Sage Journals: Discover world-class research

Abstract

The incorporation of carboxyl functionalised multi-walled carbon nanotube (MWCNT-COOH) into a leading proprietary grade orthopaedic bone cement (Simplex P™) at 0.1 wt% has been investigated. Resultant static and fatigue mechanical properties, in addition to thermal and polymerisation properties, have been determined. Significant improvements (p ≤ 0.001) in bending strength (42%), bending modulus (55%) and fracture toughness (22%) were demonstrated. Fatigue properties were improved (p ≤ 0.001), with mean number of cycles to failure and fatigue performance index being increased by 64% and 52%, respectively. Thermal necrosis index values at ≥44℃ and ≥55℃ were significantly reduced (p ≤ 0.001) (28% and 27%) versus the control. Furthermore, the onset of polymerisation increased by 58% (p < 0.001), as did the duration of the polymerisation reaction (52%). Peak energy during polymerisation increased by 672% (p < 0.001). Peak area of polymerisation increased by 116% (p < 0.001) indicating that the incorporation of MWCNT-COOH reduced the rate of polymerisation significantly. A non-significant reduction (8%) in percentage monomer conversion was also recorded. Raman spectroscopy clearly showed that the addition of MWCNT-COOH increased the ratio between normalised intensities of the G-Band and D-Band (I_G/I_D), and also increased the theoretical compressive strain (−1.72%) exerted on the MWCNT-COOH by the Simplex P™ cement matrix. Therefore, demonstrating a level of chemical interactivity between the MWCNT-COOH and the Simplex P™ bone cement exists and consequently a more effective mechanism for successful transfer of mechanical load. The extent of homogenous dispersion of the MWCNT-COOH throughout the bone cement was determined using Raman mapping.

Keywords

Polymethyl methacrylate bone cement multi-walled carbon nanotube mechanical properties thermal properties Raman spectroscopy

Get full access to this article

View all access options for this article.

References

Kuehn

Ege

Gopp

. Acrylic bone cements: composition and properties. Orthop Clin North Am 2005; 36: 17–28.

Meyer

Lautenschlager

Moore

. On the setting properties of acrylic bone cement. J Bone Joint Surg 1973; 55: 149–156.

Marrs

Andrews

Rantell

. Augmentation of acrylic bone cement with multiwall carbon nanotubes. J Biomed Mater Res Part A 2006; 77: 269–276.

Harper EJ, German MJ, Bonfield W, et al. A comparison of VersaBond™, a modified acrylic bone cement with improved handling properties, to Palacos R, Simplex P. In: Trans sixth world biomater cong, Kamuela (Big Island), 2000, p.540.

Choi

Brooks

Eaton

. Enhancement of thermal and electrical properties of carbon nanotube polymer composites by magnetic field processing. J App Phys 2003; 94: 6034–6039.

Xie

Mai

Zhou

. Dispersion and alignment of carbon nanotubes in polymer matrix: A review. Mater Sci Eng R 2005; 49: 89–112.

Andrews

Weisenberger

. Carbon nanotube polymer composites. Curr Opin Solid State Matter 2004; 8: 31–37.

Spiegelberg SH and McKinley GH. Characterization of the curing process of bone cement with multi-harmonic shear rheometry. In: Trans 24th Ann Mtg, Soc Biomater, San Diego, CA. 1998; pp.283.

McClory

McNally

Baxendale

. Electrical and rheological percolation of PMMA/MWCNT nanocomposites as a function of CNT geometry and functionality. Eur Poly J 2010; 46: 854–868.

10.

Ormsby

McNally

Mitchell

. Incorporation of multiwalled carbon nanotubes to acrylic based bone cements: Effects on mechanical and thermal properties. J Mech Behav Biomed Mater 2010; 3: 136–145.

11.

Ormsby

McNally

O'Hare

. Fatigue and biocompatibility properties of a poly(methyl methacrylate) bonecement with multi-walled carbon nanotubes. Acta Biomaterialia 2011; 8: 1201–1212.

12.

Ormsby

McNally

Mitchell

. Influence of multiwall carbon nanotube functionality and loading on mechanical properties of PMMA/MWCNT bone cements. J Mater Sci Mater Med 2010; 21: 2287–2292.

13.

Ormsby

McNally

Mitchell

. Thermal and rheological properties of PMMA/MWCNT bone cements. Carbon 2011; 49: 2893–2904.

14.

Gonçalves

Cruz

SMA

Ramalho

. Graphene oxide versus functionalized carbon nanotubes as reinforcing agent in a PMMA/HA bone cement. Nanoscale 2012; 4: 2937–2945.

15.

British Standard for Implants for Surgery: Acrylic Resin Cements. BS ISO 5833:2002.

16.

Dunne

Orr

Mushipe

. The relationship between porosity and fatigue characteristics of bone cements. Biomaterials 2003; 24: 239–245.

17.

Hastings

NAJ

Peacock

. Statistical distributions, London, UK: Butterworth, 1975.

18.

Weibull

. Fatigue testing and analysis of results, New York, USA: Macmillian, 1961.

19.

Shigley

Mischke

. Mechanical engineering design, 5th ed. New York: McGraw-Hill, 1989.

20.

Murphy

Prendergast

. On the magnitude and variability of the fatigue strength of acrylic bone cement. Int J Fatigue 2000; 22: 855–864.

21.

Britton

McInnes

Ledoux

. Shear bond strength of ceramic orthodontic brackets to enamel. Am J Orthod Dentofac 1990; 98: 348–353.

22.

Topoleski

LDT

Ducheyne

Cuckler

. A fractographic analysis of in vivo poly(methyl methacrylate) bone-cement failure mechanisms. J Biomed Mater Res 1993; 24: 135–154.

23.

Davies

O’Connor

Greer

. Comparison of the mechanical properties of Simplex P, Zimmer Regular and LVC bone cements. J Biomed Mater Res 1987; 21: 719–730.

24.

Davies

O’Connor

Greer

. Influence of antibiotic impregnation on the fatigue life of Simplex P and Palacos R acrylic bone cement, with and without centrifugation. J Biomed Mater Res 1989; 23: 379–397.

25.

Davies

Harris

. The effect of addition of methylene blue on the fatigue strength of Simplex P bone cement. J Appl Biomater 1992; 3: 81–85.

26.

Lewis

Austin

. Mechanical properties of vacuum mixed acrylic bone cement. J Appl Biomater 1994; 5: 307–314.

27.

Dunne

Orr

. Curing characteristics of acrylic bone cement. J Mater Sci Mater Med 2002; 13: 17–22.

28.

Barrett

KEJ

. Determination the rates of thermal decomposition of polymerisation initiators with a differential scanning calorimeter. J Appl Polym Sci 1976; 11: 1617–1626.

29.

Filipovic

Petrovic-Djakov

Vrhovac

. DSC investigation of isothermal bulk copolymerization of alkylaryl methacrylates. J Therm Anal and Calorim 1993; 40: 735–740.

30.

Lewis

Mladsi

. Correlation between impact strength and fracture toughness of PMMA-based bone cements. Biomaterials 2000; 21: 775–781.

31.

Wagner

Chu

. Biaxial flexural strength and indentation fracture toughness of three new dental core ceramics. J Prosthet Dentist 1996; 76: 140–144.

32.

Singh

Gracio

LeDuc

. Integrated biomimetic carbon nanotube composites for In Vivo systems. Nanoscale 2010; 2: 2855–2863.

33.

Ding

Eitan

Fisher

. Direct observation of polymer sheathing in carbon nanotube-polycarbonate composites. Nano Letters 2003; 3: 1593–1597.

Carboxyl functionalised MWCNT/polymethyl methacrylate bone cement for orthopaedic applications

Abstract

Keywords

Get full access to this article

References