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Histomorphological, histomorphometrical and biomechanical analysis of ceramic bone substitutes in a weight-bearing animal model

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Abstract

It was the purpose of this investigation to prove the biomechanical properties, the osteoconductive capacity and the degradation rate of α tricalcium phosphate (α TCP), a neutralized glass ceramics (GB9N) and a composite material (GB9N+copolymers). In a weight-bearing animal model six substitutes each were implanted in the medial tibial head of the right lower leg of adult Merino-sheep in a standardized surgical technique. After nine months the implants were harvested and prepared for histomorphological and histomorphometrical investigations (undecalcified Masson Goldner staining). For additional biomechanical testing of the specimens, non-operated bone blocks from the contralateral tibia as well as native implants served as controls. No significant differences for the maximum fracture load as well as for the yield strength were detected between harvested specimens and bone blocks from the contralateral tibia. However there were marked differences to ceramics that were not implanted. All substitutes showed osteoconduction, leading to a continuous ingrowth of new formed bone. However in the composite material soft tissue could be identified within the scaffold and there were signs of ongoing bone remodeling, nine months after implantation. The bone per tissue volume of α-TCP in conjunction to new bone (=percentage of trabecular bone volume plus percentage of residual substitute) was higher than for GB9N and the composite material. Nine months after implantation the percentage of residual α-TCP was 48%, it was 32% for GB9N and 28% for the composite.

The intention of further studies should be to accelerate the degradation rates of substitutes and to improve biomechanical properties of implants by either modifying the chemical composition or combining materials with agents as, e.g. growth factors.

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Authors and Affiliations

  1. Orthopaedic Department (RKU), University of Ulm, Oberer Eselsberg 45, 89081, Ulm

    S. Kessler, U. Mayr-Wohlfart, W. Puhl & K. P. Günther

  2. Institute of Orthopaedic Research and Biomechanics, University of Ulm, Germany

    A. Ignatius & L. Claes

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  1. S. Kessler
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  2. U. Mayr-Wohlfart
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  3. A. Ignatius
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  4. W. Puhl
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  5. L. Claes
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Kessler, S., Mayr-Wohlfart, U., Ignatius, A. et al. Histomorphological, histomorphometrical and biomechanical analysis of ceramic bone substitutes in a weight-bearing animal model. Journal of Materials Science: Materials in Medicine 13, 191–195 (2002). https://doi.org/10.1023/A:1013886130805

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