Introduction: Although several types of calcium-phosphate coumpound have been frequently applied to osseous defects at maxillofacial area for many years, there is a controversy about its efficiency on bone conductivity comprared to xenograft bone substitute. Alloplastic carbonapatite has been introduced to improve disadvantages of hydroxyapatite and to mimic natural bone containing carbon elements. However, a preclinical study about its efficiency of osteoconductivity has not been reported. This study was performed to evaluate the early osteoconductive potential of synthetic carbonapatite with multiple pores relative to anorganic bovine xenograft. Materials and methods: Total 5 beagle dogs were used for maxillary augmentation model. The control (anorganic bovine xenograft) and experimental groups (synthetic carbonapatite) were randomly distributed in the mouth split design. After bone graft, all animals were sacrificed 4 weeks after surgery. Histological specimens with Masson Trichrome staining were made and histomorphometrically analysed with image analyser. The statistical analysis was performed using paired t-test. Results: In both groups, all animals had no complications. The experimental group showed relatively much new bone formation around and along the bone substitutes, whereas it was clearly reduced in the control group. The ratios of new bone area to total area, to material area and to the residual area excluding materials were higher in the experimental group ($0.13{\pm}0.03,\;0.40{\pm}0.13,\;0.20{\pm}0.06$ respectively) than in the control group ($0.01{\pm}0.01,\;0.03{\pm}0.02,\;0.03{\pm}0.03$, respectively). And the differences between both groups were statistically significant (p<0.001, <0.01, <0.01, respectively), while the ratio of material area to total area in two groups was not significant. Conclusion: Carbonapatite showed a high osteoconductivity in the early stage of bone healing compared to bovine derived anorganic bone substitute. This study suggests that this bone materials can be applied as a reliable bone substitute in the clinical treatment.

1 "andcharacterization of carbonated apatites" 1982

2 "Xenobone Grafting WithPlatelet-Rich Plasma Gel And Bio-Oss : Radiological InHumans" 24 : 489-, 2002

3 "Tissue reactionand material characteristics of four bone substitutes" 11 : 55-, 1996

4 "The mechanicalproperties and osteoconductivity of hydroxyapatite bonescaffolds with multi-scale porosity" 28 : 45-, 2007

5 "The effects of Bio-Oss.as a scaffolds during sinus bone graft using mesenchymalstem cells in rabbit" 033 : 405-, 2007

6 "Ten-year follow-upin a maxillary sinus augmentation using anorganic bovinebone (Bio-Oss)" 14 : 369-, 2003

7 "Six-year clinicaland histologic study of sinus-lift grafts" 11 : 26-, 1996

8 "SEM and3D synchrotron radiation micro-tomography in the studyof bioceramic scaffolds for tissue-engineering applications" 97 : 638-, 2007

9 "Porous hydroxyap-atite as a bone-graft substitute in metaphyseal defects.Ahistometric study" 904-, 681986

10 "Osteoinduction in porous hydroxyapatiteimplanted in heterotopic sites of different animal models" 17 : 31-, 1996

11 "Novel synthesis and characteriza-tion of an AB-type carbonate-substituted hydroxyapatite" 59 : 697-, 2002

12 "Mediation of boneingrowth in porous hydroxyapatite bone graft substitutes" 68 : 187-, 2004

13 "Mechanicaland bone ingrowth properties of a polymer-coated" 1988

14 "Mechanical characteriza-tion of dense calcium phosphate bioceramics with intercon-nected porosity" 2007

15 "Maxillarysinus augmentation with the xenograft Bio-Oss and auto-genous intraoral bone for qualitative improvement of theimplant site: a histologic and histomorphometric clinicalstudy in humans" 16 : 23-, 2001

16 "Maxillarysinus augmentation using different grafting materials anddental implants in monkeys. Part I. Evaluation of anor-ganic bovine-derived bone matrix" 476-, 1997

17 "Maxillary sinus aug-mentation:histomorphometric analysis of graft materialsfor maxillary sinus floor augmentation" 857-, 511993

18 "Maxillary sinus aug-mentation with bovine bone mineral (bio-oss.) and themaxillary tuberosity" 033 : 391-, 2007

19 "Impact of implantsurface and grafting protocol on clinical outcomes ofendosseous implants" 22 : 399-, 2007

20 "Image Processingwith Image" 11 : 36-, 2004

21 "Histologicalevaluation of Bio-Oss in a 2-stage sinus floor elevation andimplantation procedure. A human case report" 9 : 59-, 91998

22 "Extraction sockets andimplantation of hydroxyapatites with membrane barriers :a histologic study" 13 : 153-, 2004

23 "Evaluation of sinus floor elevation using a composite bonegraft mixture" 18 : 376-, 2007

24 "Effects ofbone ingrowth on the strength and non-invasive assess-ment of a coralline hydroxyapatite material" 10 : 481-, 1989

25 "Differences of osteoconduc-tivity in multi-porous hydroxyapatite with different poreshapes" 34 : 643-, 1999

26 "Deproteinized cancellous bovine bone (Bio-Oss) as bonesubstitute for sinus floor elevation. A retrospective, histo-morphometrical study of five cases" 30 : 261-, 2003

27 "Comparison of min-eralized cancellous bone allograft (Puros) and anorganicbovine bone matrix (Bio-Oss) for sinus augmentation :histomorphometry at 26 to 32 weeks after grafting" 26 : 543-, 2006

28 "Clinical, radi-ographic, and histologic evaluation of human periodontaldefects treated with Bio-Oss and Bio-Gide" 18 : 321-, 1998

29 "Clinical evalua-tion of demineralized bone allograft in a hyaluronic acidcarrier for sinus lift augmentation in humans : a computedtomography and histomorphometric study" 18 : 204-, 2007

30 "Chemical andstructural characterization of the mineral phase from corti-cal and trabecular bone" 68 : 45-, 1997

31 "Bone-grafting materials in implantdentistry" 2 : 158-, 1993

32 "Bone regeneration graft materials" 28 : 290-, 2002

33 "Bone regenera-tion in standardized bone defects with autografts or bonesubstitutes in combination with platelet concentrate: ahistologic and histomorphometric study in the mandibles of탄산아파타이트로 된 인공골과 소뼈에서 유래한 무기질 골의 초기 골전도에 대한 연구" 20 : 703-, 2005

34 "Bone reaction to bovinehydroxyapatite for maxillary sinus floor augmentation:histologic results in humans" 26 : 471-, 2006

35 "Biology of bone grafts" 30 : 543-, 1999

36 "Analysis of performance of root-formendosseous implants placed in the maxillary sinus" 3 : 143-, 1993

37 "Advances in endosseous implants: the ‘sand-wich’split cortical graft for dental implant placement" 11 : 49-, 2000

38 "A method for the study of undecal-cified bones and teeth with attached soft tissues" 1982