通过血管生成和 Wnt 信号相关的骨生成激活,补充葡萄糖酸镁可增强支架介导的新骨形成和自然骨愈合。

Govinda Bhattarai, Saroj Kumar Shrestha, Shankar Rijal, Sung-Ho Kook, Jeong-Chae Lee
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引用次数: 0

摘要

局部植入或补充葡萄糖酸镁(MgG)作为一种有效的骨修复方法正在接受研究。尽管已有研究强调了镁离子刺激新骨形成的可能机制,但人们尚未完全了解镁在骨缺损愈合中的作用和信号传导机制。在本研究中,我们通过在动物模型中局部和口服 MgG,探索了补充 MgG 如何对骨产生特异性有益作用。我们制作了具有良好微结构和生物相容性的含 MgG(CMC-M)和不含 MgG 的壳聚糖(CMC)支架。与 CMC 相比,CMC-M 通过激活 Wnt 信号以及与 Wnt 相关的成骨和血管生成分子,促进了大鼠下颌骨缺损模型的骨愈合。在小鼠股骨缺损模型中,口服 MgG 也能刺激骨愈合,同时增加 Wnt3a 以及血管生成和成骨因子。在成年小鼠模型中,补充MgG不会改变骨增生的性质和骨髓(BM)微环境,但会增强骨髓基质细胞(BMSCs)的功能。此外,MgG还能直接刺激BMSCs培养物中Wnt信号、血管生成和成骨相关分子的诱导,并引发内皮细胞的迁移。这些结果表明,Wnt 信号相关的血管生成和成骨分子协同增强了补充 MgG 改善骨修复的作用。总之,这项研究表明,补充MgG可改善基底膜的氧化损伤,提高基底膜干细胞的功能,并维持基底膜微环境的平衡。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Supplemental Magnesium Gluconate Enhances Scaffold-Mediated New Bone Formation and Natural Bone Healing by Angiogenic- and Wnt Signal-Associated Osteogenic Activation.

Local implantation or supplementation of magnesium gluconate (MgG) is being investigated as an effective approach to bone repair. Although studies have highlighted the possible mechanisms in Mg ion-stimulated new bone formation, the role of MgG in healing bone defects and the signaling mechanisms are not yet completely understood. In this study, we explored how supplemental MgG has bone-specific beneficial effects by delivering MgG locally and orally in animal models. We fabricated MgG-incorporated (CMC-M) and -free chitosan (CMC) scaffolds with good microstructures and biocompatible properties. Implantation with CMC-M enhanced bone healing in rat model of mandible defects, compared with CMC, by activating Wnt signals and Wnt-related osteogenic and angiogenic molecules. Oral supplementation with MgG also stimulated bone healing in mouse model of femoral defects along with the increases in Wnt3a and angiogenic and osteogenic factors. Supplemental MgG did not alter nature bone accrual and bone marrow (BM) microenvironment in adult mouse model, but enhanced the functioning of BM stromal cells (BMSCs). Furthermore, MgG directly stimulated the induction of Wnt signaling-, angiogenesis-, and osteogenesis-related molecules in cultures of BMSCs, as well as triggered the migration of endothelial cells. These results suggest that supplemental MgG improves bone repair in a way that is synergistically enhanced by Wnt signal-associated angiogenic and osteogenic molecules. Overall, this study indicates that supplemental MgG might ameliorate oxidative damage in the BM, improve the functionality of BM stem cells, and maintain BM-microenvironmental homeostasis.

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