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Orthopaedic Proceedings
Vol. 101-B, Issue SUPP_5 | Pages 26 - 26
1 Apr 2019
Shitole P Gupta A Ghosh R
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Introduction

Bone fracture toughness is an important parameter in resistance of bone to monotonic and fatigue failure. Earlier studies on bone fracture toughness were focused on either cortical or cancellous bone, separately [1, 2]. Reported fracture toughness values indicated that cortical bone is tougher to break as compared to cancellous bone. In order to understand complete fracture of a whole bone, the interface between cortical and cancellous bone (named as corticellous bone) might play a crucial role and is interesting topic of research. The goal of this study was to identify fracture toughness in terms of J integral and fracture mechanism of the corticellous bone.

Material and Methods

Corticellous bone samples (single edge notch bend specimen or SENB) were prepared from bovine proximal femur according to ASTM E399-90 standard (Fig.1). For corticellous bone, samples were prepared in such way that approximately half of the sample width consist of cortical bone and another half is cancellous bone. Precaution was taken while giving notch and pre-crack to corticellous bone that pre-crack should not enter from cortical to cancellous portion. All specimens were tested using a universal testing machine (Tinius Olsen, ± 100 N) under displacement rate of 100 µm/min until well beyond yield point. The fracture toughness parameter in terms of critical stress intensity (KIC) was calculated according to ASTM E399-90 as given by, KIC=PS/BW1.5*f(a/W)

Where, P = applied load in kN, S = loading span in cm, B = specimen thickness in cm, W = specimen width in cm, a = total crack length, f(a/W) = geometric function. After the fracture test the J integral of each specimen was calculated using following equation. [ASTM E1820]. Jtotal=Jel+Jpl=KIC2/E+2Apl/Bb0

Where, Jel is J integral of the elastic deformation, Jpl is J integral of the plastic deformation, E′=E for plane stress condition and E′= E/(1−ν2) for plane strain condition (E is elastic modulus; ν is Poisson's ratio), bo = W−ao, height of the un-cracked ligament, and Apl is the area of the plastic deformation part in the load–displacement curve.


Orthopaedic Proceedings
Vol. 99-B, Issue SUPP_5 | Pages 39 - 39
1 Mar 2017
Muratoglu O Oral E Doshi B
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Introduction

Radiation cross-linked UHMWPE is preferred in total hip replacements due to its wear resistance [1]. In total knees, where stresses are higher, there is concern of fatigue damage [2]. Antioxidant stabilization of radiation cross-linked UHMWPE by blending vitamin E into the polymer powder was recently introduced [3]. Vitamin E greatly hinders radiation cross-linking in UHMWPE [4]. In contrast peroxide cross-linking of UHMWPE is less sensitive to vitamin E concentration [5]. In addition, exposing UHMWPE to around 300°C, increases its toughness by inducing controlled chain scission and enhanced intergranular diffusion of chains, simultaneously [6]. We present a chemically cross-linked UHMWPE with high vitamin E content and improved toughness by high temperature melting.

Methods and Materials

Medical grade GUR1050 UHMWPE was blended with vitamin E and with 2,5-Di(tert-butylperoxy)-2,5-dimethyl-3-hexyne or P130 (0.5% Vitamin-E and 0.9% P130). The mixed powder was consolidated into pucks. The pucks were melted for 5 hours in nitrogen at 300, 310 and 320°C.

One set of pucks melted at 310°C was accelerated aged at 70°C at 5 atm. oxygen for 2 weeks.

Tensile mechanical properties were determined using ASTM D638. Izod impact toughness was determined using ASTM D256 and F648. Wear rate was determined using a bidirectional pin-on-disc (POD) tester with cylindrical pins of UHMWPE against polished CoCr discs in undiluted, preserved bovine serum.


Orthopaedic Proceedings
Vol. 90-B, Issue SUPP_II | Pages 381 - 381
1 Jul 2008
Tong J Wong K Lupton C
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The long-term stability of total hip replacements (THRs) critically depends on the lasting integrity of the bond between the implant and the bone. Late failure in the absence of infection is known as ‘aseptic loosening’, a process characterised by the formation and progressive thickening of a continuous layer of fibrous tissue at the interface between the prosthesis and the bone. Aseptic loosening has been identified as the most common cause for long-term instability leading to the failure of ace-tabular cups. There is clearly a need to study the failure mechanisms in the acetabular fixation if the long-term stability of THR is to be significantly improved. The bonding strength in the presence of defects is measured using interfacial fracture toughness, and this information is not available currently.

In this work, interfacial fracture toughness of synthetic and bovine bone-cement interface has been studied using sandwiched Brazilian disk specimens. Experiments were carried out using a common bone cement, CMW, and polyurethane foam under selected loading angles from 0 to 25 degrees to achieve full loading conditions from tensile (mode I) to shear (mode II). Finite element analyses were carried out to obtain the solutions for strain energy release rate at a given phase angle (ratio of shear and tensile stress) associated with the experimental models. The effects of crack length on the measured interfacial fracture toughness were examined. Microscopic studies were also carried out to obtain the morphology of the fractured interfaces at selected loading angles.

The results show that both polyurethane foam and bovine cancellous bone seem to produce a similar type of interfacial failure of bone-cement interface, with cement pedicles being ‘pull-out’ of the pores of the foam/ bone. Damage sustained by the cement pedicles seems to increase progressively as the increase of shear loading component. The measured values of fracture toughness are a function of crack length and phase angle, and are comparable with those published in the literature on cortical bone and cement interface.

The implication of these results on the assessment of fixation in acetabular replacements is discussed, particularly in the light of results from bovine cancellous bone-cement interface.


Bone & Joint Research
Vol. 4, Issue 6 | Pages 99 - 104
1 Jun 2015
Savaridas T Wallace RJ Dawson S Simpson AHRW

Objectives

There remains conflicting evidence regarding cortical bone strength following bisphosphonate therapy. As part of a study to assess the effects of bisphosphonate treatment on the healing of rat tibial fractures, the mechanical properties and radiological density of the uninjured contralateral tibia was assessed.

Methods

Skeletally mature aged rats were used. A total of 14 rats received 1µg/kg ibandronate (iban) daily and 17 rats received 1 ml 0.9% sodium chloride (control) daily. Stress at failure and toughness of the tibial diaphysis were calculated following four-point bending tests.


Orthopaedic Proceedings
Vol. 98-B, Issue SUPP_9 | Pages 29 - 29
1 May 2016
McEntire B Bal B Rahaman M Pezzotti G
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Introduction. The in vivo evolution of surface material properties is important in determining the longevity of bioceramics. Fracture toughness is particularly relevant because of its role in wear resistance. Some bioceramics, such as zirconia (ZrO2) undergo in vivo phase transformation, resulting in a marked reduction in toughness and commensurate increased wear. Here, we investigated the effect of accelerated aging on the surface toughness of alumina (Al2O3), zirconia-toughened alumina (ZTA), and silicon nitride (Si3N4) femoral heads, in order to identify the optimal ceramic material for in vivo implantation and long-term durability. Materials. A newly developed Raman microprobe-assisted indentation method was applied to evaluate and compare surface fracture toughness mechanisms operative in Si3N4 (Amedica Corporation, Salt Lake City, UT, USA), Al2O3 and ZTA (BIOLOX® forte, and delta, respectively, CeramTec, GmbH, Plochingen, Germany) bioceramics. The Al2O3 and ZTA materials have long established histories in total hip arthroplasty; whereas Si3N4 has been newly developed for this purpose. The improved method proposed here consisted in coupling the “traditional” indentation technique with quantitative assessments of microscopic stress fields by confocal Raman microprobe piezo-spectroscopy. Concurrently, crack opening displacement (COD) profiles were also monitored by Raman spectroscopy. Toughness measurements were determined using both as-received and hydrothermally exposed (100–121°C for up to 300 hours) femoral heads. Results. The Raman microprobe visualized two main toughening mechanisms operative in Si3N4 and ZTA bioceramics, namely crack-face bridging by acicular Si3N4 grains and polymorphic transformation of ZrO2 dispersoids. Both mechanisms elevated the resistance to crack propagation above the brittle behavior of Al2O3, which experienced a low crack resistance of ∼1.5 MPaâ��m1/2 independent of crack length. The as-received Si3N4 showed a sharply rising R-curve, up to ∼7 MPaâ��m1/2 within a propagation distance of ∼110 µm. A rising R-curve was also observed in the as-received ZTA, although its increase was less pronounced, ∼4 MPaâ��m1/2 within ∼120 µm. After hydrothermal exposure, surface toughness values decreased by ∼5%, ∼10%, and ∼42% for Si3N4, Al2O3, and ZTA, respectively. Substantial embrittlement was particularly noted at the surface of the ZTA material, with its toughness value reduced to the level of Al2O3. At the micromechanical scale, such embrittlement is obviously related to decreased availability of transformable (metastable) tetragonal ZrO2dispersoids at the surface. In ZTA, the hydrothermal attack annihilated any rising R-curve effect; whereas this degradation mechanism was not present in either Al2O3 or Si3N4 (Fig. 1). Discussion. Empowered by the Raman microprobe, the indentation micro-fracture method was shown capable of providing reliable surface toughness measurements in dissimilar biomaterials. Different from bulk toughness, surface toughness is the most relevant parameter in designing bioceramic microstructures for use as hip arthroplasty bearing couples for improved tribological performance. It was demonstrated that the environmentally driven phase transformation in ZTA is detrimental to surface toughness. On the other hand, Si3N4 experienced surface toughness values conspicuously independent of hydrothermal attack. Conclusions. Unlike transformation toughening (which is operative in ZTA), crack-face bridging (which is the toughening mechanism in Si3N4) proved to be the most durable surface toughening effect for a biomaterial to be employed in joint arthroplasty