폴리머 스펀지법을 이용한 다공성 수산화아파타이트 지지체 제조 시 MgO 첨가량에 따른 영향

진형호; 민상호; 이원기; 박홍채; 윤석영; Hyeong-Ho Jin; Sang-Ho Min; Won Ki Lee; Hong-Chae Park; Seog-Young Yoon

Korean Journal of Materials Research, Vol.16, No.11, 715-718, November, 2006

DOI10.3740/MRSK.2006.16.11.715 Export Citation

폴리머 스펀지법을 이용한 다공성 수산화아파타이트 지지체 제조 시 MgO 첨가량에 따른 영향

The Effect of MgO Content on the Preparation of Porous Hydroxyapaite Scaffolds by Polymer Sponge Method

진형호, 민상호, 이원기¹, 박홍채 , 윤석영 ^†

부산대학교 재료공학부
¹부경대학교 응용화학공학부

Hyeong-Ho Jin, Sang-Ho Min, Won Ki Lee¹, Hong-Chae Park , and Seog-Young Yoon^†

School of Materials Science and Engineering, Pusan National University, Busan, 609-735, Korea
¹Division of Applied Chemical Engineering, Pukyong National University, Busan 608-739, Korea

E-mail:

Porous hydroxyapatite (HAp) scaffolds have been prepared by using the slurry including HAp and magnesia based on the replication of polymer sponge substrate. The influence of MgO content in slurry on the pore morphology and size, density, porosity, and mechanical strength of porous HAp scaffolds was investigated. The obtained scaffolds with average pore sizes ranging 150 to 300 mm had open, relatively uniform, and interconnected porous structure regardless of MgO content. As the MgO content increased, the pore network frame of scaffolds became to be relatively stronger, even though the pore size was not much changed. The compressive strength of the scaffolds increased rapidly with the increase of MgO content because of increasing the pore wall thickness and density of the scaffolds. As a result, the porosity, density, and compressive strength of the porous HAp scaffolds prepared by the sponge method were significantly affected by the addition of MgO.

Keywords:Porous;hydroxyapatite;magnesia;scaffold;slurry

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Minuth WW, Sittinger M, Kloth S, Cell Tissue Res., 291, 1 (1998)
Martin RB, Mater. Sci. Forum., 293, 5 (1999)
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Lin Y, Ning XS, Zhou H, Chen K, Peng R, Xu W, Mater. Lett., 57, 15 (2002)
Hulbert SF, Morrison JS, Klawitter JJ, J. Biomed, Mater. Res., 6, 347 (1972)
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Wang J, Lim SY, Ng SC, Chew CH, Gan LM, Mater. Lett., 33, 273 (1998)

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[1] Langer P, Vacanti JP, Science, 260, 920 (1993)

[2] Hubbell JA, Bio-technoI., 13, 565 (1997)

[3] Minuth WW, Sittinger M, Kloth S, Cell Tissue Res., 291, 1 (1998)

[4] Martin RB, Mater. Sci. Forum., 293, 5 (1999)

[5] Nunes CR, Simske SJ, Sachdeva R, Wolford LM, J. Biomed. Mater. Res., 36, 560 (1997)

[6] Sepulveda P, Am. Ceram. Soc. Bull., 76, 61 (1997)

[7] Woyansky JS, Scott CE, Minner WP, Am. Ceram Soc. Bull., 71, 1674 (1992)

[8] Ramay HR, Zhang M, Biomaterials, 24, 3293 (2003)

[9] Cahoon HP, Christensen CJ, J. Am. Ceram. Soc., 39, 337 (1956)

[10] Lee KY, Lee JH, Kim HI, Han KW, Park JM, Mater. Lett., 37, 90 (1998)

[11] Lin Y, Ning XS, Zhou H, Chen K, Peng R, Xu W, Mater. Lett., 57, 15 (2002)

[12] Hulbert SF, Morrison JS, Klawitter JJ, J. Biomed, Mater. Res., 6, 347 (1972)

[13] Flatley TJ, LLynch K, Benson M, Clin. Orthop., 179, 246 (1983)

[14] Kume S, Yasuoka M, Omura N, Watari K, J. Eur. Ceram. Soc., 25, 2791 (2005)

[15] Wang J, Lim SY, Ng SC, Chew CH, Gan LM, Mater. Lett., 33, 273 (1998)