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Hydroxyapatite-ceramic for juxta-articular implantation
The histocompatibility of hydroxyapatite-ceramic (HAC) has been proven extensively. For the reconstruction of juxta-articular cancellous bone defects with this synthetic material, the mechanical properties of the HAC--bone regeneration complex needed to be investigated. In order not to alter the spe...
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| Published in: | Journal of materials science. Materials in medicine 1992-09, Vol.3 (5), p.345-351 |
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| Main Authors: | , , , |
| Format: | Article |
| Language: | English |
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| cited_by | cdi_FETCH-LOGICAL-c175t-5b66c0ef788960c49c373408acf07226c82408c15a9a18793fc90b937197df1f3 |
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| cites | cdi_FETCH-LOGICAL-c175t-5b66c0ef788960c49c373408acf07226c82408c15a9a18793fc90b937197df1f3 |
| container_end_page | 351 |
| container_issue | 5 |
| container_start_page | 345 |
| container_title | Journal of materials science. Materials in medicine |
| container_volume | 3 |
| creator | Meenen, N. M. Osborn, J. F. Dallek, M. Donath, K. |
| description | The histocompatibility of hydroxyapatite-ceramic (HAC) has been proven extensively. For the reconstruction of juxta-articular cancellous bone defects with this synthetic material, the mechanical properties of the HAC--bone regeneration complex needed to be investigated. In order not to alter the specific ability of the articular structures to distribute and absorb loading stress, the physiological force-transmitting performance of the subchondral zone must be achieved by filling the defect within HAC. The influence of a physiological load on the remodelling within HAC-filled subchondral bone defects was studied. As orientation is the important factor affecting the physical properties of hard tissue, the morphological aspect of functional adaptation of the hydroxyapatite--bone compound is shown to be determined by the orientation of the bone collagen fibres. By biomechanical methods, the elastic properties of the resulting ceramo-osseous regeneration complex were tested. Reproducible subchondral bone defects were prepared in medical femoral condyles of rabbits, leaving a 0.5 mm coplanar layer of bone and cartilage. The defects were filled with granules of HAC. Polarizing microscopy revealed the dynamical aspect of the bony integration of the material and the remodelling process under physiological locomotion. It showed a rapid ongrowth of collagen fibres on the ceramic surface. By its increasing orientation to domains from woven texture to economical trabecular architecture, the load-bearing facility is documented. Indenting the articular surface on an impressive force testing machine 18 months after HAC implantation proved the equal elastic response of the ceramo-osseous regeneration complex with the overlying structures in comparison with the integrity of not-operated femoral condyles. When integrated by bone, HAC fulfils in the dynamic animal model physiological demands even in large bone defects close to articular surfaces. |
| doi_str_mv | 10.1007/BF00705366 |
| format | article |
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As orientation is the important factor affecting the physical properties of hard tissue, the morphological aspect of functional adaptation of the hydroxyapatite--bone compound is shown to be determined by the orientation of the bone collagen fibres. By biomechanical methods, the elastic properties of the resulting ceramo-osseous regeneration complex were tested. Reproducible subchondral bone defects were prepared in medical femoral condyles of rabbits, leaving a 0.5 mm coplanar layer of bone and cartilage. The defects were filled with granules of HAC. Polarizing microscopy revealed the dynamical aspect of the bony integration of the material and the remodelling process under physiological locomotion. It showed a rapid ongrowth of collagen fibres on the ceramic surface. By its increasing orientation to domains from woven texture to economical trabecular architecture, the load-bearing facility is documented. Indenting the articular surface on an impressive force testing machine 18 months after HAC implantation proved the equal elastic response of the ceramo-osseous regeneration complex with the overlying structures in comparison with the integrity of not-operated femoral condyles. When integrated by bone, HAC fulfils in the dynamic animal model physiological demands even in large bone defects close to articular surfaces.</description><identifier>ISSN: 0957-4530</identifier><identifier>EISSN: 1573-4838</identifier><identifier>DOI: 10.1007/BF00705366</identifier><language>eng</language><ispartof>Journal of materials science. 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Reproducible subchondral bone defects were prepared in medical femoral condyles of rabbits, leaving a 0.5 mm coplanar layer of bone and cartilage. The defects were filled with granules of HAC. Polarizing microscopy revealed the dynamical aspect of the bony integration of the material and the remodelling process under physiological locomotion. It showed a rapid ongrowth of collagen fibres on the ceramic surface. By its increasing orientation to domains from woven texture to economical trabecular architecture, the load-bearing facility is documented. Indenting the articular surface on an impressive force testing machine 18 months after HAC implantation proved the equal elastic response of the ceramo-osseous regeneration complex with the overlying structures in comparison with the integrity of not-operated femoral condyles. 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As orientation is the important factor affecting the physical properties of hard tissue, the morphological aspect of functional adaptation of the hydroxyapatite--bone compound is shown to be determined by the orientation of the bone collagen fibres. By biomechanical methods, the elastic properties of the resulting ceramo-osseous regeneration complex were tested. Reproducible subchondral bone defects were prepared in medical femoral condyles of rabbits, leaving a 0.5 mm coplanar layer of bone and cartilage. The defects were filled with granules of HAC. Polarizing microscopy revealed the dynamical aspect of the bony integration of the material and the remodelling process under physiological locomotion. It showed a rapid ongrowth of collagen fibres on the ceramic surface. By its increasing orientation to domains from woven texture to economical trabecular architecture, the load-bearing facility is documented. Indenting the articular surface on an impressive force testing machine 18 months after HAC implantation proved the equal elastic response of the ceramo-osseous regeneration complex with the overlying structures in comparison with the integrity of not-operated femoral condyles. When integrated by bone, HAC fulfils in the dynamic animal model physiological demands even in large bone defects close to articular surfaces.</abstract><doi>10.1007/BF00705366</doi><tpages>7</tpages></addata></record> |
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| ispartof | Journal of materials science. Materials in medicine, 1992-09, Vol.3 (5), p.345-351 |
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| title | Hydroxyapatite-ceramic for juxta-articular implantation |
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