3D printed porous PLGA/n-HA/MgP composite scaffolds with improved osteogenic and angiogenic properties

Enhanced osteogenesis and angiogenesis capacity of 3D printed porous PLGA/n-HA scaffolds incorporated with magnesium phosphate. [Display omitted] •Porous PLGA/n-HA/MgP composite (PHM) scaffolds are fabricated by FDM.•Doping of MgP accelerates the degradation of scaffolds and buffers the acid environ...

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Published in:Materials & design 2023-10, Vol.234, p.112351, Article 112351
Main Authors: Lu, Minxun, Li, Longqing, Zheng, Chuanxi, Wang, Yitian, Zhang, Boqing, Wang, Ling, Li, Zhuangzhuang, Zhang, Yuqi, Zhou, Yong, Zhou, Changchun, Min, Li, Fan, Yujiang, Tu, Chongqi
Format: Article
Language:English
Subjects:
3D printing
Angiogenesis
Magnesium phosphates
Nano-hydroxyapatite
Osteogenesis
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Summary:Enhanced osteogenesis and angiogenesis capacity of 3D printed porous PLGA/n-HA scaffolds incorporated with magnesium phosphate. [Display omitted] •Porous PLGA/n-HA/MgP composite (PHM) scaffolds are fabricated by FDM.•Doping of MgP accelerates the degradation of scaffolds and buffers the acid environment caused by PLGA degradation.•Scaffold with 10% MgP ratio shows good effect on osteogenesis and neovascularization.•Over 30% MgP content shows a negative effect on bone regeneration. The osteogenic and angiogenic characteristics are crucial for the selection of bone substitute materials and structural design. This study proposed a porous PLGA/n-HA/MgP composited scaffold by printing of the poly (lactide-coglycolide) (PLGA), nano-hydroxyapatite (n-HA), and magnesium phosphate (MgP). The physicochemical properties, osteogenic activities, and pro-angiogenic impacts of porous 3D printed PLGA/n-HA scaffolds with variable MgP concentration were investigated. The results indicated that the presence of MgP in the composite promoted scaffold degradation and buffered the acidic environment induced by PLGA degradation. The highest pro-osteogenic activity has been observed in PLGA/n-HA/10% MgP (PH10M) group, which up-regulated BMP2 and RUNX2 factors in vitro and in vivo. Nevertheless, at a maximal ion release of 7.2 mmol/L, PLGA/n-HA/30% MgP (PH30M) marginally reduced theosteogenic differentiation of osteoblasts through the RANKL/OPG pathway. In vitro, PLGA/n-HA/20% MgP (PH20M) demonstrated superior migration, pro-angiogenic factor expression, and angiogenesis compared to other groups, and the histological investigation corroborated the improved angiogenesis in PH10M and PH20M. In conclusion, suitable MgP ratio shows the potential to improve the osteogenic and angiogenic properties of PLGA/n-HA-based composites in orthopedic applications.
ISSN:0264-1275
1873-4197
DOI:10.1016/j.matdes.2023.112351