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Bone healing capacity of the new fluoridated hydroxyapatite in the rabbit cranium defect
³ë±Ô¼·, ÇѼ¼Áø, ±èöȯ, ±è°æ¿í,
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³ë±Ô¼· ( Rho Kyu-Seop ) - ´Ü±¹´ëÇб³ Ä¡°ú´ëÇÐ ±¸°¾Ç¾È¸é¿Ü°úÇб³½Ç
ÇѼ¼Áø ( Han Se-Jin ) - ´Ü±¹´ëÇб³ Ä¡°ú´ëÇÐ ±¸°¾Ç¾È¸é¿Ü°úÇб³½Ç
±èöȯ ( Kim Cheol-Whan ) - ´Ü±¹´ëÇб³ Ä¡°ú´ëÇÐ ±¸°¾Ç¾È¸é¿Ü°úÇб³½Ç
±è°æ¿í ( Kim Kyung-Wook ) - ´Ü±¹´ëÇб³ Ä¡°ú´ëÇÐ ±¸°¾Ç¾È¸é¿Ü°úÇб³½Ç
KMID : 0355620070330050464
Abstract
The bone graft materials are grossly divided into autogenous bone, allogenic bone, xenogenic bone, and alloplastic material. Among the various allogenic graft materials, hydroxyapatite(Ca10(PO4)6(OH)2, HA), the main inorganic phase of human hard tissue, is widely used as a repair material for bones. When HA applied to bony defect, however, it may be encapsulated with fibrous tissue and floated in the implanted area by the lack of consolidation. Fluoridated hydroxyapatite(Ca10(PO4)6(OH)2, FHA), where F- partially replaces the OH- in the hydroxyapatite, is considered as an alternative material for bone repair due to its solubility and biocompatibility. This study was designed to find out the bone healing capacity of FHA newly produced as a nanoscale fiber in the laboratory. We implanted HA and FHA in the rabbit cranium defect and histologically analysed the specimen. The results were as follows. 1. In the 4 weeks, fibrous connective tissue and little bone formation around materials of the experimental group I implanted HA were observed. In the experimental group II implanted FHA, newly formed bone around materials were observed. 2. In the 8 weeks, the amount of newly formed and matured bone of the experimental group II was more than the experimental group I and control group. From the results obtained, we suggest that FHA, newly synthesized, is relatively favorable bone substitute with bioconpatibility and has better bone healing capacity than pure HA.
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Bone graft;Alloplast;Calvaria
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