Science and Technology of Advanced Materials (Dec 2023)

Optimizing the biodegradability and osteogenesis of biogenic collagen membrane via fluoride-modified polymer-induced liquid precursor process

  • Xiyan Li,
  • Chuangji Li,
  • Mengxi Su,
  • Xinyi Zhong,
  • Yihan Xing,
  • Zhengjie Shan,
  • Shoucheng Chen,
  • Xingchen Liu,
  • Xiayi Wu,
  • Quan Liu,
  • Ye Li,
  • Shiyu Wu,
  • Zhuofan Chen

DOI
https://doi.org/10.1080/14686996.2023.2186690
Journal volume & issue
Vol. 24, no. 1

Abstract

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ABSTRACTBiogenic collagen membranes (BCM) have been widely used in guided bone regeneration (GBR) owing to their biodegradability during tissue integration. However, their relatively high degradation rate and lack of pro-osteogenic properties limit their clinical outcomes. It is of great importance to endow BCM with tailored degradation as well as pro-osteogenic properties. In this study, a fluoride-modified polymer-induced liquid precursor (PILP) based biomineralization strategy was used to convert the collagen membrane from an organic phase to an apatite-based inorganic phase, thus achieving enhanced anti-degradation performance as well as osteogenesis. As a result, three phases of collagen membranes were prepared. The original BCM in the organic phase induced the mildest inflammatory response and was mostly degraded after 4 weeks. The organic-inorganic mixture phase of the collagen membrane evoked a prominent inflammatory response owing to the fluoride-containing amorphous calcium phosphate (F-ACP) nanoparticles, resulting in active angiogenesis and fibrous encapsulation, whereas the inorganic phase induced a mild inflammatory response and degraded the least owing to the transition of F-ACP particles into calcium phosphate with high crystallinity. Effective control of ACP is key to building novel apatite-based barrier membranes. The current results may pave the way for the development of advanced apatite-based membranes with enhanced barrier performances.

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