Aloe vera mucilage loaded gelatin electrospun fibers contained in polylactic acid coaxial system and polylactic acid and poly(e-caprolactone) tri-layer membranes for tissue engineering

María Mónica Castillo Ortega, Jesús Manuel Quiroz Castillo, Teresa Del Castillo Castro, Dora Evelia Rodriguez Felix, Hisila Del Carmen Santacruz Ortega, Octavio Manero, Karla Alejandra Lopez Gastelum, Lerma Hanaiy Chan Chan, Diego Hernandez Martinez, Jose Agustin Tapia Hernández, Damian Francisco Plascencia Martínez*

*Autor correspondiente de este trabajo

Producción científica: Contribución a una revistaArtículorevisión exhaustiva

1 Cita (Scopus)

Resumen

BACKGROUND: Polymeric electrospun mats have been used as scaffolds in tissue engineering for the development of novel materials due to its characteristics. The usage of synthetic materials has gone in decline due to environmental problems associated with their synthesis and waste disposal. Biomaterials such as biopolymers have been used recently due to good compatibility on biological applications and sustainability. OBJECTIVE: The purpose of this work is to obtain novel materials based on synthetic and natural polymers for applications on tissue engineering. METHODS: Aloe vera mucilage was obtained, chemically characterized, and used as an active compound contained in electrospun mats. Polymeric scaffolds were obtained in single, coaxial and tri-layer structures, characterized and evaluated in cell culture. RESULTS: Mucilage loaded electrospun fibers showed good compatibility due to formation of hydrogen bonds between polymers and biomolecules from its structure, evidenced by FTIR spectra and thermal properties. Cell viability test showed that most of the obtained mats result on viability higher than 75%, resulting in nontoxic materials, ready to be used on scaffolding applications. CONCLUSION: Mucilage containing fibers resulted on materials with potential use on scaffolding applications due to their mechanical performance and cell viability results.

Idioma originalInglés
Páginas (desde-hasta)387-399
Número de páginas13
PublicaciónBio-medical materials and engineering
Volumen35
N.º4
DOI
EstadoPublicada - 12 jul. 2024

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