An engineered lamellar bone mimicking full-scale hierarchical architecture for bone regeneration
Tao Yang, Zhichao Hao, Zhenzhen Wu, Binxin Xu, Jiangchen Liu, Le Fan, Qinmei Wang, Yanshan Li, Dongying Li, Sangzhu Tang, Chuanzi Liu, Weichang Li, Wei Teng
Journal:Bioactive Materials
IF:18.9
DOI:10.1016/j.bioactmat.2023.03.024
PMID:37091064
Published:2023-04-08
research field:生物材料生物医学工程骨生物学组织工程
Abstract
Lamellar bone, compactly and ingeniously organized in the hierarchical pattern with 6 ordered scales, is the structural motif of mature bone. Each hierarchical scale exerts an essential role in determining physiological behavior and osteogenic bioactivity of bone. Engineering lamellar bone with full-scale hierarchy remains a longstanding challenge. Herein, using bioskiving and mineralization, we attempt to engineer compact constructs resembling full-scale hierarchy of lamellar bone. Through systematically investigating the effect of mineralization on physicochemical properties and bioactivities of multi-sheeted collagen matrix fabricated by bioskiving, the hierarchical mimicry and hierarchy-property relationship are elucidated. With prolongation of mineralization, hierarchical mimicry and osteogenic bioactivity of constructs are performed in a bidirectional manner, i.e. first rising and then descending, which is supposed to be related with transformation of mineralization mechanism from nonclassical to classical crystallization. Construct mineralized 9 days can accurately mimic each hierarchical scale and efficiently promote osteogenesis. Bioinformatic analysis further reveals that this construct potently activates integrin α5-PI3K/AKT signaling pathway through mechanical and biophysical cues, and thereby repairing critical-sized bone defect. The present study provides a bioinspired strategy for completely resembling complex hierarchy of compact mineralized tissue, and offers a critical research model for in-depth studying the structure-function relationship of bone.
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