A novel gene-activated matrix composed of PEI/plasmid-BMP2 complexes and hydroxyapatite/chitosan-microspheres promotes bone regeneration

A novel gene-activated matrix composed of PEI/plasmid-BMP2 complexes and hydroxyapatite/chitosan-microspheres promotes bone regeneration

The incorporation of pro-osteogenic growth factors into bone graft materials to enhance bone regeneration is a key research area within the field of bone tissue engineering and regenerative medicine. However, growth factors directly incorporated in protein form are easily degraded, and have a limite...

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Main Authors: Ding, Ruyuan, Liu, Yajun, Cheng, Dawei, Yang, Gang, Wu, Wenjing, Du, Haoran, Jin, Xin, Chen, Yihan, Wang, Yuanyin, Heng, Boon Chin *, Xu, Jianguang
Format: Article
Published: Springer 2022
Subjects:
QH Natural history
QR Microbiology
RD Surgery
Online Access:http://eprints.sunway.edu.my/3114/
https://link.springer.com/article/10.1007/s12274-022-4292-8
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Institution: Sunway University
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spelling my.sunway.eprints.31142024-08-13T05:59:57Z http://eprints.sunway.edu.my/3114/ A novel gene-activated matrix composed of PEI/plasmid-BMP2 complexes and hydroxyapatite/chitosan-microspheres promotes bone regeneration Ding, Ruyuan Liu, Yajun Cheng, Dawei Yang, Gang Wu, Wenjing Du, Haoran Jin, Xin Chen, Yihan Wang, Yuanyin Heng, Boon Chin * Xu, Jianguang QH Natural history QR Microbiology RD Surgery The incorporation of pro-osteogenic growth factors into bone graft materials to enhance bone regeneration is a key research area within the field of bone tissue engineering and regenerative medicine. However, growth factors directly incorporated in protein form are easily degraded, and have a limited active half-life, which cannot exert long-term and stable osteoinductive and oteoconductive effects. The combination of gene therapy and tissue engineering through gene-activated matrix (GAM) may provide a good alternative solution to overcome such limitations. Scaffold materials can be combined together with plasmid DNA and a chemical-based transfection agent to form GAM, through which transfected cells could secrete growth factors in a sustained manner over a longer time duration; thereby enabling bone graft materials to act as a repository of therapeutic genes, while providing structural support and a scaffold matrix for new bone tissue ingrowth. In this study, we prepared hydroxyapatite/chitosan-microspheres (HA/CS-MS) with microfabrication technology and emulsification method, and loaded the polyethylene imine/bone morphogenetic protein 2 plasmid (PEI/pBMP2) complexes with high transfection capacity (transfection efficiency up to 54.79% ± 4.95%), thus forming a novel GAM system with superior bone regeneration capacity—PEI/pBMP2-HA/CS-MS. The in vitro experiments in this study demonstrated that our GAM had excellent biocompatibility (with cell viability over 95%), and that the as-fabricated microsphere material possessed a nano-network fibrous structure similar to natural extracellular matrix (ECM), together with a higher surface area that can provide more cell adhesion sites. The sizes of the prepared microspheres were mainly distributed in the 160–180 µm range, while the maximal loading rate of PEI-pBMP2 complexes was 59.79% ± 1.85%. As a loaded complexes system, the GAM can release plasmids in a slow controlled manner, effectively transfecting surrounding target cells (release effect for up to 21 days), while cells adherent to the material can also take up plasmids, resulting in sustained secretion of the target protein, thereby effectively promoting bone regeneration. In vivo data from micro-computed tomography (micro-CT) and histological staining showed that the use of the composite materials effectively enhanced bone regeneration in defect areas. These findings thus demonstrated that the novel GAM system had excellent osteoinductivity with significant clinical potential. Springer 2022 Article PeerReviewed Ding, Ruyuan and Liu, Yajun and Cheng, Dawei and Yang, Gang and Wu, Wenjing and Du, Haoran and Jin, Xin and Chen, Yihan and Wang, Yuanyin and Heng, Boon Chin * and Xu, Jianguang (2022) A novel gene-activated matrix composed of PEI/plasmid-BMP2 complexes and hydroxyapatite/chitosan-microspheres promotes bone regeneration. Nano Research, 15. pp. 6348-6360. ISSN 1998-0000 https://link.springer.com/article/10.1007/s12274-022-4292-8 10.1007/s12274-022-4292-8
institution Sunway University
building Sunway Campus Library
collection Institutional Repository
continent Asia
country Malaysia
content_provider Sunway University
content_source Sunway Institutional Repository
url_provider http://eprints.sunway.edu.my/
topic QH Natural history
QR Microbiology
RD Surgery
spellingShingle QH Natural history
QR Microbiology
RD Surgery
Ding, Ruyuan
Liu, Yajun
Cheng, Dawei
Yang, Gang
Wu, Wenjing
Du, Haoran
Jin, Xin
Chen, Yihan
Wang, Yuanyin
Heng, Boon Chin *
Xu, Jianguang
A novel gene-activated matrix composed of PEI/plasmid-BMP2 complexes and hydroxyapatite/chitosan-microspheres promotes bone regeneration
description The incorporation of pro-osteogenic growth factors into bone graft materials to enhance bone regeneration is a key research area within the field of bone tissue engineering and regenerative medicine. However, growth factors directly incorporated in protein form are easily degraded, and have a limited active half-life, which cannot exert long-term and stable osteoinductive and oteoconductive effects. The combination of gene therapy and tissue engineering through gene-activated matrix (GAM) may provide a good alternative solution to overcome such limitations. Scaffold materials can be combined together with plasmid DNA and a chemical-based transfection agent to form GAM, through which transfected cells could secrete growth factors in a sustained manner over a longer time duration; thereby enabling bone graft materials to act as a repository of therapeutic genes, while providing structural support and a scaffold matrix for new bone tissue ingrowth. In this study, we prepared hydroxyapatite/chitosan-microspheres (HA/CS-MS) with microfabrication technology and emulsification method, and loaded the polyethylene imine/bone morphogenetic protein 2 plasmid (PEI/pBMP2) complexes with high transfection capacity (transfection efficiency up to 54.79% ± 4.95%), thus forming a novel GAM system with superior bone regeneration capacity—PEI/pBMP2-HA/CS-MS. The in vitro experiments in this study demonstrated that our GAM had excellent biocompatibility (with cell viability over 95%), and that the as-fabricated microsphere material possessed a nano-network fibrous structure similar to natural extracellular matrix (ECM), together with a higher surface area that can provide more cell adhesion sites. The sizes of the prepared microspheres were mainly distributed in the 160–180 µm range, while the maximal loading rate of PEI-pBMP2 complexes was 59.79% ± 1.85%. As a loaded complexes system, the GAM can release plasmids in a slow controlled manner, effectively transfecting surrounding target cells (release effect for up to 21 days), while cells adherent to the material can also take up plasmids, resulting in sustained secretion of the target protein, thereby effectively promoting bone regeneration. In vivo data from micro-computed tomography (micro-CT) and histological staining showed that the use of the composite materials effectively enhanced bone regeneration in defect areas. These findings thus demonstrated that the novel GAM system had excellent osteoinductivity with significant clinical potential.
format Article
author Ding, Ruyuan
Liu, Yajun
Cheng, Dawei
Yang, Gang
Wu, Wenjing
Du, Haoran
Jin, Xin
Chen, Yihan
Wang, Yuanyin
Heng, Boon Chin *
Xu, Jianguang
author_facet Ding, Ruyuan
Liu, Yajun
Cheng, Dawei
Yang, Gang
Wu, Wenjing
Du, Haoran
Jin, Xin
Chen, Yihan
Wang, Yuanyin
Heng, Boon Chin *
Xu, Jianguang
author_sort Ding, Ruyuan
title A novel gene-activated matrix composed of PEI/plasmid-BMP2 complexes and hydroxyapatite/chitosan-microspheres promotes bone regeneration
title_short A novel gene-activated matrix composed of PEI/plasmid-BMP2 complexes and hydroxyapatite/chitosan-microspheres promotes bone regeneration
title_full A novel gene-activated matrix composed of PEI/plasmid-BMP2 complexes and hydroxyapatite/chitosan-microspheres promotes bone regeneration
title_fullStr A novel gene-activated matrix composed of PEI/plasmid-BMP2 complexes and hydroxyapatite/chitosan-microspheres promotes bone regeneration
title_full_unstemmed A novel gene-activated matrix composed of PEI/plasmid-BMP2 complexes and hydroxyapatite/chitosan-microspheres promotes bone regeneration
title_sort novel gene-activated matrix composed of pei/plasmid-bmp2 complexes and hydroxyapatite/chitosan-microspheres promotes bone regeneration
publisher Springer
publishDate 2022
url http://eprints.sunway.edu.my/3114/
https://link.springer.com/article/10.1007/s12274-022-4292-8
_version_ 1808975643851882496

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