Biomimetic bilayer scaffold from Bombyx mori silk materials for small diameter vascular applications in tissue engineering

Gaviria Castrillon, Ana M.; Wray, Sandra; Rodríguez, Aníbal; Díaz Fajardo, Sahara; Machain, Victoria Alejandra; Parisi, Julieta Marcia; Bosio, Gabriela Natalia; Kaplan, David L.; Restrepo Osorio, Adriana; Bosio, Valeria Elizabeth

doi:10.1002/jbm.a.37789

Artículo

Biomimetic bilayer scaffold from Bombyx mori silk materials for small diameter vascular applications in tissue engineering

Gaviria Castrillon, Ana M.; Wray, Sandra; Rodríguez, Aníbal; Díaz Fajardo, Sahara; Machain, Victoria Alejandra; Parisi, Julieta Marcia; Bosio, Gabriela Natalia Icon

; Kaplan, David L.; Restrepo Osorio, Adriana; Bosio, Valeria Elizabeth Icon

Fecha de publicación: 08/2024

Editorial: Wiley-liss, div John Wiley & Sons Inc.

Revista: Journal of Biomedical Materials Research Part A

ISSN: 1549-3296

Idioma: Inglés

Tipo de recurso: Artículo publicado

Clasificación temática:

Tecnologías que involucran la manipulación de células, tejidos, órganos o todo el organismo

Resumen

Enhancing the biocompatibility and mechanical stability of small diameter vascularscaffolds remain significant challenges. To address this challenge, small-diametertubular structures were electrospun from silk fibroin (SF) from silk textile industry dis-carded materials to generate bilayer scaffolds that mimic native blood vessels, butderived from a sustainable natural material resource. The inner layer was obtained bydirectly dissolving SF in formic acid, while the middle layer (SF-M) was achievedthrough aqueous concentration of the protein. Structural and biological properties ofeach layer as well as the bilayer were evaluated. The inner layer exhibited nano-scalefiber diameters and 57.9% crystallinity, and degradation rates comparable with theSF-M layer. The middle layer displayed micrometer-scale fibers diameters with anultimate extension of about 274%. Both layers presented contact angles suitable forcell growth and cytocompatibility, while the bilayer material displayed an intermedi-ate mechanical response and a reduced enzymatic degradation rate when comparedto each individual layer. The bilayer material emulates many of the characteristics ofnative small-diameter vessels, thereby suggesting further studies towards in vivo opportunities.

Palabras clave: BIOMIMETIC , SILK FOBROIN , VASCULAR SCAFFOLDS , TISSUE ENGEENIRING

Ver el registro completo

Archivos asociados

Tamaño: 4.102Mb

Formato: PDF

Solicitar

Licencia

Excepto donde se diga explícitamente, este item se publica bajo la siguiente descripción: Creative Commons Attribution-NonCommercial-ShareAlike 2.5 Unported (CC BY-NC-SA 2.5)

Identificadores

URI: http://hdl.handle.net/11336/266991

URL: https://onlinelibrary.wiley.com/doi/10.1002/jbm.a.37789

DOI: http://dx.doi.org/10.1002/jbm.a.37789

Colecciones

Articulos(IFLP)
Articulos de INST.DE FISICA LA PLATA

Articulos(INIFTA)
Articulos de INST.DE INV.FISICOQUIMICAS TEORICAS Y APLIC.

Citación

Gaviria Castrillon, Ana M.; Wray, Sandra; Rodríguez, Aníbal; Díaz Fajardo, Sahara; Machain, Victoria Alejandra; et al.; Biomimetic bilayer scaffold from Bombyx mori silk materials for small diameter vascular applications in tissue engineering; Wiley-liss, div John Wiley & Sons Inc.; Journal of Biomedical Materials Research Part A; 113; 1; 8-2024; 1-12

Altmétricas