J. Seebeck scite author profile

Fracture fixation in severe osteoporotic bone by means of implants that rely on screw anchorage is still a clinical problem. So far, a sufficiently accurate prediction of the holding capacity of screws as a function of local bone morphology has not been obtained. In this study the ultimate pullout loads of screws in the epi-, meta-, and diaphyseal regions of human tibiae were correlated to the cortical thicknesses and cancellous bone mineral densities at the screw axes determined from QCT densitometric data. Stepwise multiple linear regression showed that in regions with cortical thicknesses below 1.5 mm, cancellous density determined the ultimate pullout load (R2 = 0.85, p < 0.001), while in regions with cortices above 1.5 mm, cortical thickness alone significantly influenced the holding capacity of a screw (R2 = 0.90, p < 0.001). The findings of this study provide a basis for a bone morphology-related pre-operative estimation of the holding capacity of screws, which could help to improve their proper application in osteoporotic bone.

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Effect of cortical thickness and cancellous bone density on the holding strength of internal fixator screws

Seebeck¹,

Goldhahn²,

Städele³

et al. 2004

Journal Orthopaedic Research

148

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Internal fixators are a new class of implants designed to preserve the periosteal blood supply of the bone. In contrast to conventional plate fixation in which the screws have spherical heads and are loaded mainly by axial pullout forces, screws in internal fixators are "locked" within the plate and therefore subjected to axial as well as bending loads. In this study the ultimate loads of screws of a commercially available internal fixator system were tested in a pullout (n = 72) and cantilever bending mode (n = 72) in metaphyseal and diaphyseal regions of four pairs of human tibiae with different bone qualities. Cortical thickness and cancellous bone density were determined at the screw insertion sites. Stepwise multiple linear regression revealed that cortical thickness and cancellous density can explain 93% and 98% of the variance of the ultimate load of the screws in an axial pullout and cantilever bending mode. Screws in internal fixators are better suited to transmit shear forces and thereby make better use of the strength potential of bone than screws used in conventional plate fixation: this is especially advantageous when bone strength is reduced, e.g. due to osteoporosis.

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Straining of the intact and fractured proximal humerus under physiological-like loading

Maldonado

Seebeck

Heller

et al. 2003

Journal of Biomechanics

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In vitro initial stability of a stemless humeral implant

Favre

Seebeck

Thistlethwaite

et al. 2016

Clinical Biomechanics

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J. Seebeck

Mechanical behavior of screws in normal and osteoporotic bone

Effect of cortical thickness and cancellous bone density on the holding strength of internal fixator screws

Straining of the intact and fractured proximal humerus under physiological-like loading

In vitro initial stability of a stemless humeral implant

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