Please use this identifier to cite or link to this item: http://hdl.handle.net/1822/42486

TitleEngineering enriched microenvironments with gradients of platelet lysate in hydrogel fibers
Author(s)Santo, Vítor Sérgio Soares Espírito
Babo, Pedro Miguel Sousa
Amador, Miguel
Correia, Cláudia
Cunha, Bárbara
Coutinho, Daniela F.
Neves, N. M.
Mano, J. F.
Reis, R. L.
Gomes, Manuela E.
KeywordsInjectable systems
Microfluidics
Photocrosslinkable hydrogels
Smart biomaterials
Tissue engineering
Vascularization
Issue dateMay-2016
PublisherAmerican Chemical Society
JournalBiomacromolecules
CitationSanto V. E., Babo P. S., Amador M., Correia C., Cunha B., Coutinho D. F., Neves N. M., Mano J. F., Reis R. L., Gomes M. E. Engineering enriched microenvironments with gradients of platelet lysate in hydrogel fibers, Biomacromolecules, Vol. 17, Issue 6, pp. 1985−1997, doi:10.1021/acs.biomac.6b00150, 2016
Abstract(s)Gradients of physical and chemical cues are characteristic of specific tissue microenvironments and contribute toward morphogenesis and tissue regeneration upon injury. Recent advances on microfluidics and hydrogel manipulation raised the possibility of generating biomimetic biomaterials enriched with bioactive factors and encapsulating cells following designs specifically tailored for a target application. The novelty of this work relies on the combination of methacrylated gellan gum (MeGG) with platelet lysate (PL), aiming to generate novel advanced 3D PL-enriched photo-cross-linkable hydrogels and overcoming the lack of adhesion sites provided by the native MeGG hydrogels. This combination takes advantage of the availability, enriched growth factor composition, and potential autologous application of PL while simultaneously preserving the ability provided by MeGG to tailor mechanical properties, protein release kinetics, and shape of the construct according to the desired goal. Incorporation of PL in the hydrogels significantly improved cellular adhesion and viability in the constructs. The use of microfluidic tools allowed the design of a fiber-like hydrogel incorporating a gradient of PL along the length of the fiber. These spatial protein gradients led to the viability and cell number gradients caused by maintenance of human umbilical vein endothelial cells (HUVECs) survival in the fibers toward the PL-enriched sections in comparison with the nonloaded MeGG sections of the fibers. Altogether, we propose a proof of concept strategy to design a PL gradient biomaterial with potential in tissue engineering approaches and analysis of cell-microenvironment interactions.
TypeArticle
URIhttp://hdl.handle.net/1822/42486
DOI10.1021/acs.biomac.6b00150
ISSN1526-4602
Publisher versionhttp://www.ncbi.nlm.nih.gov/pubmed/27203709
Peer-Reviewedyes
AccessRestricted access (Author)
Appears in Collections:3B’s - Artigos em revistas/Papers in scientific journals


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