H. M. Tensi scite author profile

In this finite element study the stresses between a stem component of a cementless hip endoprosthesis (Young modulus of Co-Cr-Mo) and the human femur were calculated for two different loading types. Linear and non-linear models were used to simulate the interface implant bone. Two models, a stem with a porous coated surface over the entire length and a stem with a porous coated surface in the proximal region were compared regarding the load transmission to the femur. An additional calculation of an 'isoelastic' stem (Young modulus of cortical bone) was done to show the influence of the stem stiffness. A porous coated surface over the entire length causes principal shear stresses up to 2.75 MPa in the distal-medial region during level walking. The highest compressive stresses were calculated in the proximal-lateral region as 1.5 MPa in cancellous bone. A more physiological load transmission is obtained by limiting the coated area to the proximal region. All stresses in the two models are lower than experimentally evaluated strengths in the interface between implant and bone. A strong influence of the Young modulus of the stem material on the interface stresses was found. An 'isoelastic' stem causes compressive stresses in the proximal-lateral region whose values exceed the experimental strength of cancellous bone.

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Performance of Vegetable Oils as a Cooling Medium in Comparison to a Standard Mineral Oil

Totten¹,

Tensi

Lainer

1999

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Wetting Kinematics

Tensi¹

1992

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Quenching Theory and Technology

Liščić¹,

Tensi²,

Canale³

et al. 2010

131

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H. M. Tensi

Theory and Technology of Quenching

Non-Linear Three-Dimensional Finite Element Analysis of a Cementless Hip Endoprosthesis

Performance of Vegetable Oils as a Cooling Medium in Comparison to a Standard Mineral Oil

Wetting Kinematics

Quenching Theory and Technology

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