A Force-Feedback Methodology for Teleoperated Suturing Task in Robotic-Assisted Minimally Invasive Surgery

Ehrampoosh, Armin; Shirinzadeh, Bijan; Pinskier, Joshua; Smith, Julian Anderson; Moshinsky, Randall; Zhong, Yongmin

doi:10.3390/s22207829

Cited by 16 publications

(6 citation statements)

References 52 publications

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“…Robot-assisted minimally invasive surgery (RAMIS) is opening a new horizon for healthcare providers seeking a reliable solution for remote surgeries, but losing the sense of touch is a major shortcoming in RAMIS [61][62][63][64][65]. Due to the lack of haptic and tactile feedback, haptic feedback systems were introduced as a part of RAMIS units by Naghmeh M. Bandari et al [66].…”

Section: Tissue Distinction and Discontinuity Detection In Minimally ...mentioning

confidence: 99%

Recent Technological Progress of Fiber-Optical Sensors for Bio-Mechatronics Applications

Abdhul Rahuman,

Kahatapitiya,

Amarakoon

et al. 2023

Technologies

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Bio-mechatronics is an interdisciplinary scientific field that emphasizes the integration of biology and mechatronics to discover innovative solutions for numerous biomedical applications. The broad application spectrum of bio-mechatronics consists of minimally invasive surgeries, rehabilitation, development of prosthetics, and soft wearables to find engineering solutions for the human body. Fiber-optic-based sensors have recently become an indispensable part of bio-mechatronics systems, which are essential for position detection and control, monitoring measurements, compliance control, and various feedback applications. As a result, significant advancements have been introduced for designing and developing fiber-optic-based sensors in the past decade. This review discusses recent technological advancements in fiber-optical sensors, which have been potentially adapted for numerous bio-mechatronic applications. It also encompasses fundamental principles, different types of fiber-optical sensors based on recent development strategies, and characterizations of fiber Bragg gratings, optical fiber force myography, polymer optical fibers, optical tactile sensors, and Fabry–Perot interferometric applications. Hence, robust knowledge can be obtained regarding the technological enhancements in fiber-optical sensors for bio-mechatronics-based interdisciplinary developments. Therefore, this review offers a comprehensive exploration of recent technological advances in fiber-optical sensors for bio-mechatronics. It provides insights into their potential to revolutionize biomedical and bio-mechatronics applications, ultimately contributing to improved patient outcomes and healthcare innovation.

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Section: Tissue Distinction and Discontinuity Detection In Minimally ...mentioning

confidence: 99%

Recent Technological Progress of Fiber-Optical Sensors for Bio-Mechatronics Applications

Abdhul Rahuman,

Kahatapitiya,

Amarakoon

et al. 2023

Technologies

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“…Ehrampoosh et al presented a new force-sensing instrument that facilitates teleoperated robotic manipulation and semi-automates the suturing task. The end-effector mechanism of the instrument has a rotating degree of freedom to generate the ideal needle-insertion trajectory and to pass the needle through its curvature [ 17 ]. In [ 18 ], a modular 3-degrees-of-freedom (3DoF) force sensor that easily integrates with an existing minimally invasive surgical instrument was presented.…”

Section: Literature Reviewmentioning

confidence: 99%

Integration of Virtual Reality in the Control System of an Innovative Medical Robot for Single-Incision Laparoscopic Surgery

Covaciu

Crişan

Vaida

et al. 2023

Sensors

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In recent years, there has been an expansion in the development of simulators that use virtual reality (VR) as a learning tool. In surgery where robots are used, VR serves as a revolutionary technology to help medical doctors train in using these robotic systems and accumulate knowledge without risk. This article presents a study in which VR is used to create a simulator designed for robotically assisted single-uniport surgery. The control of the surgical robotic system is achieved using voice commands for laparoscopic camera positioning and via a user interface developed using the Visual Studio program that connects a wristband equipped with sensors attached to the user’s hand for the manipulation of the active instruments. The software consists of the user interface and the VR application via the TCP/IP communication protocol. To study the evolution of the performance of this virtual system, 15 people were involved in the experimental evaluation of the VR simulator built for the robotic surgical system, having to complete a medically relevant task. The experimental data validated the initial solution, which will be further developed.

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“…Hooshiar et al also proposed a novel force feedback mode based on magnetostriction [21]. In addition, Ehrampoosh et al proposed a novel force-sensing device based on indirect force estimation based on a data model for suturing in RMIS [22]. In which the operator obtains information about the needle-tissue interaction force simulation through an impedance-controlled sensing system.…”

Section: Operator Sensingmentioning

confidence: 99%

Application of tactile sensing in human-computer interaction in robot-assisted surgery and medical fields

Chen

2023

TNS

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Robot-assisted Minimally Invasive Surgery (RMIS) is a revolutionary breakthrough in the field of surgery in 21st-century clinical medicine, and in recent years it has become the standard of care in Western medicine. It makes highly accurate medical operations possible based on the advantages of traditional minimally invasive surgery, such as reducing patient trauma and accelerating post-operative healing. However, the most advanced robotic-assisted surgical systems available on the market, as exemplified by the da Vinci system, are still not equipped with tactile receptors. In recent years, scientists and engineers have come up with different techniques and ideas, including various forms of tactile sensors, to improve the quality of the process. In this paper, the sensor devices that can be used for RMIS are classified into six different types based on their structural characteristics, and typical examples of them are listed. For some of the sensing structures that are only in the theoretical stage, inferences and explanations are given based on references. And the application directions are summarized as tactile diagnosis and operator sensing. Research in the last decade in both areas of sensing technology is summarized and outlined respectively.

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A Force-Feedback Methodology for Teleoperated Suturing Task in Robotic-Assisted Minimally Invasive Surgery

Cited by 16 publications

References 52 publications

Recent Technological Progress of Fiber-Optical Sensors for Bio-Mechatronics Applications

Recent Technological Progress of Fiber-Optical Sensors for Bio-Mechatronics Applications

Integration of Virtual Reality in the Control System of an Innovative Medical Robot for Single-Incision Laparoscopic Surgery

Application of tactile sensing in human-computer interaction in robot-assisted surgery and medical fields

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