Apatit - wollastonit biyoaktif seramiklerin üretimi ve karakterizasyonu

AKAO M., Aoki H., Kato K., Mechanical properties of sintered hydroxyapatite for prosthetic applications, J Mater Sci, 16, 809-12, (1981).
ALANYALI H., Biyoaktif Cam Seramikler, Metalurji, 69-74, (1997)
ASTM C373-88 : Standard Test Method for Water Absorption, Bulk Density, Apparent Porosity, and Apparent Specific Gravity of Fired Whiteware Products. ASTM International, West Conchohocken, PA, (2006).
ASTM C773-88 : Standart Test Method for Compressive (Crushing) Strength of Fired Whiteware Materials. ASTM International, West Conchohocken, PA, (2006).
ASTM C1161-02c : Standart Test Method for Flexural Strength of Advaced Ceramics at Ambient Temperature. ASTM International, West Conchohocken, PA, (2008).
ASTM C1198-08 : Standard Test Method for Dynamic Young's Modulus, Shear Modulus, and Poisson's Ratio for Advanced Ceramics by Sonic Resonance. ASTM International, West Conchohocken, PA, (2006).
ASTM F1264-03 : Standart Specification and Test Methods for Intramedullary Fixation Devices. ASTM International, West Conchohocken, PA, (2007).
ASTM C1327-03 : Standard Test Method for Vickers Indentation Hardness of Advanced Ceramics. ASTM International, West Conchohocken, PA, (2008) .
BALAS F., Perez-Pariente J., Vallet-Regi M., In vitro bioactivity of silicon-substituted hydroxyapatites, J Biomed Mater Res A, 66, 364-75, (2003).
BALÇIK C., Tokdemir T., Şenköylü A., Koç N., Timuçin M., Akın S., Korkusuz F., Korkusuz P., Early weight bearing of porous HA/TCP ceramics in vio: A longitudinal study in a segmental bon edefect model of rabbit, Acta Biomaterialia, 3, 985-96, (2007).
BİGİ A., Boanini E., Capuccini C., Gazzano M., Strontium-substituted hydroxyapatite nanocrystals, Inorg Chim Acta, 360, 1009-16, (2007).
BIRKS, A.S., Nondestructive Testing Handbook. Volume 7- Ultrasonic Testing, American Society for Non-Destructive Testing, 2nd Edition, Columbus-Ohio, (1991). Pp:830.
BOTELHO C.M., Lopes M.A., Gibson I.R., Best S.M., Santos J.D., Structural Analysis of Sisubstıtuted Hydroxyapatite : Zeta Potential and X-ray Photelectron Spectroscopy, J Mat Sci: Mat in Med, 13, 1123-27, (2002).
BROW R.K., Tallant D.R., Warren W.L., Mclntyre A., Day D.E., Spectroscopic studies of. The structure of titanophosphate and calcium titanophosphate glasses, Phys Chem Glasses, 38, 300-306, (1997).
CARLISE E.M., Silicon. A Possible Factor in Bone Calcification, Science, New Series, 167, 1, 279-80, (1970).
CHANG C.K., Mao D.L., Wu J.S., Characteristics of crystals precipitated in sintered apatite/wollastonite glass ceramics, Cer Int, .26, 779-85, (2000).
CORRERIA R.N., Magalhaes M.C., Marques P.A.P.P, Senos A.M.R., Wet Synthesis and Characterisation of Modified Hydroxyapatite Powders, J Mat Sci, 7, 501-505, (1996).
DRIESSENS F., Verbeeck R., Biomaterials, Boca Raton: CRC Press, (1990).
EVANS A.G., Fracture Toughness: The Role of Indentation Techniques, Fracture Mechanics Applied to Brittle Materials, ed. Freiman SW., American Society for Testing Materials, Philadelphia, (1979), Pp. 112.
GIBSON I.R., Huang J., Best S.M, Bonfield W., Enhanced in vitro cell activity and surface apatite layer formation on novel silicon-substituted hydroxyapatites, Proceedings of the 12th international symposium on ceramics in medicine, bioceramics 12, ed. Ohgushi H., Hastings GW., Yoshikawa T., Singapore, World Scientific, (1999), Pp. 191.
GIBSON I.R., BEST S.M., Bonfield W., Chemical characterization of silicon-substituted hydroxyapatite, Jour Biomed Mat Res, 44, 422-29, (1999).
GIBSON I.R., Best S.M., Bonfield W., Effect of Silicon Substitution on the Sintering and Microstructure of Hydroxyapatite, J Am Ceram Soc, 85, 2771-77, (2002).
HEIMKE G., Advanced ceramics for biomedical applications, Angew Chem, 28, 111-16, (1989).
HENCH L.L., Wilson J., An Introduction to Bioceramics, Advaced Series in Ceramics – Vol:1, World Scientific, Singapore, (1993), pp: 1-24.
HENCH L.L., Bioceramics, J Am Ceram Soc, 81, 1705-28, (1998).
JAMES P.F., Glass-Ceramics: New Compositions and Uses, J Non-Crys Sol, 181, 1-15, (1995).
JARCHO M., Bolen C.H., Thomas M.B, Bobick J., Kay J.F, Doremus R.H., Hydroxyapatite synthesis and characterization in dense polycrystalline form, J Mat Sci, 11, 2027-35, (1976)
JARCHO M., Calcium phosphate ceramics as hard tissue prosthetics, Clin Orthop, 157, 259- 278, (1981).
KATSUKİ H., S. Furuta S., Komarneni S., Microwave versus Conventional Hydrothermal Synthesis of Hydroxyapatite Crystals from Gypsum, J Am Ceram Soc, 82, 2557-59, (1999).
KİM S.R., Lee J.H., Kim Y.T., Riu D.H., Jung S.J., Lee Y.J., Chung S.C., Kim Y.H., Synthesis of Si, Mg substituted hydroxyapatites and their sintering behaviors, Biomaterials, 24, pp.1389-98, (2003).
KISSINGER H.E., Reaction kinetics in Differential Thermal Analysis, Anal Chem, 29, 1702- 6, (1957).
KİTSUGİ T., Yamamuro T., Nakamura T., Kokubo T., The bonding of Glass- Ceramics to Bone, Int Orthopaedics, 13, 199-206, (1989).
KOÇ N., Timuçin M., Tıp Seramikleri, Tur. Jour. Arthroplasty Arthroscopic Surgery, 10,1, 104-9, (1999).
KOKUBO T., Shigematsu M., Nagashima Y., Tashiro M., Nakamura T., Higashi S.,Apatite and wollastonite containing glass-ceramics for prosthetic application, Bull Inst Chem Res Kyoto Univ, 60, 260-68, (1982).
KOKUBO T., Ito S., Sakka S., Yamamuro T., Formation of a high-strength bioactive glass-ceramic in the system MgO-CaO-SiO2-P2O5, J Mat Sci, 21, 536-40, (1986).
KOKUBO T., Ito S., Shigematsu M., Sakka S., Yamamuro T., Fatigue and Life-Time of Bioactive Glass-Ceramic A-W Containing Apatite and Wollastonite, J Mat Sci, 22, 4067-70, (1987).
KOKUBO T., Ito S., Huang Z. T., Hayashi T., Sakka S., Ca, P-rich Layer Formed on HighStrength Bioactive Glass-Ceramics A-W, J Biomed Mat Res, 24, 331-43, (1990).
KOKUBO T., Bioactive Glass Ceramics: Properties and Applications, Biomaterials, 12, 155-63, (1991).
KOKUBO T., A/W Glass Ceramic: Processing and Properties, AW Glass-Ceramic Development, Characterisation, Modification and Clinical Application, ed: Yamamuro T., Kyoto University, (1994).
KOUDELKA P., Zeyer M., Jager C., Lead borophosphate glasses doped with titanium dioxide, J Non-Cryst Sol, 326-327, 72-76, (2003).
LEE J.H., Lee K.S., Chang J.S., Cho W.S., Kim Y., Kim S.R., Kim Y.T., Biocompatibility of Si substituted Hydroxyapatite, Key Eng Mat, 254-256, 135-38, (2004).
LeGEROS, R.Z., Biological and Synthetic Apatites, Hydroxyapaites and Related Materials, ed: Brown P.W., Constantz B., (1994). Pp: 3-29.
LEVENTOURİ T.H., Bunaciu C.E., Perdikatsis V., Neutron powder diffraction studies of silicon-substituted hydroxyapatite, Biomaterials, 24, 4205-11, (2003).
Lİ Z., Ghosh A., Kobayashi A.S., Bradt R.C., Indentation Fracture Toghness of Sintered Silicon Carbide in the Palmqvist Crack Regime, J Am Ceram Soc, 72, 904-11, (1989).
LİKİTVANİCHKUL S., Lacourse W.C., Apatite-wollastonite glass-ceramics. Part 1 Crystallization kinetics by differential thermal analysis. J Mat Sci, 33, 5901-904, (1998).
LIU D.M., Preparation and Characterisation of Porous Hydroxyapatite Bioceramic via a Slip-Casting Route, Cer Int, 24, 441-46, (1998).
MARTİNEZ, V., Kittl P., Diaz, G., Fracture statistic of torsion and flexure in glass rectangular bars, J Mat Sci , 27, 1457-63, (1992).
METSGER D.S., Rieger M.R., Foreman D.W., Mechanical Properties of sintered hydroxyyapatite and tricalcium phosphate ceramics, J Mat Sci : Mater Med, 10, 9-17, (1999).
NAKAMURA T., Yamamuro T., Higashi S., Kokubo T., Ito S., A New Glass-Ceramic for Bone Replacement: Evaluation of Its Bonding to Bone Tissues, J Biomed Mat Res, 19, 685- 98, (1985).
NİİHARA K., Horena M.R., Hasselman D.Ph., Evaluation of KIC of brittle solids by the indentation method with low crack-to-indent ratio, J Mat Sci Let, 1, pp13-18, (1982).
OVESEN J., Moller-Madsen B., Thomson J.S., Danscher G., Mosekilde L.I., The Positive Effects of Zinc on Skeletal Strength in Growing Rats, Bone, 29, 265-70, (2001).
PAAVOLAINEN P., Slatis P., Karaharju E., Holmstrom T., Studies on mechanical strength of bone. II. Torsional strength of cortical bone after rigid plate fixation with and without compression, Acta Orthop Scan, 49, 506-11, (1978).
PADİLLA S., Román J., Carenas A., Vallet-Regí M., The influence of the phosphorus content on the bioactivity of sol–gel glass ceramics, Biomaterials, 26, 475-83, (2006).
PATEL N., Best S.M., Bonfield W., Gibson I.R., King K.A, Damien E., Revell P.A., A comparative study on the in vivo behavior of hydroxyapatite and silicon substituted hydroxyapatite granules, J Mat Sci, 13, 1199-1206, (2002).
PİETAK A.M., Reid J.W., Stott M.J., Sayer M., Silicon substitution in the calcium phosphate bioceramics, Biomaterials, 28, 4023-32, (2007).
POGREBENKOV V.V., Karlov V.M, Kozik A.V, Vereshchagin V.V., Hydroxyapatite – Wollastonite Bioceramics, Glass and Ceramics, 57, 9-10, (2000).
PORTER A.E., Patel N., Skipper J.N.S., Best S.M., Bonfield W., Comparison of in vivo dissolution processes in hydroxyapatite and silicon substituted-hydroxyapatite bioceramics, Biomaterials, 24, 4609-20, (2003)
RAO R.B., Rao D.K., Veeraiah N., The role of titanium ions on structural, dielectric and optical properties of Li2O-MgO-B2O3 glass system, Mat Chem Phys, 87, 357-69, (2004).
RAY C., Day D.E., Determining the nucleation rate curve for lithium disilicate glass by differential thermal analysis, J Am Ceram Soc, 73, 439-42, (1990).
ROBERTSON D.D., Beck T.J., Chan B.W., Scott W.W., Sharma G.B., Maloney W.J., Torsional strength estimates of femoral diaphyses with endosteal lytic lesions: dual-energy X-ray absorptiometry study, J Orthop Res, 25, 1343-50, (2007).
ROYER A., Viguie J.C., Heughebaert M., Heughabeart J.C., Stroichiometry of hydroxyapatite: influence on the flexural strength, J Mat Sci: Mater Med, 4, 76-82, (1993).
RUYS A., Silicon doped hydroxyapatite, J Aust Ceram Soc, 29, 71-80, (1993).
SANTOS JD., Reis RL., Monteiro FJ, Knowles JC, Hastings GW., Liquid Phase Sintering of Hydroxyapatite by Phosphate and Silicate Glass Additions, J Mat Sci : Mat in Med, 6, 348-52, (1995) .
SHAIM A., Et-tabirou M., Role of titanium in sodium titanophosphate glasses and a model of structural units, Mat Chem Phys, 80, 63-67, (2003).
SUCHANEK W., Yoshimura M., Processing and properties of hydroxyapatite-based biomaterials for use as hard tissue replacement implants, Jour Mat Res, 13, 94-117, (1998).
TANRED DC., McCormack BAO., Carr AJ., A quantitative study of the sintering and mechanical properties of hydroxyapatite/phosphate glass composites, Biomaterials, 19, 1735- 43, (1998).
TANCRED DC., Carr. AJ., McCormack, BAO., The sintering and mechanical behavior of hydroxyapatite with bioglass additions. J Mat Sci, 12, 81-93, (2001).
TAS AC., Korkusuz F., Timucin M., Akkas N., An Investigation of the Chemical Synthesis and High Temperature Sintering Behaviour of Calcium Hydroxyapatite (HA) and Tricalcium Phosphate (TCP) Bioceramics, J Mat Sci: Mater Med, 8, 91-96, (1997).
VALLET-REGİ M., Arcos D., Silicon substituted hydroxyapatites. A method to upgrade calcium phosphate based implants, J Mat Chem, 15, 1509-16, (2005).
WANG C.K., Ju C.P, Chern Lin J.H., Effect of doped bioactive glass on structure and properties of sintered hydroxyapatite, Mat Chem Phys, 53, 138-49, (1998).
WU H.F., Lin C.C., Shen P.Y., Structure and dissolution of CaO-ZrO2-TiO2-Al2O3- B2O3- SiO2 glass(Ⅱ), J Non-Crys Sol, 209, 76-86, (1997).
YAMAMURO T., AW Glass-Ceramic Development, Characterisation, Modification and Clinical Application, Kyoto University, (1994).
YU B., Liang A., Gu S., Influence of different TiO2 content on crystallization of CaO-MgOP2O5-SiO2 system glasses, Mat Let, 56, 539-42, (2002).

APA	TİMUÇİN M, Korkusuz F, ÖZTÜRK A, KORKUSUZ P, DURUCAN C, KOÇ N, PARK J, VAKIFAHMETOĞLU Ç, TAN C (2008). Apatit - wollastonit biyoaktif seramiklerin üretimi ve karakterizasyonu. , 1 - 69.
Chicago	TİMUÇİN Muharrem,Korkusuz Feza,ÖZTÜRK Abdullah,KORKUSUZ PETEK,DURUCAN Caner,KOÇ Nurşen,PARK Jongee,VAKIFAHMETOĞLU Çekdar,TAN Cengiz Apatit - wollastonit biyoaktif seramiklerin üretimi ve karakterizasyonu. (2008): 1 - 69.
MLA	TİMUÇİN Muharrem,Korkusuz Feza,ÖZTÜRK Abdullah,KORKUSUZ PETEK,DURUCAN Caner,KOÇ Nurşen,PARK Jongee,VAKIFAHMETOĞLU Çekdar,TAN Cengiz Apatit - wollastonit biyoaktif seramiklerin üretimi ve karakterizasyonu. , 2008, ss.1 - 69.
AMA	TİMUÇİN M,Korkusuz F,ÖZTÜRK A,KORKUSUZ P,DURUCAN C,KOÇ N,PARK J,VAKIFAHMETOĞLU Ç,TAN C Apatit - wollastonit biyoaktif seramiklerin üretimi ve karakterizasyonu. . 2008; 1 - 69.
Vancouver	TİMUÇİN M,Korkusuz F,ÖZTÜRK A,KORKUSUZ P,DURUCAN C,KOÇ N,PARK J,VAKIFAHMETOĞLU Ç,TAN C Apatit - wollastonit biyoaktif seramiklerin üretimi ve karakterizasyonu. . 2008; 1 - 69.
IEEE	TİMUÇİN M,Korkusuz F,ÖZTÜRK A,KORKUSUZ P,DURUCAN C,KOÇ N,PARK J,VAKIFAHMETOĞLU Ç,TAN C "Apatit - wollastonit biyoaktif seramiklerin üretimi ve karakterizasyonu." , ss.1 - 69, 2008.
ISNAD	TİMUÇİN, Muharrem vd. "Apatit - wollastonit biyoaktif seramiklerin üretimi ve karakterizasyonu". (2008), 1-69.

APA	TİMUÇİN M, Korkusuz F, ÖZTÜRK A, KORKUSUZ P, DURUCAN C, KOÇ N, PARK J, VAKIFAHMETOĞLU Ç, TAN C (2008). Apatit - wollastonit biyoaktif seramiklerin üretimi ve karakterizasyonu. , 1 - 69.
Chicago	TİMUÇİN Muharrem,Korkusuz Feza,ÖZTÜRK Abdullah,KORKUSUZ PETEK,DURUCAN Caner,KOÇ Nurşen,PARK Jongee,VAKIFAHMETOĞLU Çekdar,TAN Cengiz Apatit - wollastonit biyoaktif seramiklerin üretimi ve karakterizasyonu. (2008): 1 - 69.
MLA	TİMUÇİN Muharrem,Korkusuz Feza,ÖZTÜRK Abdullah,KORKUSUZ PETEK,DURUCAN Caner,KOÇ Nurşen,PARK Jongee,VAKIFAHMETOĞLU Çekdar,TAN Cengiz Apatit - wollastonit biyoaktif seramiklerin üretimi ve karakterizasyonu. , 2008, ss.1 - 69.
AMA	TİMUÇİN M,Korkusuz F,ÖZTÜRK A,KORKUSUZ P,DURUCAN C,KOÇ N,PARK J,VAKIFAHMETOĞLU Ç,TAN C Apatit - wollastonit biyoaktif seramiklerin üretimi ve karakterizasyonu. . 2008; 1 - 69.
Vancouver	TİMUÇİN M,Korkusuz F,ÖZTÜRK A,KORKUSUZ P,DURUCAN C,KOÇ N,PARK J,VAKIFAHMETOĞLU Ç,TAN C Apatit - wollastonit biyoaktif seramiklerin üretimi ve karakterizasyonu. . 2008; 1 - 69.
IEEE	TİMUÇİN M,Korkusuz F,ÖZTÜRK A,KORKUSUZ P,DURUCAN C,KOÇ N,PARK J,VAKIFAHMETOĞLU Ç,TAN C "Apatit - wollastonit biyoaktif seramiklerin üretimi ve karakterizasyonu." , ss.1 - 69, 2008.
ISNAD	TİMUÇİN, Muharrem vd. "Apatit - wollastonit biyoaktif seramiklerin üretimi ve karakterizasyonu". (2008), 1-69.