Abstract
Tissue engineering has yielded several successes in early clinical trials of regenerative medicine with grafting therapeutic cells seeded into biodegradable scaffolds. However this conventional cell delivery method has limited the field’s progress. In recent decades, we have developed a novel cell transferring method, cell sheet technology that allows for controlled attachment and detachment of cells via simple temperature variations of a surface-intelligent temperatureresponsive polymer:poly (N-isopropylacrylamide). It has been widely applied to create functional tissue sheets with cells derived from various tissues to treat a wide range of diseases. Periodontal cell sheets non-invasively harvested from temperature- responsive culture surfaces have been successfully manufactured, resulting in communicative multilayered constructs. Transplantation of cell sheets onto periodontal defects has improved bone and tissue regeneration in animal models and humans and shows low immunogenicity. In this review, we summarize the recent advances of techniques in cell sheet engineering and its application for periodontal regeneration.
Keywords: Application, cell sheet technology, co-culture, micro-printing, periodontal regeneration, tissue engineering.
Current Stem Cell Research & Therapy
Title:Recent Advances in Cell Sheet Technology for Periodontal Regeneration
Volume: 9 Issue: 3
Author(s): Jing Wang, Rui Zhang, Yun Shen, Chenyuan Xu, Shengcai Qi, Liyan Lu, Raorao Wang and Yuanzhi Xu
Affiliation:
Keywords: Application, cell sheet technology, co-culture, micro-printing, periodontal regeneration, tissue engineering.
Abstract: Tissue engineering has yielded several successes in early clinical trials of regenerative medicine with grafting therapeutic cells seeded into biodegradable scaffolds. However this conventional cell delivery method has limited the field’s progress. In recent decades, we have developed a novel cell transferring method, cell sheet technology that allows for controlled attachment and detachment of cells via simple temperature variations of a surface-intelligent temperatureresponsive polymer:poly (N-isopropylacrylamide). It has been widely applied to create functional tissue sheets with cells derived from various tissues to treat a wide range of diseases. Periodontal cell sheets non-invasively harvested from temperature- responsive culture surfaces have been successfully manufactured, resulting in communicative multilayered constructs. Transplantation of cell sheets onto periodontal defects has improved bone and tissue regeneration in animal models and humans and shows low immunogenicity. In this review, we summarize the recent advances of techniques in cell sheet engineering and its application for periodontal regeneration.
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Cite this article as:
Wang Jing, Zhang Rui, Shen Yun, Xu Chenyuan, Qi Shengcai, Lu Liyan, Wang Raorao and Xu Yuanzhi, Recent Advances in Cell Sheet Technology for Periodontal Regeneration, Current Stem Cell Research & Therapy 2014; 9 (3) . https://dx.doi.org/10.2174/1574888X09666140213150218
DOI https://dx.doi.org/10.2174/1574888X09666140213150218 |
Print ISSN 1574-888X |
Publisher Name Bentham Science Publisher |
Online ISSN 2212-3946 |
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