In the last years, a rapid development in production, and functionalization of graphene give rise to several products that have shown great potentials in many fields, such as nanoelectronics, energy technology, sensors, and catalysis. In this context we should not forget the biomedical application of graphene that became a new area with outstanding potential. The first study on graphene for biomedical applications has been performed by Dai in 2008 that reported the use of graphene oxide as an efficient nanocarrier for drug delivery. This pioneristic study opened the doors for the use of graphene in widespread biomedical applications such as drug/gene delivery, biological sensing and imaging, antibacterial materials, but also as biocompatible scaffold for cell culture and tissue engineering. The application of graphene-based scaffolds for tissue engineering applications is confirmed by the many exciting and intriguing literature reports over the last few years, that clearly confirm that graphene and its related substrates are excellent platforms for adhesion, proliferation, and differentiation of various cells such as human Mesenchymal stem cells, human neuronal stem cells, and induced pluripotent stem cells. Since most of the papers on this fields are related to in vitro studies, several future in vivo investigations need to be conducted in order to lead to its utilization as implantable tissue engineering material.
Stem Cells Commitment on Graphene-Based Scaffolds
BUGGIO, MAURIZIO;SIVOLELLA, STEFANO;GARDIN, CHIARA;FERRONI, LETIZIA;ZAVAN, BARBARA
2016
Abstract
In the last years, a rapid development in production, and functionalization of graphene give rise to several products that have shown great potentials in many fields, such as nanoelectronics, energy technology, sensors, and catalysis. In this context we should not forget the biomedical application of graphene that became a new area with outstanding potential. The first study on graphene for biomedical applications has been performed by Dai in 2008 that reported the use of graphene oxide as an efficient nanocarrier for drug delivery. This pioneristic study opened the doors for the use of graphene in widespread biomedical applications such as drug/gene delivery, biological sensing and imaging, antibacterial materials, but also as biocompatible scaffold for cell culture and tissue engineering. The application of graphene-based scaffolds for tissue engineering applications is confirmed by the many exciting and intriguing literature reports over the last few years, that clearly confirm that graphene and its related substrates are excellent platforms for adhesion, proliferation, and differentiation of various cells such as human Mesenchymal stem cells, human neuronal stem cells, and induced pluripotent stem cells. Since most of the papers on this fields are related to in vitro studies, several future in vivo investigations need to be conducted in order to lead to its utilization as implantable tissue engineering material.Pubblicazioni consigliate
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