On the Control and Validation of the PARA-SILSROB Surgical Parallel Robot

This paper presents the development of the hardware and software architecture of a sixdegrees of freedom (DOF) parallel robot (PARA-SILSROB) by illustrating all the stages undertaken to achieve the experimental model of the robot. Based on the experimental model, the control architecture is also pre...

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Bibliographic Details
Published inApplied sciences Vol. 14; no. 17; p. 7925
Main Authors Pisla, Doina, Popa, Calin, Pusca, Alexandru, Ciocan, Andra, Gherman, Bogdan, Mois, Emil, Cailean, Andrei-Daniel, Vaida, Calin, Radu, Corina, Chablat, Damien, Hajjar, Nadim Al
Format Journal Article
LanguageEnglish
Published Basel MDPI AG 05.09.2024
Multidisciplinary digital publishing institute (MDPI)
Subjects
Cameras
Computer Science
Design
Ergonomics
esophageal cancer
esophagectomy
experimental test
FDA approval
Kinematics
Laparoscopy
Learning curves
parallel robot
robot-assisted surgery
Robotics
Robots
Surgeons
Surgery
Surgical apparatus & instruments
surgical robot
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Summary:This paper presents the development of the hardware and software architecture of a sixdegrees of freedom (DOF) parallel robot (PARA-SILSROB) by illustrating all the stages undertaken to achieve the experimental model of the robot. Based on the experimental model, the control architecture is also presented, which is primarily based on a master–slave control system through which the surgeon controls the robot using the master console composed of commercial peripheral components (two 3D Space Mouse devices, computer, and keyboard) integrated with the solution developed in this study and presented in this paper. The robot was developed also according to the surgical protocol and surgeon’s requirements, and for the functionality testing of the mechanical structure, two experimental stands were used. The first stand presented several surgical steps, such as manipulation, resection, and suture of experimental tissues (simulating real-life robot-assisted surgical maneuvers) using commercial instruments. The second stand presented a simulation of an esophagectomy for esophageal cancer and digestive reconstruction through a right intercostal approach. For this testing phase, the organs were created using 3D reconstruction, and their simplified models were 3D printed using PolyJet technology. Furthermore, the input trajectory generated using the master console was compared with the robot actuator’s movements and the obtained results were used for validation of the proposed robot control system.
ISSN:2076-3417
2076-3417
DOI:10.3390/app14177925