Abstract
Introduction
Wear plays a key role in the clinical outcome of total hip replacements (THR). In addition, increased frictional moment can stress the implant interfaces which may lead to high torsional loadings in the intermodular taper junction (fretting) and cup loosening and to the development of noise (squeaking). Against the background of larger head diameters (increased range of motion and decreased risk of dislocation), the friction induced by the joint articulation is of particular interest. As of now, the investigation of friction with the use of relevant joint kinematics and loadings are limited to numerical studies. Experimental approaches use simplified models which do not take into consideration complex activities. Thus, with the aim of this study is the identification of articular frictional moments that consider critical in vivo loading conditions and kinematics as well as the clinical cup inclination, head size and clearance of ceramic-on-ceramic hip bearings.
Materials and Methods
A standard hip simulator (Minibionix 852 with 4 DOF Hip setup, MTS, Eden Prairie, USA) was modified in order to allow for high-precision friction measurements during head-insert articulation in all 6 DOF (MC2.5D-500, AMTI, Boston, USA). Disturbing systemic effects have been minimized by using quasi frictionless aerostatic lateral force compensation (Eitzenberger, Wessobrunn, Germany) and cross talk compensation. Beside the standard protocoll for in vitro wear assessment (ISO 14242-1), more complex profiles from in vivo patient data (Heidelberg Motion Lab and Orthoload database) have been used: normal walking with different walking speeds and patient's weights, stairs up/down and start-stop conditions. All-ceramic bearings (Biolox delta, Ceramtec, Plochingen, Germany) have been orientated in clinically relevant cup inclinations (30, 45, 60 and 75 deg). For each head diameter (28, 36 and 48 mm) n=8 specimens have been devided in two groups: small and large clearance according to the manufacturer's specification. All tests were run at 37°C in diluted bovine serum (20 g/l protein content).
Results and Discussion
For all continuously running activities (normal walking, stairs up/down and ISO standard), increased resulting frictional moments have been measured with larger head diameters and smaller clearances in a range of less than 6 Nm. This data corresponds well to the results of a well-lubricated ceramic-on-ceramic bearing from numerical studies. In addition, the initial breakaway torque after a short resting period (start-stop initiation) was increased, where the highest maximal moments have been measured with increasing resting durations and larger head diameters (large clearance: up to 11 Nm, small clearance: up to 20 Nm). Interestingly enough, not in all cases a negative effect on the resulting moment was seen with increasing cup inclination, even though no subluxation was induced.
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