A 3D-bioprinted scaffold with doxycycline-controlled BMP2-expressing cells for inducing bone regeneration and inhibiting bacterial infection

A 3D-bioprinted scaffold with doxycycline-controlled BMP2-expressing cells for inducing bone regeneration and inhibiting bacterial infection

Large bone defects face a high risk of pathogen exposure due to open wounds, which leads to high infection rates and delayed bone union. To promote successful repair of infectious bone defects, fabrication of a scaffold with dual functions of osteo-induction and bacterial inhibition is required. Thi...

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Bibliographic Details
Published in:Bioactive materials Vol. 6; no. 5; pp. 1318 - 1329
Main Authors: Wang, Minqi, Li, Hanjun, Yang, Yiqi, Yuan, Kai, Zhou, Feng, Liu, Haibei, Zhou, Qinghui, Yang, Shengbing, Tang, Tingting
Format: Journal Article
Language:English
Published: Elsevier B.V 01-05-2021
KeAi Publishing
KeAi Communications Co., Ltd
Subjects:
3D bioprinting
Antibacterial activity
Bone repair
Genetic engineering
Infectious bone defect
Bone repair
Antibacterial activity
3D bioprinting
Genetic engineering
Infectious bone defect
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Summary:Large bone defects face a high risk of pathogen exposure due to open wounds, which leads to high infection rates and delayed bone union. To promote successful repair of infectious bone defects, fabrication of a scaffold with dual functions of osteo-induction and bacterial inhibition is required. This study describes creation of an engineered progenitor cell line (C3H10T1/2) capable of doxycycline (DOX)-mediated release of bone morphogenetic protein-2 (BMP2). Three-dimensional bioprinting technology enabled creation of scaffolds, comprising polycaprolactone/mesoporous bioactive glass/DOX and bioink, containing these engineered cells. In vivo and in vitro experiments confirmed that the scaffold could actively secrete BMP2 to significantly promote osteoblast differentiation and induce ectopic bone formation. Additionally, the scaffold exhibited broad-spectrum antibacterial capacity, thereby ensuring the survival of embedded engineered cells when facing high risk of infection. These findings demonstrated the efficacy of this bioprinted scaffold to release BMP2 in a controlled manner and prevent the occurrence of infection; thus, showing its potential for repairing infectious bone defects. [Display omitted] •Genetic engineering and 3D bioprinting.•Dual-functional.•Suitable for infectious bone defect repair.
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Minqi Wang and Hanjun Li contributed equally to this work.
ISSN:2452-199X
2452-199X
DOI:10.1016/j.bioactmat.2020.10.022