Casals, Alicia; Hernansanz, Albert; Sayols, Narcís; Amat, Josep Assistance Strategies for Robotized Laparoscopy Conference Robot 2019: Fourth Iberian Robotics Conference, 2019, ISBN: 978-3-030-36149-5. Abstract | Links | BibTeX | Tags: Cooperative robotics, Laparoscopy, Robot, Safety, Surgery, Surgical robots, Virtual feedback Minelli, Marco; Ferraguti, Federica; Piccinelli, Nicola; Muradore, Riccardo; Secchi, Cristian Energy-Shared Two-Layer (Approach for Multi-Master-Multi-Slave) Bilateral Teleoperation Systems Conference 2019. Abstract | Links | BibTeX | Tags: Control architecture, Control programming, Laparoscopy, Robot, Surgical robots, Teleoperation, Telerobotics Oleari, Elettra; Leporini, Alice; Trojaniello, Diana; Sanna, Alberto; Capitanio, Umberto; Deho, Federico; Larcher, Alessandro; Montorsi, Francesco; Salonia, Andrea; Setti, Francesco; Muradore, Riccardo Enhancing Surgical Process Modeling for Artificial Intelligence Development in Robotics the SARAS Case Study for Minimally Invasive Procedures Journal Article pp. 1-6, 2019, ISBN: 978-1-7281-2342-4. Abstract | Links | BibTeX | Tags: Artificial Intelligence, Autonomy, Cognitive control, Cognitive functions, Decision making, Laparoscopes, Laparoscopy, Laparoscopy, learning systems, machine learning, Medical robotics, multirobots teleoperated platform, Robotic surgery, Surgery, Surgical robots, Teleoperation Setti, Francesco; Oleari, Elettra; Leporini, Alice; Trojaniello, Diana; Sanna, Alberto; Capitanio, Umberto; Montorsi, Francesco; Salonia, Andrea; Muradore, Riccardo 2019, ISBN: 978-1-5386-7825-1. Abstract | Links | BibTeX | Tags: Artificial Intelligence, Cognitive control, Computer Science, Laparoscopy, Laparoscopy, machine learning, Robot, Robotic surgery, Surgery, Teleoperation Hernansanz, Albert; Martínez, ; Rovira, ; Casals, Alicia A physical/virtual platform for hysteroscopy training Conference Proceedings of the 9th Joint Workshop on New Technologies for Computer/Robot Assisted Surgery, 2019. Abstract | Links | BibTeX | Tags: Computer Science, Endoscopy, Laparoscopy, Laparoscopy, Robot, Robotic Surgery, Robotic surgery, Surgery, Surgical robots, Training
2019
title = {Assistance Strategies for Robotized Laparoscopy},
author = {Alicia Casals and Albert Hernansanz and Narcís Sayols and Josep Amat},
editor = {Springer
},
url = {https://link.springer.com/chapter/10.1007%2F978-3-030-36150-1_40},
doi = {10.1007/978-3-030-36150-1_40},
isbn = {978-3-030-36149-5},
year = {2019},
date = {2019-11-20},
booktitle = {Robot 2019: Fourth Iberian Robotics Conference},
pages = {485-496},
abstract = {Robotizing laparoscopic surgery not only allows achieving better accuracy to operate when a scale factor is applied between master and slave or thanks to the use of tools with 3 DoF, which cannot be used in conventional manual surgery, but also due to additional informatic support. Relying on computer assistance different strategies that facilitate the task of the surgeon can be incorporated, either in the form of autonomous navigation or cooperative guidance, providing sensory or visual feedback, or introducing certain limitations of movements. This paper describes different ways of assistance aimed at improving the work capacity of the surgeon and achieving more safety for the patient, and the results obtained with the prototype developed at UPC.},
keywords = {Cooperative robotics, Laparoscopy, Robot, Safety, Surgery, Surgical robots, Virtual feedback},
pubstate = {published},
tppubtype = {conference}
}
title = {Energy-Shared Two-Layer (Approach for Multi-Master-Multi-Slave) Bilateral Teleoperation Systems},
author = {Marco Minelli and Federica Ferraguti and Nicola Piccinelli and Riccardo Muradore and Cristian Secchi},
url = {https://nxgsur-icra2019.sciencesconf.org/272549/document},
doi = {10.5281/zenodo.3362947 },
year = {2019},
date = {2019-05-20},
abstract = {In this paper, a two-layer architecture for the bilateral teleoperation of multi-arms systems with communication delay is presented. We extend the single-master-single-slave two layer approach proposed in [1] by connecting multiple robots to a single energy tank. This allows to minimize the conservativeness due to passivity preservation and to increment the level of transparency that can be achieved. The proposed approach is implemented on a realistic surgical scenario developed within the EU-funded SARAS project.
},
keywords = {Control architecture, Control programming, Laparoscopy, Robot, Surgical robots, Teleoperation, Telerobotics},
pubstate = {published},
tppubtype = {conference}
}
title = {Enhancing Surgical Process Modeling for Artificial Intelligence Development in Robotics the SARAS Case Study for Minimally Invasive Procedures},
author = {Elettra Oleari and Alice Leporini and Diana Trojaniello and Alberto Sanna and Umberto Capitanio and Federico Deho and Alessandro Larcher and Francesco Montorsi and Andrea Salonia and Francesco Setti and Riccardo Muradore},
editor = {IEEE},
doi = {10.1109/ISMICT.2019.8743931},
isbn = {978-1-7281-2342-4},
year = {2019},
date = {2019-05-09},
pages = {1-6},
abstract = {Nowadays Minimally Invasive Surgery (MIS) is playing an increasingly major role in the clinical practice also thanks to a rapid evolution of the available medical technologies, especially surgical robotics. A new challenge in this respect is to equip robots with cognitive capabilities, in order to make them able to act autonomously and cooperate with human surgeons. In this paper we describe the methodological approach developed to comprehensively describe a specific surgical knowledge, to be transferred to a complex Artificial Intelligence (AI) integrating Perception, Cognitive and Planning modules. Starting from desk researches and a strict cooperation with expert surgeons, the surgical process is framed on a high-level perspective, which is then deepened into a granular model through a Surgical Process Modelling approach, so as to embed all of the needed information by the AI to properly work. The model is eventually completed adding the corresponding Process Risk Analysis. We present the results obtained with the application of the aforementioned methodology to a Laparoscopic Radical Nephrectomy (LRN) procedure and discuss on the next technical implementation of this model.},
keywords = {Artificial Intelligence, Autonomy, Cognitive control, Cognitive functions, Decision making, Laparoscopes, Laparoscopy, Laparoscopy, learning systems, machine learning, Medical robotics, multirobots teleoperated platform, Robotic surgery, Surgery, Surgical robots, Teleoperation},
pubstate = {published},
tppubtype = {article}
}
title = {A Multirobots Teleoperated Platform for Artificial Intelligence Training Data Collection in Minimally Invasive Surgery},
author = {Francesco Setti and Elettra Oleari and Alice Leporini and Diana Trojaniello and Alberto Sanna and Umberto Capitanio and Francesco Montorsi and Andrea Salonia and Riccardo Muradore},
editor = {IEEE},
url = {http://bmvc2018.org/contents/papers/0593.pdf},
doi = {10.1109/ISMR.2019.8710209},
isbn = {978-1-5386-7825-1},
year = {2019},
date = {2019-05-09},
pages = {1-7},
abstract = {Dexterity and perception capabilities of surgical robots may soon be improved by cognitive functions that can support surgeons in decision making and performance monitoring, and enhance the impact of automation within the operating rooms. Nowadays, the basic elements of autonomy in robotic surgery are still not well understood and their mutual interaction is unexplored. Current classification of autonomy encompasses six basic levels: Level 0: no autonomy; Level 1: robot assistance; Level 2: task autonomy; Level 3: conditional autonomy; Level 4: high autonomy. Level 5: full autonomy. The practical meaning of each level and the necessary technologies to move from one level to the next are the subject of intense debate and development. In this paper, we discuss the first outcomes of the European funded project Smart Autonomous Robotic Assistant Surgeon (SARAS). SARAS will develop a cognitive architecture able to make decisions based on pre-operative knowledge and on scene understanding via advanced machine learning algorithms. To reach this ambitious goal that allows us to reach Level 1 and 2, it is of paramount importance to collect reliable data to train the algorithms. We will present the experimental setup to collect the data for a complex surgical procedure (Robotic Assisted Radical Prostatectomy) on very sophisticated manikins (i.e. phantoms of the inflated human abdomen). The SARAS platform allows the main surgeon and the assistant to teleoperate two independent two-arm robots. The data acquired with this platform (videos, kinematics, audio) will be used in our project and will be released (with annotations) for research purposes.},
keywords = {Artificial Intelligence, Cognitive control, Computer Science, Laparoscopy, Laparoscopy, machine learning, Robot, Robotic surgery, Surgery, Teleoperation},
pubstate = {published},
tppubtype = {conference}
}
title = {A physical/virtual platform for hysteroscopy training},
author = {Albert Hernansanz and Martínez and Rovira and Alicia Casals},
editor = {CRAS 2019},
doi = {10.5281/zenodo.3373297},
year = {2019},
date = {2019-03-21},
booktitle = {Proceedings of the 9th Joint Workshop on New Technologies for Computer/Robot Assisted Surgery},
abstract = {This work presents HysTrainer (HT), a training module for hysteroscopy, which is part of the generic endoscopic training platform EndoTrainer (ET). This platform merges both technologies, with the benefits of having a physical anatomic model and computer assistance for augmented reality and objective assessment. Further to the functions of a surgical trainer, EndoTrainer provides an integral education, training and evaluation platform.},
keywords = {Computer Science, Endoscopy, Laparoscopy, Laparoscopy, Robot, Robotic Surgery, Robotic surgery, Surgery, Surgical robots, Training},
pubstate = {published},
tppubtype = {conference}
}
Assistance Strategies for Robotized Laparoscopy Conference Robot 2019: Fourth Iberian Robotics Conference, 2019, ISBN: 978-3-030-36149-5. Energy-Shared Two-Layer (Approach for Multi-Master-Multi-Slave) Bilateral Teleoperation Systems Conference 2019. Enhancing Surgical Process Modeling for Artificial Intelligence Development in Robotics the SARAS Case Study for Minimally Invasive Procedures Journal Article pp. 1-6, 2019, ISBN: 978-1-7281-2342-4. 2019, ISBN: 978-1-5386-7825-1. A physical/virtual platform for hysteroscopy training Conference Proceedings of the 9th Joint Workshop on New Technologies for Computer/Robot Assisted Surgery, 2019.
2019