Toward delivery of multiple growth factors in tissue engineering

Abstract Inspired by physiological events that accompany the “wound healing cascade”, the concept of developing a tissue either in vitro or in vivo has led to the integration of a wide variety of growth factors (GFs) in tissue engineering strategies in an effort to mimic the natural microenvironment...

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Bibliographic Details
Published in:Biomaterials 2010-08, Vol.31 (24), p.6279-6308
Main Authors: Chen, Fa-Ming, Zhang, Min, Wu, Zhi-Fen
Format: Article
Language:English
Subjects:
Advanced Basic Science
Animals
Biomaterials
Controlled delivery
Dentistry
Drug delivery system
Drug Delivery Systems - methods
Gene therapy
Gene Transfer Techniques
Humans
Intercellular Signaling Peptides and Proteins - administration & dosage
Intercellular Signaling Peptides and Proteins - therapeutic use
Platelet-Rich Plasma
Platelet-rich plasma (PRP)
Tissue Engineering - methods
Wound healing
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Summary:Abstract Inspired by physiological events that accompany the “wound healing cascade”, the concept of developing a tissue either in vitro or in vivo has led to the integration of a wide variety of growth factors (GFs) in tissue engineering strategies in an effort to mimic the natural microenvironments of tissue formation and repair. Localised delivery of exogenous GFs is believed to be therapeutically effective for replication of cellular components involved in tissue development and the healing process, thus making them important factors for tissue regeneration. However, any treatment aiming to mimic the critical aspects of the natural biological process should not be limited to the provision of a single GF, but rather should release multiple therapeutic agents at an optimised ratio, each at a physiological dose, in a specific spatiotemporal pattern. Despite several obstacles, delivery of more than one GF at rates mimicking an in vivo situation has promising potential for the clinical management of severely diseased tissues. This article summarises the concept of and early approaches toward the delivery of dual or multiple GFs, as well as current efforts to develop sophisticated delivery platforms for this ambitious purpose, with an emphasis on the application of biomaterials-based deployment technologies that allow for controlled spatial presentation and release kinetics of key biological cues. Additionally, the use of platelet-rich plasma or gene therapy is addressed as alternative, easy, cost-effective and controllable strategies for the release of high concentrations of multiple endogenous GFs, followed by an update of the current progress and future directions of research utilising release technologies in tissue engineering and regenerative medicine.
ISSN:0142-9612
1878-5905
DOI:10.1016/j.biomaterials.2010.04.053