Your search keyword '"Dendorfer S"' showing total 2 results

1. Deformation behaviour of bovine cancellous bone.

Author

Dendorfer, S., Maier, H. J., and Hammer, J.

Subjects

*MECHANICAL loads, *PHYSIOLOGIC strain, *BONES, *OSTEOPOROSIS, *ARTIFICIAL implants

Abstract

Repetitive cyclic loading from daily activities is reported to induce fatigue damage and microcracking in bone structures. In terms of osteoporotic structures or in cases of serious damage of skeleton segments and the replacement by metallic implants the degree of damage due to cyclic loading will be even more pronounced. It is generally assumed that fatigue induced cracking and crack propagation essentially act as driving forces for complex physiological phenomena such as remodelling processes of bones and the adaptation to applied loads. In cases where the crack propagation rate exceeds the remodelling velocity, sudden and unexpected fracture of the bone is observed. Especially for implant reinforced structures the deviation in stiffness to the bone material can induce high peak stresses and accelerate crack propagation. Whereas, for cortical bone the mechanical behaviour under cyclic loading is sufficiently described, only rough data are available for trabaecular structures. In this study the deformation behaviour of bovine vertebra trabecular bone specimens is investigated under cyclic compressive loading. A powerlaw relationship was found between the applied load ratio and cycles to failure. A linear decrease of maximum, integral strains at failure with increasing applied load ratio was observed. Optical deformation measurement of the surface strains revealed that low strains (0–1 increasing applied load ratio whereby the higher strains behave directly opposite. This indicates that different failure mechanisms are acting at low cycle and high cycle fatigue, respectively. [ABSTRACT FROM AUTHOR]

Published

2006

2. First clinical and biomechanical results of the Trochanteric Fixation Nail (TFN).

Author

Lenich, A., Fierlbeck, J., Al-Munajjed, A., Dendorfer, S., Mai, R., Füchtmeier, B., Mayr, E., and Hammer, J.

Subjects

BIOMECHANICS, INTRAMEDULLARY fracture fixation, FEMUR injuries, TOTAL hip replacement, OSTEOPOROSIS

Abstract

Conventional osteosynthesis of proximal femur fractures is still affected by serious complication rates between 4–18%, even though advanced implant modifications and surgical techniques are common practice. In terms of increasing age and co-morbidity of patients this complication ratio is expected to increase even further in the immediate future. One major reason for implant failure is the decreasing stability potential of the implant due to a loss in mechanical properties of cancellous bone. Therefore, efforts in new intramedulary techniques specifically focus on the load bearing characteristics of the implant by developing new geometries to improve the implant-tissue interface. This investigation discusses first clinical results of the trochanteric fixation nail TFN (145 patients) and a biomechanical analysis of the blade/femur head interaction under different static loading conditions. The TFN shows promising performance in first clinical results. In the clinical study the overall complication rate was significantly lower compared to other similar osteosynthesis. For the investigation of the biomechanical stability of the helical TFN blade the following experiments were performed: Analysis of the axial load required for insertion of the blade by free rotation; measurement of the corresponding rotation angle for total insertion (32 mm) (n=8); pull-out forces with suppressed rotation (n=4); loads for rotational overwinding of the implant in the fully inserted condition (n=4). All investigations were performed on human femoral heads. The bone mineral densities of the specimens were detected by QCT-scans. Prior to cadaveric testing the experimental set-up was validated (n=8) by the use of synthetic foam blocks (Sawbone®). [ABSTRACT FROM AUTHOR]

Published

2006