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Engineered Tissue Interfaces for in vitro and in vivo Bioengineering
Link to bioRxiv paper:
http://biorxiv.org/cgi/content/short/2020.11.06.371278v1?rss=1
Authors: Hickey, R. J., Leblanc Latour, M., Harden, J. L., Pelling, A.
Abstract:
In regenerative medicine, the healing of the interfacial zone between tissues is a major challenge, yet approaches for engineering and studying the complex microenvironment of this interface remain lacking. Here, we create and study these complex living interfaces by manufacturing modular "blocks" of decellularized plant-derived scaffolds with varying shapes and sizes with a computer numerical controlled mill. Each block can then be seeded with different cell types and easily assembled in a manner akin to LEGO bricks to create an engineered tissue interface (ETI). As a proof-of-concept study we utilize ETIs to investigate the interaction between lab grown bone and connective tissues. We also demonstrate how ETIs are biocompatible in vivo, stimulating the formation of blood vessels, cell infiltration, and tissue integration after implantation. This work creates possibilities for new tissue design avenues for understanding fundamental biological processes or the development of synthetic artificial tissues.
Copy rights belong to original authors. Visit the link for more info
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By Multimodal LLCLink to bioRxiv paper:
http://biorxiv.org/cgi/content/short/2020.11.06.371278v1?rss=1
Authors: Hickey, R. J., Leblanc Latour, M., Harden, J. L., Pelling, A.
Abstract:
In regenerative medicine, the healing of the interfacial zone between tissues is a major challenge, yet approaches for engineering and studying the complex microenvironment of this interface remain lacking. Here, we create and study these complex living interfaces by manufacturing modular "blocks" of decellularized plant-derived scaffolds with varying shapes and sizes with a computer numerical controlled mill. Each block can then be seeded with different cell types and easily assembled in a manner akin to LEGO bricks to create an engineered tissue interface (ETI). As a proof-of-concept study we utilize ETIs to investigate the interaction between lab grown bone and connective tissues. We also demonstrate how ETIs are biocompatible in vivo, stimulating the formation of blood vessels, cell infiltration, and tissue integration after implantation. This work creates possibilities for new tissue design avenues for understanding fundamental biological processes or the development of synthetic artificial tissues.
Copy rights belong to original authors. Visit the link for more info