%0 Journal Article %1 5676231 %A Rouse, E.J. %A Nahlik, D.C. %A Peshkin, M.A. %A Kuiken, T.A. %D 2011 %J Neural Systems and Rehabilitation Engineering, IEEE Transactions on %K Newton'soptimizationmethod Osseo-MagneticLink bonetranslations humeralcontrolsystem intuitiverotationalcontrol magnetmisalignment neodymium-iron-boronmagnet proprioception proprioceptivefeedback prostheticcontrolsystems prostheticrotator prostheticsocket residualbone sensorplacement three-axisHall-effectsensors transhumeralresiduallimb upper-limbprostheses wristrotationcontrolsystem biomechanics bone feedback magneticsensors mechanoception medicalcontrolsystems prosthetics Adult Algorithms Arm ArtificialLimbs BoneandBones ComputerSimulation Earth(Planet) ElectromagneticFields Humans Humerus Magnetics Male Models Anatomic ProsthesisDesign Radius Rotation %N 2 %P 213 -220 %R 10.1109/TNSRE.2010.2102365 %T Development of a Model Osseo-Magnetic Link for Intuitive Rotational Control of Upper-Limb Prostheses %V 19 %X The lack of proprioceptive feedback is a serious deficiency of current prosthetic control systems. The Osseo-Magnetic Link (OML) is a novel humeral or wrist rotation control system that could preserve proprioception. It utilizes a magnet implanted within the residual bone and sensors mounted in the prosthetic socket to detect magnetic field vectors and determine the bone's orientation. This allows the use of volitional bone rotation to control a prosthetic rotator. We evaluated the performance of the OML using a physical model of a transhumeral residual limb. A small Neodymium-Iron-Boron magnet was placed in a model humerus, inside a model upper arm. Four three-axis Hall-effect sensors were mounted on a ring 3 cm distal to the magnet. An optimization algorithm based on Newton's method determined the position and orientation of the magnet within the model humerus under various conditions, including bone translations, interference, and magnet misalignment. The orientation of the model humerus was determined within 3 #x00B0; for rotations centered in the arm; an additional 6 #x00B0; error was found for translations 20 mm from center. Adjustments in sensor placement may reduce these errors. The results demonstrate that the OML is a feasible solution for providing prosthesis rotation control while preserving rotational proprioception.

@article{5676231, abstract = {The lack of proprioceptive feedback is a serious deficiency of current prosthetic control systems. The Osseo-Magnetic Link (OML) is a novel humeral or wrist rotation control system that could preserve proprioception. It utilizes a magnet implanted within the residual bone and sensors mounted in the prosthetic socket to detect magnetic field vectors and determine the bone's orientation. This allows the use of volitional bone rotation to control a prosthetic rotator. We evaluated the performance of the OML using a physical model of a transhumeral residual limb. A small Neodymium-Iron-Boron magnet was placed in a model humerus, inside a model upper arm. Four three-axis Hall-effect sensors were mounted on a ring 3 cm distal to the magnet. An optimization algorithm based on Newton's method determined the position and orientation of the magnet within the model humerus under various conditions, including bone translations, interference, and magnet misalignment. The orientation of the model humerus was determined within 3 #x00B0; for rotations centered in the arm; an additional 6 #x00B0; error was found for translations 20 mm from center. Adjustments in sensor placement may reduce these errors. The results demonstrate that the OML is a feasible solution for providing prosthesis rotation control while preserving rotational proprioception.}, added-at = {2012-01-13T16:31:04.000+0100}, author = {Rouse, E.J. and Nahlik, D.C. and Peshkin, M.A. and Kuiken, T.A.}, biburl = {https://www.bibsonomy.org/bibtex/28c6458d1a3779657014abeb707c1eebd/bunke}, doi = {10.1109/TNSRE.2010.2102365}, groups = {public}, interhash = {c3a5fd74a9f2631fcbfec1d5aa986392}, intrahash = {8c6458d1a3779657014abeb707c1eebd}, issn = {1534-4320}, journal = {Neural Systems and Rehabilitation Engineering, IEEE Transactions on}, keywords = {Newton'soptimizationmethod Osseo-MagneticLink bonetranslations humeralcontrolsystem intuitiverotationalcontrol magnetmisalignment neodymium-iron-boronmagnet proprioception proprioceptivefeedback prostheticcontrolsystems prostheticrotator prostheticsocket residualbone sensorplacement three-axisHall-effectsensors transhumeralresiduallimb upper-limbprostheses wristrotationcontrolsystem biomechanics bone feedback magneticsensors mechanoception medicalcontrolsystems prosthetics Adult Algorithms Arm ArtificialLimbs BoneandBones ComputerSimulation Earth(Planet) ElectromagneticFields Humans Humerus Magnetics Male Models Anatomic ProsthesisDesign Radius Rotation}, month = {april }, number = 2, pages = {213 -220}, timestamp = {2012-01-13T16:31:04.000+0100}, title = {Development of a Model Osseo-Magnetic Link for Intuitive Rotational Control of Upper-Limb Prostheses}, username = {bunke}, volume = 19, year = 2011 }