Abstract
Two types of cellulose-based materials, 6-carboxycellulose with 2.1 or 6.6 wt% of –COOH groups, were prepared and tested for potential use in tissue engineering. The materials were functionalized with arginine, i.e. an amino acid with a basic side chain, or with chitosan, in order to balance the relatively acid character of oxidized cellulose molecules, and were seeded with vascular smooth muscle cells (VSMC). The cell adhesion and growth were then evaluated directly on the materials, and also on the underlying polystyrene culture dishes. Of these two types of studied materials, 6-carboxycellulose with 2.1 wt% of –COOH groups was more appropriate for cell colonization. The cells on this material achieved an elongated shape, while they were spherical in shape on the other materials. The number of cells and the concentration (per mg of protein) of contractile proteins alpha-actin and SM1 and SM2 myosins, i.e. markers of the phenotypic maturation of VSMC, were also significantly higher on this material. Functionalization of the material with arginine and chitosan further improved the phenotypic maturation of VSMC. Chitosan also improved the adhesion and growth of these cells. In comparison with the control polystyrene dishes, the proliferation of cells on our cellulose-based materials was relatively low. This suggests that these materials can be used in applications where high proliferation activity of cells is not desirable, e.g. proliferation of VSMC on vascular prostheses. Alternatively, the cell proliferation might be enhanced by another more efficient modification, which would require further research.
Highlights
Cellulose is a polysaccharide consisting of a linear chain of several hundred to over ten thousand b(1 ? 4) linked D-glucose units
Tubes 4 mm in diameter made of bacterial cellulose showed compliance similar to that of human saphenous vein and higher than expanded polytetrafluorethylene and polyethylene terephthalate (PET), i.e. synthetic polymers currently used for fabricating vascular replacements
We investigate the adhesion, growth and phenotypic maturation of vascular smooth muscle cells (VSMC) on two types of cellulose materials for potential use in soft tissue engineering: oxidized 6-carboxycellulose with 2.1 wt% of –COOH groups (2.1) and oxidized 6-carboxycellulose with 6.6 wt% of –COOH groups (6.6)
Summary
Cellulose is a polysaccharide consisting of a linear chain of several hundred to over ten thousand b(1 ? 4) linked D-glucose units. Bacterial cellulose is identical to plant cellulose in chemical structure, but it can be produced without contaminant molecules, such as lignin and hemicelluloses, and does not require intensive purification processes It is remarkable for its mechanical strength and biocompatibility, so it has often been applied in tissue engineering (Petersen and Gatenholm 2011). Cellulose oxidation induces conversion of the glucose residues to glucuronic acid residues containing –COOH groups The concentration of these groups modulates the degradation time of cellulose, and its pH, its swelling in a water environment, mechanical stability, drug loading efficiency and other behavior of the material (Zhu et al 2001). Cellulose-based materials (listed above) in the form of woven fibrous scaffolds were exposed to solutions of arginine or chitosan (USA, Sigma-Aldrich) for 2 h at room temperature (20 °C). The pH was examined using an Orion Star A211 pH meter
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