Manipulating Soft Tissues by Deep Reinforcement Learning for Autonomous Robotic Surgery

Nguyen, Ngoc Duy; Nguyen, Thanh Thi; Nahavandi, Saeid; Bhatti, Asim; Guest, Glenn

doi:10.1109/syscon.2019.8836924

Cited by 23 publications

(10 citation statements)

References 36 publications

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“…It is possible, however, that such policies should be context-specific. Learning-based strategies, for instance based on recurrent networks or reinforcement paradigms 46 , have shown promise in producing optimal policies for robotic surgical tasks 47 . Subsequent efforts will investigate whether learned trajectories result in better performance outcomes compared to traditional methods of robotic control.…”

Section: Discussionmentioning

confidence: 99%

Deep learning robotic guidance for autonomous vascular access

et al. 2020

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Section: Discussionmentioning

confidence: 99%

Deep learning robotic guidance for autonomous vascular access

et al. 2020

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“…They implemented this approach using a dVRK in both simulated and physical scenarios. In later works, this method is improved with a multiple pinch point Deep RL algorithm that exhibits better results [93]- [94].…”

Section: Automation Of Surgical Tasksmentioning

confidence: 99%

A Review on Deep Learning in Minimally Invasive Surgery

et al. 2021

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In the last five years, deep learning has attracted great interest in computer-assisted systems for Minimally Invasive Surgery. The straightforward accessibility to images in surgical interventions makes deep neural networks enormously powerful for solving classification problems in complex surgical scenarios. The objective of this work is to provide readers a survey on deep learning models applied to minimally invasive surgery, identifying the different architectures used depending on the application, the results achieved until now, and the publicly available surgical datasets that can be used for validating new studies. A total of 85 publications have been extracted from manual research from four databases (IEEE Xplorer, Springer Link, Science Direct, and ACM Digital Library). After analyzing all these studies, they have been classified into four applications: surgical image analysis, surgical task analysis, surgical skill assessment, and automation of surgical tasks. This work provides a technical description of these works and a comparison among them. Finally, promising research directions to advance in this field are identified.

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“…DRL for soft-tissue manipulation: Previous works used a DRL based approach to learn a tensioning policy for surgical soft tissue multiple pinch point cutting task [15], [4]. Shin [3].…”

Section: Related Workmentioning

confidence: 99%

“…Recent efforts in surgical subtask automation have shown a surge in interest in employing data-driven approaches such as Deep Reinforcement Learning (DRL) [3], [4]. DRL has provided breakthrough success in other robotic domains, namely manipulation [5], navigation and locomotion tasks [6].…”

Section: Introductionmentioning

confidence: 99%

Safe Reinforcement Learning using Formal Verification for Tissue Retraction in Autonomous Robotic-Assisted Surgery

Pore¹,

Corsi²,

Marchesini³

et al. 2021

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Deep Reinforcement Learning (DRL) is a viable solution for automating repetitive surgical subtasks due to its ability to learn complex behaviours in a dynamic environment. This task automation could lead to reduced surgeon's cognitive workload, increased precision in critical aspects of the surgery, and fewer patient-related complications. However, current DRL methods do not guarantee any safety criteria as they maximise cumulative rewards without considering the risks associated with the actions performed. Due to this limitation, the application of DRL in the safety-critical paradigm of robot-assisted Minimally Invasive Surgery (MIS) has been constrained. In this work, we introduce a Safe-DRL framework that incorporates safety constraints for the automation of surgical subtasks via DRL training. We validate our approach in a virtual scene that replicates a tissue retraction task commonly occurring in multiple phases of an MIS. Furthermore, to evaluate the safe behaviour of the robotic arms, we formulate a formal verification tool for DRL methods that provides the probability of unsafe configurations. Our results indicate that a formal analysis guarantees safety with high confidence such that the robotic instruments operate within the safe workspace and avoid hazardous interaction with other anatomical structures.

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Manipulating Soft Tissues by Deep Reinforcement Learning for Autonomous Robotic Surgery

Cited by 23 publications

References 36 publications

Deep learning robotic guidance for autonomous vascular access

Deep learning robotic guidance for autonomous vascular access

A Review on Deep Learning in Minimally Invasive Surgery

Safe Reinforcement Learning using Formal Verification for Tissue Retraction in Autonomous Robotic-Assisted Surgery

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