Finite element modeling of hip resurfacing cup deformation

Kesler, Nathanael Murray

12 January 2010

Hip resurfacing arthroplasty is touted as an attractive alternative to total hip arthroplasty for treatment of severe joint pain and limited mobility in young patients because it is bone conserving and allows for a greater range of motion. There is concern in the orthopaedic community, however, regarding surgically-induced deformation of hip resurfacing cups. Cup deformation could potentially compromise the tight clearance between the femoral head and cup, resulting in increased wear, acoustic emissions, and joint binding. This phenomenon has been investigated both experimentally and with finite element analysis (FEA). Finite element studies have contributed significantly to our understanding of cup deformation, such as the effect of different cup dimensions on deformation results, but unfortunately such studies were deficient in a number of ways. The first objective of this thesis was to create a three-dimensional finite element model of resurfacing cup deformation that addressed the limitations of previous models pertaining to pelvic geometry, meshing, material properties, and cup insertion, in order to more fully elucidate cup deformation. The second objective was to demonstrate that two-dimensional characterization of cup deformation at the cup rim is insufficient, by more fully characterizing cup deformation in three-dimensions. The geometry was obtained via laser scanning and digital processing of a hemi-pelvis replica, meshing was performed without the use of shell elements, linear elasticity with strain-hardening after the onset of yielding was assigned to the cup and bone, and the most appropriate method for simulation of cup insertion was determined via two-dimensional axisymmetric analyses. Also, cup deformation was characterized in three-dimensions. The key findings of this thesis are that bone yield behaviour has important implications on press-fitting simulation, and the cup deforms irregularly and possibly plastically during press-fitting. A three-dimensional finite element model of resurfacing cup deformation that addressed the limitations of previous models was successfully created. Measurement of deformation at the rim of the resurfacing cup for characterization of cup deformation is insufficient; full characterization of cup deformation in three-dimensions is necessary. Future work should incorporate clinical testing to obtain model inputs such as impact and muscle forces, as well as model validation.

Finite

Element

Modeling

Hip

Resurfacing

Cup

Deformation

Finite element investigation of Closed Head Injuries

Chen, Hongxi

27 August 2010

Head injuries are very common in daily life and in war field. Head injuries are classified into open and closed. The mechanical mechanisms involved in closed head injuries are very different from those in open head injuries. Closed head injuries are more often re-ported with the use of protective device such as helmets. Helmets were found effective in reducing open head injuries, but less effective for closed head injuries. Finite element modeling is an effective and efficient tool for investigating head injuries. In this thesis, a two-dimensional finite element model was constructed based on a Mag-netic Resonance Image (MRI) scan data from a patient. MATLAB programming was used to extract the information from the MRI scan data. The finite element model was then used to investigate factors affecting closed head injuries. As a new contribution to closed head injury study, the fluid component in the human head, CSF, was studied by a group of comparative simulations. The other three factors, elasticity modulus of the cra-nium, contact area of impact, and impact duration were also investigated. Their effects on reducing the strain values in the brain were measured. Investigation results show that, increasing elasticity modulus of the cranium, contact area of impact and impact duration are very helpful to reduce the strain values in the brain. Helmet is helpful to protect people from closed head injuries because it can change all these three factors by using different shell stiffness and different padding material. The cerebrospinal fluid is effective in protecting the brain from impacts, as a fluid is able to reduce normal strains and filter nearly all shear strains transferred to the brain. It indicates that if a layer of fluid could be added as a layer in a protective helmet, the helmet would be more effective in protecting the brain. Conclusions obtained from the investigations are helpful for preventing closed head injuries and for improving design of protective devices such as helmets.

Finite

Element

Method

Closed

Head

Injuries

Optimum coupling in thin-walled, closed section composite beams

Lentz, W. Karl

05 1900

No description available.

Composite materials

Elasticity

Finite element method

Three dimensional isoparametric finite element analysis with geometric and material nonlinearities

Li, Jian

08 1900

No description available.

Finite element method

Nonlinear theories

Engineering mathematics

Optimum structural modification with respect to dynamic behaviour

Jonas, Stephan

08 1900

No description available.

Structural design

Finite element method

Structural dynamics

Hybrid and mixed finite element models for viscous, incompressible fluid flows

Bratianu, Constantin

12 1900

No description available.

Finite element method

Navier-Stokes equations

A complete three-dimensional electromagnetic simulation of ground-penetrating radars using the finite-difference time-domain method

Bourgeois, Jacqueline M.

05 1900

No description available.

Radar Antennas

Radar simulators

Finite element method

Finite element analysis of printed wiring board deformations during thermal cycles involved in the solder masking process

Martin, Timothy Lee

05 1900

No description available.

Solder and soldering

Printed circuits

Finite element method

Application method of the least squares finite element method to fracture mechanics

Johnsen, Eivind

05 1900

No description available.

Finite element method

Least squares

Fracture mechanics

On-line detection of rotor faults in permanent magnet machines using only terminal quantities

le Roux, Wiehan

12 1900

No description available.

Rotors

Finite element method

Permanent magnet motors