HiL simulation in biomechanics: A new approach for testing total joint replacements

Abstract Instability of artificial joints is still one of the most prevalent reasons for revision surgery caused by various influencing factors. In order to investigate instability mechanisms such as dislocation under reproducible, physiologically realistic boundary conditions, a novel test approach...

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Bibliographic Details
Published in:Computer methods and programs in biomedicine 2012-02, Vol.105 (2), p.109-119
Main Authors: Herrmann, Sven, Kaehler, Michael, Souffrant, Robert, Rachholz, Roman, Zierath, János, Kluess, Daniel, Mittelmeier, Wolfram, Woernle, Christoph, Bader, Rainer
Format: Article
Language:English
Subjects:
Biological and medical sciences
Biomechanical Phenomena
Computer Simulation
Dislocation
Equipment Failure Analysis - statistics & numerical data
Hardware-in-the-loop simulation
Humans
Instability
Internal Medicine
Joint Instability - etiology
Joint Instability - physiopathology
Joint Prosthesis - adverse effects
Joint simulator
Medical sciences
Multibody model
Other
Prosthesis Design
Radiotherapy. Instrumental treatment. Physiotherapy. Reeducation. Rehabilitation, orthophony, crenotherapy. Diet therapy and various other treatments (general aspects)
Range of Motion, Articular
Reoperation
Technology. Biomaterials. Equipments. Material. Instrumentation
Total joint replacement
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Summary:Abstract Instability of artificial joints is still one of the most prevalent reasons for revision surgery caused by various influencing factors. In order to investigate instability mechanisms such as dislocation under reproducible, physiologically realistic boundary conditions, a novel test approach is introduced by means of a hardware-in-the-loop (HiL) simulation involving a highly flexible mechatronic test system. In this work, the underlying concept and implementation of all required units is presented enabling comparable investigations of different total hip and knee replacements, respectively. The HiL joint simulator consists of two units: a physical setup composed of a six-axes industrial robot and a numerical multibody model running in real-time. Within the multibody model, the anatomical environment of the considered joint is represented such that the soft tissue response is accounted for during an instability event. Hence, the robot loads and moves the real implant components according to the information provided by the multibody model while transferring back the position and resisting moment recorded. Functionality of the simulator is proved by testing the underlying control principles, and verified by reproducing the dislocation process of a standard total hip replacement. HiL simulations provide a new biomechanical testing tool for analyzing different joint replacement systems with respect to their instability behavior under realistic movements and physiological load conditions.
ISSN:0169-2607
1872-7565
DOI:10.1016/j.cmpb.2011.07.012