Abstract

The biodegradable polymers--polylactic acid (PLA) and polyglycolic acid (PGA)--are currently being studied as carriers for bioactive bone regeneration compounds. The inclusion of osteo-inductive substances in poly-(DL, lactide-co-glycolide) copolymer alloplastic implants has been shown to enhance the repair of osseous defects. The purpose of this study was to examine, by SEM, the attachment relationship of biodegradable polymer implants to cells and tissue matrix. Three groups of copolymer implants were studied: (1) plain 50:50 PLA-PGA copolymer, (2) PLA-PGA copolymer with hydroxyapatite (HA), and (3) PLA-PGA copolymer with autolyzed, antigen-extracted (AA) bone particles. Polymer discs were surgically implanted into the pectoralis muscles of rats. At seven, 14, and 21 days post-implantation, the baskets were removed and the contents prepared for SEM. Results showed that at one week, implants were coated primarily with red and white blood cells in a fibrinoid clot. Degradation of the polymers was evidenced by irregular enlarging of polymer surface pores. At two and three weeks, polymers became lobular and then fibrinoid as degradation progressed. Inflammatory cell and red blood cell adhesions were increasingly replaced by fibroblasts and collagen matrix deposition. As polymer degradation progressed, AA and HA particles were exposed; however, the lack of cell or tissue adhesion in these areas suggests that degradation may be more influenced by the fluid environment than by direct cell attachment. Furthermore, degradation may inhibit direct cell attachment.