Strength and fatigue properties of three-step sintered dense nanocrystal hydroxyapatite bioceramics

doi:10.1007/s11706-013-0205-9

PDF(298 KB)

Front. Mater. Sci. ›› 2013, Vol. 7 ›› Issue (2) : 190-195. DOI: 10.1007/s11706-013-0205-9

COMMUNICATION

Strength and fatigue properties of three-step sintered dense nanocrystal hydroxyapatite bioceramics

Wen-Guang GUO^1,2, Zhi-Ye QIU¹, Han CUI², Chang-Ming WANG², Xiao-Jun ZHANG², In-Seop LEE³, Yu-Qi DONG⁴(), Fu-Zhai CUI¹()

Author information +

History +

Abstract

Dense hydroxyapatite (HA) ceramic is a promising material for hard tissue repair due to its unique physical properties and biologic properties. However, the brittleness and low compressive strength of traditional HA ceramics limited their applications, because previous sintering methods produced HA ceramics with crystal sizes greater than nanometer range. In this study, nano-sized HA powder was employed to fabricate dense nanocrystal HA ceramic by high pressure molding, and followed by a three-step sintering process. The phase composition, microstructure, crystal dimension and crystal shape of the sintered ceramic were examined by X-ray diffraction (XRD) and scanning electron microscopy (SEM). Mechanical properties of the HA ceramic were tested, and cytocompatibility was evaluated. The phase of the sintered ceramic was pure HA, and the crystal size was about 200 nm. The compressive strength and elastic modulus of the HA ceramic were comparable to human cortical bone, especially the good fatigue strength overcame brittleness of traditional sintered HA ceramics. Cell attachment experiment also demonstrated that the ceramics had a good cytocompatibility.

Keywords

nanocrystal hydroxyapatite ceramic / three-step sintering / mechanical property / fatigue strength / cytocompatibility

Cite this article

EndNote

Ris (Procite)

Bibtex

Download citation ▾

Wen-Guang GUO, Zhi-Ye QIU, Han CUI, Chang-Ming WANG, Xiao-Jun ZHANG, In-Seop LEE, Yu-Qi DONG, Fu-Zhai CUI. Strength and fatigue properties of three-step sintered dense nanocrystal hydroxyapatite bioceramics. Front Mater Sci, 2013, 7(2): 190‒195 https://doi.org/10.1007/s11706-013-0205-9

References

[1] Guo X, Xiao P, Liu J, . Fabrication of nanostructured hydroxyapatite via hydrothermal synthesis and spark plasma sintering. Journal of the American Ceramic Society , 2005, 88(4): 1026-1029
[2] Chen I W, Wang X H. Sintering dense nanocrystalline ceramics without final-stage grain growth. Nature , 2000, 404(6774): 168-171
[3] Zhao H S, Wang G C, Hu S P, . In vitro biomimetic construction of hydroxyapatite-porcine acellular dermal matrix composite scaffold for MC3T3-E1 preosteoblast culture. Tissue Engineering Part A , 2011, 17(5-6): 765-776
[4] Sadighpour L, Geramipanah F, Raeesi B. In vitro mechanical tests for modern dental ceramics. Journal of Dentistry of Tehran University of Medical Sciences , 2006, 3(3): 143-152
[5] Nakahira A, Tamai M, Aritani H, . Biocompatibility of dense hydroxyapatite prepared using an SPS process. Journal of Biomedical Materials Research , 2002, 62(4): 550-557
[6] Meyers M A, Chen P-Y, Lin A Y-M, . Biological materials: Structure and mechanical properties. Progress in Materials Science , 2008, 53(1): 1-206
[7] Gu Y W, Khor K A, Cheang P. Bone-like apatite layer formation on hydroxyapatite prepared by spark plasma sintering (SPS). Biomaterials , 2004, 25(18): 4127-4134
[8] Joschek S, Nies B, Krotz R, . Chemical and physicochemical characterization of porous hydroxyapatite ceramics made of natural bone. Biomaterials , 2000, 21(16): 1645-1658
[9] Kusmanto F, Walker G, Gan Q, . Development of composite tissue scaffolds containing naturally sourced mircoporous hydroxyapatite. Chemical Engineering Journal , 2008, 139(2): 398-407
[10] Deville S, Saiz E, Tomsia A P. Freeze casting of hydroxyapatite scaffolds for bone tissue engineering. Biomaterials , 2006, 27(32): 5480-5489
[11] Wen S, Van D. Grain boundary in some nano-materials. Ceramics International , 1995, 21(2): 109-112
[12] Suchanek W, Yashima M, Kakihana M, . Hydroxyapatite ceramics with selected sintering additives. Biomaterials , 1997, 18(13): 923-933
[13] Aronov D, Karlov A, Rosenman G. Hydroxyapatite nanoceramics: Basic physical properties and biointerface modification. Journal of the European Ceramic Society , 2007, 27(13-15): 4181-4186
[14] Yoon B H, Park C S, Kim H E, . In-situ fabrication of porous hydroxyapatite (HA) scaffolds with dense shells by freezing HA/camphene slurry. Materials Letters , 2008, 62(10-11): 1700-1703
[15] Omori M, Onoki T, Hashida T, . Low temperature synthesis of hydroxyapatite from CaHPO₄·H₂O and Ca(OH)₂ based on effect of the spark plasma system (SPS). Ceramics International , 2006, 32(6): 617-621
[16] Miao X, Tan D M, Li J, . Mechanical and biological properties of hydroxyapatite/tricalcium phosphate scaffolds coated with poly(lactic-co-glycolic acid). Acta Biomaterialia , 2008, 4(3): 638-645
[17] He L H, Standard O C, Huang T T Y, . Mechanical behaviour of porous hydroxyapatite. Acta Biomaterialia , 2008, 4(3): 577-586
[18] Werner J, Linner-Krcmar B, Friess W, . Mechanical properties and in vitro cell compatibility of hydroxyapatite ceramics with graded pore structure. Biomaterials , 2002, 23(21): 4285-4294
[19] Chen B, Zhang T, Zhang J, . Microstructure and mechanical properties of hydroxyapatite obtained by gel-casting process. Ceramics International , 2008, 34(2): 359-364
[20] Kumar R, Prakash K H, Cheang P, . Microstructure and mechanical properties of spark plasma sintered zirconia-hydroxyapatite nano-composite powders. Acta Materialia , 2005, 53(8): 2327-2335
[21] Fellah B H, Gauthier O, Weiss P, . Osteogenicity of biphasic calcium phosphate ceramics and bone autograft in a goat model. Biomaterials , 2008, 29(9): 1177-1188
[22] Kalita S J, Bhatt H A. Nanocrystalline hydroxyapatite doped with magnesium and zinc: Synthesis and characterization. Materials Science and Engineering C , 2007, 27(4): 837-848
[23] Chen Q Z, Wong C T, Lu W W, . Strengthening mechanisms of bone bonding to crystalline hydroxyapatite in vivo. Biomaterials , 2004, 25(18): 4243-4254