Interfacial strength of novel PMMA/HA/nanoclay bone cement

Bio-Medical Materials and Engineering

Volumn 18, Issue 6, 2008, Pages 367-375

  Wang, C X ^a   Tong, J ^a  

^a UNIVERSITY OF PORTSMOUTH   (United Kingdom)

Author keywords

Bioactive bone cement; interfacial fracture toughness; nanoclay; strain energy release rate

Indexed keywords

BIOACTIVE BONE CEMENT; BONE-CEMENT INTERFACE; INTERFACIAL FRACTURE TOUGHNESS; INTERFACIAL PROPERTY; INTERFACIAL STRENGTH; JOINT ARTHROPLASTY; NANO CLAYS; PREMATURE FRACTURE;

CRACKS; FRACTURE; LOADING; NANOCOMPOSITES; STRAIN ENERGY; STRENGTH OF MATERIALS;

BONE CEMENT;

BONE CEMENT; HYDROXYAPATITE; POLY(METHYL METHACRYLATE); SILICATE;

ARTICLE; CHEMISTRY; HARDNESS; MATERIALS TESTING; SCANNING ELECTRON MICROSCOPY; SHEAR STRENGTH; SURFACE PROPERTY; TENSILE STRENGTH; TRANSITION TEMPERATURE;

BONE CEMENTS; DURAPATITE; HARDNESS TESTS; MATERIALS TESTING; MICROSCOPY, ELECTRON, SCANNING; POLYMETHYL METHACRYLATE; SHEAR STRENGTH; SILICATES; SURFACE PROPERTIES; TENSILE STRENGTH; TRANSITION TEMPERATURE;

EID: 64849098150     PISSN: 09592989     EISSN: None     Source Type: Journal    
DOI: 10.3233/BME-2008-0553     Document Type: Article

References (21)

1. G. Lewis, Properties of acrylic bone cement: state of the art review, Journal of Biomedical Materials Research (Appl. Biomater.) 38 (1997), 155-182.
2. T.M. Wright and S. Goodman (eds), Implant Wear in Total Joint Replacement, American Academy of Orthopaedic Surgeons, Rosemont, IL, 2001.
3. M.J. Conroy, A. Pédrono, J.E. Bechtold, K. Søballe, D. Ambard and P. Swider, High-resolution magnetic resonance flow imaging in a model of porous bone-implant interface, Magnetic Resonance Imaging 24 (2006), 657-661.
4. J. Huang, L.D. Silvio, M. Wang, K.E. Tanner and W. Bonfield, In vitro mechanical and biological assessment of hydroxyapatite reinforced polyethylene composite, Journal of Materials Science: Material in Medicine 8 (1997), 1-5.
5. M.J. Dalby, L.D. Silvio, E.J. Harper andW. Bonfield, Initial interaction of osteoblasts with the surface of a hydroxyapatitepoly (methylmethacrylate) cement, Biomaterials 22 (2001), 1739-1747.
6. M.J. Dalby, L.D. Silvio, E.J. Harper and W. Bonfield, Increasing hydroxyapatite incorporation into poly(methylmethacrylate) cement increases osteoblast adhesion and response, Biomaterials 23 (2002), 569-576.
7. A.M. Moursi, A.V. Winnard, P.L. Winnard, J.J. Lannutti and R.R. Seghi, Enhanced osteoblast response to a polymethylmethacrylate-hydroxyapatite composite, Biomaterials 23 (2002), 133-144.
8. K. Ishihara, J. Arai, N. Nakabayashi, S. Morita and K. Furuya, Adhesive bone cement containing hydroxyapatite particle as bone compatible filler, Journal of Biomedical Materials Research 26 (1992), 937-945.
9. S.Y. Kwon, Y.S. Kim, Y.K. Woo, S.S. Kim and J.B. Park, Hydroxyapatite impregnated bone cement: in vitro and in vivo studies, Bio-Medical Materials and Engineering 7 (1997), 129-140.
10. J.H.Wang, T.H. Young, D.J. Lin, M.K. Sun, H.S. Huag and L.P. Cheng, Preparation of clay/PMMA nanocomposites with intercalated or exfoliated structure for bone cement synthesis, Macromolecular Materials and Engineering 291 (2006), 661-669.
11. L.M. Stadtmueller, K.R. Ratinac and S.P. Ringer, The effects of intragallery polymerization on the structure of PMMAclay nanocomposites, Polymer 46 (2005), 9574-9584.
12. K.R. Ratinac, R.G. Gilbert, L. Ye, A.S. Jones and S.P. Ringer, The effects of processing and organoclay properties on the structure of poly(methyl methacrylate)-clay nanocomposites, Polymer 47 (2006), 6337-6361.
13. P. Meneghetti and S. Qutubuddin, Synthesis, thermal properties and applications of polymer-clay nanocomposites, Thermochimica Acta 442 (2006), 74-77.
14. Q.H. Zeng, A.B. Yu, G.Q. Lu and D.R. Paul, Clay-based polymer nanocomposites: research and commercial development, Journal of Nanoscience and Nanotechnology 5 (2005), 1574-1592.
15. J. Tong, Interfacial fracture toughness of synthetic bone-cement interface, Key Engineering Materials 312 (2007), 251- 256.
16. C. Atkinson, R.E. Smelser and J. Sanchez, Combined mode fracture via the cracked Brazilian disk test, International Journal of Fracture 18 (1982), 279-291.
17. J.S. Wang and Z. Suo, Experimental determination of interfacial toughness curves using Brazil-nut-sandwiches, Acta Metall. Mater. 38 (1990), 1279-1290.
18. J. Tong, K.Y. Wong and C. Lupton, Determination of interfacial fracture toughness of bone-cement interface using sandwich Brazilian disks, Engineering Fracture Mechanics 74 (2007), 1904-1916.
19. ASTM F-1839, Standard specification for rigid polyurethane foam for use as a standard material for testing orthopaedic devices and instruments, 2001.
20. J. Fu and H.A. Naguib, Effect of nanoclay on the mechanical properties of PMMA/Clay nanocomposite foams, Journal of Cellular Plastics 42 (2006), 325-342.
21. L. Cristofolini, M. Viceconti, A. Cappello and A. Toni, Mechanical validation of whole bone composite femur models, Journal of Biomechanics 29 (1996), 525-535.