New versatile, elastomeric, degradable polymeric materials for medicine.

The present investigation was focused on the cell compatibility of recently developed biodegradable polyesterurethane-foam (DegraPol-foam) to chondrocytes and osteoblasts. Both chondrocytes and osteoblasts, isolated from adult male rats, exhibited relatively high cell adhesion on DegraPol-foam. Scanning electron microscopy (SEM) showed that cells grew on the surface and into the open cell pores of the foam. Morphologically, cells found on the surface of the foam exhibited a flat cell appearance and built a confluent cell multilayer. In contrast, inside the foams cell showed rounded morphology building cell aggregates and cell islets. In addition, chondrocytes and osteoblasts proliferated on the DegraPol-foam and preserved their phenotype for up to 2 weeks. During degradation of these polymers, small crystalline particles of short-chain poly[(R)-3-hydroxybutyric acid] (Mn approximately 2300) (PHB-P) and lysine methyl ester are released. Therefore, lysine methyl ester and PHB-P, as possible degradation products of the polymer, are investigated here for their effects on macrophages and osteoblasts. Results obtained in the present study clearly indicate that macrophages and, to a lesser degree, osteoblasts have the ability to take up (phagocytose) PHB-P. At low concentrations, particles of PHB failed to induce cytotoxic effects or to activate macrophages. Osteoblasts showed only limited PHB-P phagocytosis and no signs of any cellular damage. At high concentrations of PHB-P, the cell viability of macrophages and to a lesser extent of osteoblasts was affected.

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