Experimental Evaluation of a 3-Armed 6-DOF Parallel Robot for Femur Fracture Surgery

Alruwaili, Fayez; Saeedi-Hosseiny, Marzieh S.; Clancy, Michael P.; McMillan, Sean; Iordachita, Iulian; Abedinnasab, Mohammad H.

doi:10.1142/s2424905x22410094

J. Med. Robot. Res.

2022

DOI: 10.1142/s2424905x22410094

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Experimental Evaluation of a 3-Armed 6-DOF Parallel Robot for Femur Fracture Surgery

Fayez Alruwaili¹,

Marzieh S. Saeedi-Hosseiny²,

Michael P. Clancy³

et al.

Abstract: This paper presents the experimental position and force testing of a 3-armed 6-DOF Parallel Robot, Robossis, that is specifically designed for the application of long-bone femur fracture surgery. Current surgical techniques require a significant amount of time and effort to restore the fractured femur fragments’ length, alignment and rotation. To address these issues, the Robossis system will facilitate the femur fracture surgical procedure and oppose the large traction forces/torques of the muscle groups surr… Show more

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Cited by 2 publications

References 71 publications

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Analysis and Optimization of a 6-DoF 3-RRPS Parallel Mechanism for Robot-Assisted Long-Bone Fracture Surgery

Clancy,

Alruwaili,

Saeedi-Hosseiny

et al. 2023

Journal of Mechanisms and Robotics

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Robot-assisted femur repair has been of increased interest in recent literature due to the success of robot-assisted surgeries and current reoperation rates for femur fracture surgeries. The current limitation of robot-assisted femur fracture surgery is the lack of large force generation and sufficient workspace size in traditional mechanisms. To address these challenges, our group has created a 3-RRPS parallel mechanism, Robossis, which maintains the strength of parallel mechanisms while improving the translational and rotational workspace volume. In this paper, an optimal design methodology of parallel mechanisms for application to robot-assisted femur fracture surgery using a single-objective genetic algorithm is proposed. The genetic algorithm will use a single objective function to evaluate the various configurations based on the clinical and mechanical design criteria for femur fracture surgery as well as the global conditioning index. The objective function is composed of the desired translational and rotational workspaces based on the design criteria, the dynamic load-carrying capacity, and the homogenous-Jacobian global conditioning index. Lastly, experimental results of Robossis were obtained to validate the kinematic solution and the mechanism itself; Robossis had an average error of 0.31mm during experimental force testing.

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Analysis and Optimization of a 6-DoF 3-RRPS Parallel Mechanism for Robot-Assisted Long-Bone Fracture Surgery

Clancy,

Alruwaili,

Saeedi-Hosseiny

et al. 2023

Journal of Mechanisms and Robotics

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show abstract

Comprehensive Review of Noninvasive Brain-Computer Interfaces for Controlling Robotic Arms

Hamou,

Moufassih,

Tarahi

et al. 2024

J. Med. Robot. Res.

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A robotic arm is a mechanical device with a given number of Degrees of Freedom (DoFs) that mimics the functions of a human arm and performs any desired task, such as grasping and moving objects. Current research is directed toward the design of robots and artificial human body parts controlled by brain signals, translating human thoughts into actions. Brain-Computer Interface (BCI) systems have been used to enable people with motor disabilities to control assistive robotic equipment that replaces the lost functions. This paper presents a review of the state-of-the-art of the latest papers dealing with the control of a robotic arm based on Electroencephalogram (EEG). A comparative study of the different methods and techniques used in different blocks of the robotic arm’s noninvasive BCI controlling system is conducted. These blocks include signal acquisition using noninvasive electrodes, signal preprocessing, feature extraction, classification, and command. Additionally, this paper presents a performance comparison of the reviewed controlling systems of robotic arms using EEG signals.

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Experimental Evaluation of a 3-Armed 6-DOF Parallel Robot for Femur Fracture Surgery

Cited by 2 publications

References 71 publications

Analysis and Optimization of a 6-DoF 3-RRPS Parallel Mechanism for Robot-Assisted Long-Bone Fracture Surgery

Analysis and Optimization of a 6-DoF 3-RRPS Parallel Mechanism for Robot-Assisted Long-Bone Fracture Surgery

Comprehensive Review of Noninvasive Brain-Computer Interfaces for Controlling Robotic Arms

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