal balance of mechanical properties and osteogenic activity. Achieving this dual enhancement remains a significant challenge, particularly regarding the intrinsic properties of the ceramic. This study introduces a one-step solid-phase reaction strategy to generate new phase and nanostructure to enhance the performance of hydroxyapatite (HA) ceramic for bone repair. By incorporating magnesium phosphates (MP), the new phase (magnesian whitlockite, MWH) was produced, which exhibit suitable Mg²⁺ release and degradation efficiency compared to pure HA. The formation of interlaced nanocrystalline structure significantly improved the mechanical properties of the ceramics through a ‘grain binding strengthening’ mechanism, facilitating a transition from intergranular to transgranular fracture modes. Furthermore, MWH crystals with better strength than HA, contributed to the overall mechanical performance, ensuring compatibility with the mechanical requirements of bone implantation. The favorable release kinetics of Mg²⁺ promoted adhesion, spreading, and osteogenic differentiation of bone marrow stromal cells (BMSCs). In vivo studies validated the satisfactory bone regeneration capabilities of HA/MWH bioceramics. This innovative approach achieves a synergistic enhancement of mechanical strength and osteogenic activity, providing valuable insights for the optimization of porous bioceramics and their application in bone regeneration.

Statement of Significance

We present an innovative method to conveniently improve the synergistic performance of both mechanical strength and osteogenic activity in bioceramics. A one-step solid phase reaction was developed to produce Hydroxyapatite (HA)/Magnesian Whitlockite (MWH) dual-phase bioceramics, which exhibit superior mechanical properties over popular HA bioceramics. And the more favorable functional Mg²⁺ release kinetics of MWH resulted in a marked enhancement of osteogenic properties. We conducted experiments, computer simulations, cellular and animal evaluations to meticulously investigate the interlaced nanocrystalline structure, the ‘grain binding strengthening’ mechanisms of mechanical enhancement, and the improvement of osteogenic properties. Our work covers the entire spectrum of material science, preparation techniques, and biological performance validation. It provides new scientific insights for the research of porous bioceramics and would promote their applications in bone regeneration.

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一步固相反应诱导羟基磷灰石/镁镁白脱石生物陶瓷增强骨再生。

用于骨修复的再生生物陶瓷需要机械性能和成骨活性的最佳平衡。实现这种双重增强仍然是一个重大的挑战，特别是关于陶瓷的内在特性。本研究介绍了一种一步固相反应策略来生成新的相和纳米结构，以提高羟基磷灰石（HA）骨修复陶瓷的性能。通过加入磷酸镁（MP），制备出新的相（镁质whitlockite， MWH），与纯HA相比，该相具有较好的Mg2+释放和降解效率。交错纳米晶结构的形成通过“晶粒结合强化”机制显著改善了陶瓷的力学性能，促进了陶瓷从晶间断裂模式向穿晶断裂模式的转变。此外，MWH晶体具有比HA更好的强度，有助于整体力学性能，确保与骨植入的力学要求兼容。良好的Mg2+释放动力学促进骨髓基质细胞（BMSCs）的粘附、扩散和成骨分化。体内研究证实了HA/MWH生物陶瓷令人满意的骨再生能力。这种创新的方法实现了机械强度和成骨活性的协同增强，为多孔生物陶瓷的优化及其在骨再生中的应用提供了有价值的见解。意义声明：我们提出了一种创新的方法来方便地提高生物陶瓷的机械强度和成骨活性的协同性能。采用一步固相反应法制备了羟基磷灰石(HA)/镁Whitlockite （MWH）双相生物陶瓷，其力学性能优于常用的羟基磷灰石生物陶瓷。MWH更有利的功能Mg2+释放动力学导致成骨性能显著增强。我们通过实验，计算机模拟，细胞和动物评估来仔细研究交错纳米晶体结构，机械增强的“晶粒结合强化”机制，以及成骨性能的改善。我们的工作涵盖了材料科学、制备技术和生物性能验证的整个领域。这为多孔生物陶瓷的研究提供了新的科学见解，并将促进其在骨再生中的应用。

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来源期刊

Acta Biomaterialia 工程技术-材料科学：生物材料

CiteScore

16.80

自引率

3.10%

发文量

776

审稿时长

30 days

期刊介绍： Acta Biomaterialia is a monthly peer-reviewed scientific journal published by Elsevier. The journal was established in January 2005. The editor-in-chief is W.R. Wagner (University of Pittsburgh). The journal covers research in biomaterials science, including the interrelationship of biomaterial structure and function from macroscale to nanoscale. Topical coverage includes biomedical and biocompatible materials.