Multiscale architecture design of 3D printed biodegradable Zn-based porous scaffolds for immunomodulatory osteogenesis

Reconciling the dilemma between rapid degradation and overdose toxicity is challenging in biodegradable materials when shifting from bulk to porous materials. Here, we achieve significant bone ingrowth into Zn-based porous scaffolds with 90% porosity via osteoinmunomodulation. At microscale, an allo...

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Bibliographic Details
Published in:Nature communications 2024-04, Vol.15 (1), p.3131-3131, Article 3131
Main Authors: Li, Shuang, Yang, Hongtao, Qu, Xinhua, Qin, Yu, Liu, Aobo, Bao, Guo, Huang, He, Sun, Chaoyang, Dai, Jiabao, Tan, Junlong, Shi, Jiahui, Guan, Yan, Pan, Wei, Gu, Xuenan, Jia, Bo, Wen, Peng, Wang, Xiaogang, Zheng, Yufeng
Format: Article
Language:English
Subjects:
13/1
13/51
14/19
147/135
147/3
631/61/54/990
639/301/54/993
Biocompatibility
Biodegradability
Biodegradable materials
Biodegradation
Bone growth
Degradation
Eutectoids
Filopodia
Humanities and Social Sciences
Immune response
Immunomodulation
Inflammation
Lamellar structure
Macrophages
Minimal surfaces
multidisciplinary
Osteogenesis
Overdose
Phenotypes
Porosity
Porous materials
Regeneration
Regeneration (physiology)
Scaffolds
Science
Science (multidisciplinary)
Three dimensional printing
Toxicity
Transcriptomics
Zinc
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Summary:Reconciling the dilemma between rapid degradation and overdose toxicity is challenging in biodegradable materials when shifting from bulk to porous materials. Here, we achieve significant bone ingrowth into Zn-based porous scaffolds with 90% porosity via osteoinmunomodulation. At microscale, an alloy incorporating 0.8 wt% Li is employed to create a eutectoid lamellar structure featuring the LiZn 4 and Zn phases. This microstructure optimally balances high strength with immunomodulation effects. At mesoscale, surface pattern with nanoscale roughness facilitates filopodia formation and macrophage spreading. At macroscale, the isotropic minimal surface G unit exhibits a proper degradation rate with more uniform feature compared to the anisotropic BCC unit. In vivo, the G scaffold demonstrates a heightened efficiency in promoting macrophage polarization toward an anti-inflammatory phenotype, subsequently leading to significantly elevated osteogenic markers, increased collagen deposition, and enhanced new bone formation. In vitro, transcriptomic analysis reveals the activation of JAK/STAT pathways in macrophages via up regulating the expression of Il-4 , Il-10 , subsequently promoting osteogenesis. Rapid degradation inducing overdose toxicity remains challenging in porous biodegradable bone scaffolds. Here the authors present multiscale architecture design on ZnLi scaffolds with 90% porosity orchestrates immune responses and subsequent bone regeneration.
ISSN:2041-1723
2041-1723
DOI:10.1038/s41467-024-47189-5