Atelocollagen-based Hydrogels Crosslinked with Oxidised Polysaccharides as Cell Encapsulation Matrix for Engineered Bioactive Stromal Tissue.
10.1007/s13770-017-0063-0
- Author:
Andreea LUCA
1
;
Maria BUTNARU
;
Sergiu Stelian MAIER
;
Laura KNIELING
;
Ovidiu BREDETEAN
;
Liliana VERESTIUC
;
Daniela Cristina DIMITRIU
;
Marcel POPA
Author Information
1. Department of Natural and Synthetic Polymers, Faculty of Chemical Engineering and Environmental Protection, Gheorghe Asachi University from Iasi, Boulevard Profesor Dimitrie Mangeron 67, 700050 Iasi, Romania.
- Publication Type:Original Article
- Keywords:
Bioactive engineered stroma;
Cell encapsulation;
Oxidised polysaccharides
- MeSH:
Cell Adhesion;
Cell Survival;
Coculture Techniques;
Diffusion;
Extracellular Matrix;
Fibroblasts;
Hydrogel*;
Hydrogels*;
Polysaccharides*;
Regeneration;
Stromal Cells
- From:
Tissue Engineering and Regenerative Medicine
2017;14(5):539-556
- CountryRepublic of Korea
- Language:English
-
Abstract:
Tissue stroma is responsible for extracellular matrix (ECM) formation and secretion of factors that coordinate the behaviour of the surrounding cells through the microenvironment created. It's inability to spontaneously regenerate makes it a good candidate for research studies such as testing various tissue engineered products capable of replacing the stroma in order to assure normal tissue regeneration and function. In this study, a bioactive stroma was obtained considering two main components: 1) the artificial ECM formed using atelocollagen-oxidized polysaccharides hydrogels in which the polysaccharide compound (oxidised gellan or pullulan) has the role of crosslinker and 2) encapsulated stromal cells (dermal fibroblasts, ovarian theca-interstitial and granulosa cells). The cell-hosting ability of the hydrogels is demonstrated by a good diffusion of globular proteins (albumin) while the fibrillar morphology proves to be optimal for cell adhesion. These structural properties and cytocompatibility of the components maintain good cell viability and cell encapsulation for more than 12 days. Nevertheless, the results indicate some differences favouring the gellan crosslinked hydrogels. Ovarian stromal cells functionality was maintained as indicated by hormone secretion, confirming cell-cell signalling in encapsulated and co-culture conditions. In vivo implantation shows the regenerative potential of the cell-populated hydrogels as they are integrated into the natural tissue. The possibility of cryopreserving the hydrogel-cell system, while maintaining both cell viability and hydrogel structural integrity underlines the potential of these ready-to-use hydrogels as bioactive stroma for multipurpose tissue regeneration.