Injectable calcium phosphate hydraulic cement (CPHC) used for periodontal tissue regeneration: A study of a dog model.

Injectable calcium phosphate hydraulic cement (CPHC) is a new bone substitute family. This study aimed to evaluate the use of CPHC in surgical periodontitis-simulating defects in a dog model. CPHC was obtained by adding powder mixtures of different calcium phosphates with different solubility. Alveolar bone was removed by drilling over the mesial and distal roots of the 2nd mandibular premolar in six dogs. The defects were randomly selected, three were untreated and six treated. The defects had a depth of 6 mm and a width of 3 mm. The animals were sacrificed after 9 months and samples prepared, with no decalcification, for histological evaluation. Seventy-nine percent of the root was covered by bone in the experimental defects, compared to 41% of the root for the control defects. Bone height was significantly higher for the experimental defects (4.9 +/- 0.9 mm) than for the control defects (1.4 +/- 0.5 mm). After 9 months, 97 +/- 6% of the CPHC was degradated and replaced by bone. This study proves the interest of this cement because of the particularly high level of periodontal bone regeneration. The ability of the cement to be easily injected and shaped in bone defects and the immediate immobilization of the teeth after hardening is notable. (Journal of Applied Biomaterials & Biomechanics 2003; 1: 186-93).

[1]  U. Wikesjö,et al.  Periodontal repair in dogs: evaluation of the natural disease model , 2005 .

[2]  C. Delecourt,et al.  Volume effect on biological properties of a calcium phosphate hydraulic cement: experimental study in sheep. , 1999, Bone.

[3]  D. Cochran,et al.  Comparison of bioactive glass to demineralized freeze-dried bone allograft in the treatment of intrabony defects around implants in the canine mandible. , 1999, Journal of periodontology.

[4]  K. Selvig,et al.  Effect of allogeneic freeze-dried demineralized bone matrix on regeneration of alveolar bone and periodontal attachment in dogs. , 1998, Journal of clinical periodontology.

[5]  S. Lynch,et al.  Clinical, radiographic, and histologic evaluation of human periodontal defects treated with Bio-Oss and Bio-Gide. , 1998, The International journal of periodontics & restorative dentistry.

[6]  G. Pasquier,et al.  Experimental evaluation of a percutaneous injectable biomaterial used in radio-interventional bone-filling procedures , 1998, Journal of materials science. Materials in medicine.

[7]  U. Wikesjö,et al.  Periodontal repair in dogs: effect of recombinant human transforming growth factor-beta1 on guided tissue regeneration. , 1998, Journal of clinical periodontology.

[8]  J. Lemaître,et al.  Biomechanical characterization of a biodegradable calcium phosphate hydraulic cement: a comparison with porous biphasic calcium phosphate ceramics. , 1998, Journal of biomedical materials research.

[9]  P. Schultz,et al.  HRTEM Study of Biological Crystal Growth Mechanisms in the Vicinity of Implanted Synthetic Hydroxyapatite Crystals , 1997, Journal of dental research.

[10]  K. Anselme,et al.  Injectable percutaneous bone biomaterials: an experimental study in a rabbit model , 1996 .

[11]  U. Wikesjö,et al.  Effects of polyglactin mesh combined with resorbable calcium carbonate or replamineform hydroxyapatite on periodontal repair in dogs. , 1996, Journal of clinical periodontology.

[12]  M. Bohner,et al.  Resorption of, and bone formation from, new beta-tricalcium phosphate-monocalcium phosphate cements: an in vivo study. , 1996, Journal of biomedical materials research.

[13]  J. Wozney,et al.  Periodontal repair in dogs: recombinant human bone morphogenetic protein-2 significantly enhances periodontal regeneration. , 1995, Journal of periodontology.

[14]  U. Wikesjö,et al.  Periodontal repair in dogs: space provision by reinforced ePTFE membranes enhances bone and cementum regeneration in large supraalveolar defects. , 1994, Journal of periodontology.

[15]  Y. Bando,et al.  A comparative study of ultrastructures of the interfaces between four kinds of surface-active ceramic and bone. , 1992, Journal of biomedical materials research.

[16]  K. Warrer,et al.  Guided tissue regeneration combined with osseous grafting in suprabony periodontal lesions. An experimental study in the dog. , 1992, Journal of clinical periodontology.

[17]  A. Terano,et al.  An Experimental Study in Dogs , 1990 .

[18]  J. Mellonig,et al.  Comparison of decalcified freeze-dried bone allograft and porous particulate hydroxyapatite in human periodontal osseous defects. , 1989, Journal of periodontology.

[19]  T. West,et al.  Freeze-dried bone and coralline implants compared in the dog. , 1985, Journal of periodontology.

[20]  U. Wikesjö,et al.  Periodontal repair in dogs: effect of allogenic freeze-dried demineralized bone matrix implants on alveolar bone and cementum regeneration. , 1998, Journal of periodontology.

[21]  D. Wood,et al.  Replacement of the rabbit medial meniscus with a polyester-carbon fibre bioprosthesis. , 1990, Biomaterials.