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A cadaver-based biomechanical model of acetabulum reaming for surgical virtual reality training simulators

Luigi Pelliccia, Mario Lorenz, Christoph‐E. Heyde, Maximilian Kaluschke, Philipp Klimant, Sebastian Knopp, Stefan Schleifenbaum, Christian Rotsch, René Weller, Michael Werner, Gabriel Zachmann, Dirk Zajonz, Niels Hammer

Year
2020
Citations
18
Access
Open access

Abstract

Total hip arthroplasty (THA) is a highly successful surgical procedure, but complications remain, including aseptic loosening, early dislocation and misalignment. These may partly be related to lacking training opportunities for novices or those performing THA less frequently. A standardized training setting with realistic haptic feedback for THA does not exist to date. Virtual Reality (VR) may help establish THA training scenarios under standardized settings, morphology and material properties. This work summarizes the development and acquisition of mechanical properties on hip reaming, resulting in a tissue-based material model of the acetabulum for force feedback VR hip reaming simulators. With the given forces and torques occurring during the reaming, Cubic Hermite Spline interpolation seemed the most suitable approach to represent the nonlinear force-displacement behavior of the acetabular tissues over Cubic Splines. Further, Cubic Hermite Splines allowed for a rapid force feedback computation below the 1 ms hallmark. The Cubic Hermite Spline material model was implemented using a three-dimensional-sphere packing model. The resulting forces were delivered via a human-machine-interaction certified KUKA iiwa robotic arm used as a force feedback device. Consequently, this novel approach presents a concept to obtain mechanical data from high-force surgical interventions as baseline data for material models and biomechanical considerations; this will allow THA surgeons to train with a variety of machining hardness levels of acetabula for haptic VR acetabulum reaming.

Keywords

Haptic technologyAcetabulumVirtual realityComputer scienceBiomechanicsDisplacement (psychology)SimulationBiomedical engineeringMedicineSurgery

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