Abstract
Introduction
The success of cementless total hip arthroplasty (THA), primary as well as for revision, largely depends on the initial stability of the femoral implant. In this respect, several studies have estimated that the micromotion at the bone-implant interface should not exceed 150µm (Jasty 1997, Viceconti 2000) in order to ensure optimal bonding between bone and implant. Therefore, evaluating the initial stability through micromotion measurements serves as a valid method towards reviewing implant design and its potential for uncemented THAs.
In general, the methods used to measure the micromotion assume that the implant behaves as a rigid body. While this could be valid for some primary stems (Østbyhaug 2010), studies that support the same assumption related to revision implants were not found.
The aim of this study is to assess the initial stability of a femoral revision stem, taking into account possible non-rigid behaviour of the implant. A new in vitro measuring method to determine the micromotion of femoral revision implants is presented. Both implant and bone induced displacements under cyclic load are measured locally.
Methods
A Profemur R modular revision stem (MicroPort Orthopedics Inc. Arlington, TN, United States of America) and artificial femora (composite bone 4th generation #3403, Sawbones Europe AB, Malmö, Sweden) prepared by a surgeon were used.
The micromotions were measured in proximal-distal, medial-lateral or anterior-posterior directions at four locations situated in two transverse planes, using pin and bushing combinations. At each measuring location an Ø8mm bushing was attached to the bone, and a concentric Ø3mm pin was attached to the implant [Fig.1 and 2]. A supporting structure used to hold either guiding bushings or linear variable displacement transducers (LVDT) is attached to the proximal part of the implant. The whole system was installed on a hydraulic force bench (PC160N, Schenck GmbH, Darmstadt, Germany) and 250 physiological loading cycles were applied [Fig.3].
Results
By combining the local bone and implant displacements, the relative average micromotion appeared to be less than 25µm in the proximal region and less than 50µm in the distal region. These data correspond to a regular implant-bone fit. Also the micromotion is on average larger in the medial-lateral plane than in the posterior-anterior plane.
If the implant deformations were not taken into account then the average values for micromotion were overestimated up to 20µm at proximal levels, and up to 140µm at distal levels.
Conclusion
Good initial stability is achieved in each case, suggesting a successful long-term outcome. These findings are consistent with a success rate of 96% reported for the used implant over an average of 10 years (Köster 2008). To adequately evaluate the initial stability of femoral implants, the non-rigid behaviour cannot be ignored.
Acknowledgments
This research is supported by BVOT (Belgian Association for Orthopaedics and Traumatology) and Impulse Fund KU Leuven.
