Trajectory-Optimized Sensing for Active Search of Tissue Abnormalities in Robotic Surgery

Salman, Hadi; Ayvali, Elif; Srivatsan, Rangaprasad Arun; Ma, Yan; Zevallos, Nicolas; Yasin, Rashid; Wang, Long; Simaan, Nabil; Choset, Howie

doi:10.1109/icra.2018.8460936

Cited by 22 publications

(21 citation statements)

References 25 publications

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“…In recent years, some researchers are studying automatic palpation algorithms applying Gaussian process regression and other algorithms to accelerate the palpation progress. 29,30 In future work, some artificial intelligence algorithms such as reinforcement learning and Bayesian optimization algorithm will be applied to obtain accurate tumor contour with as few measurements as possible.…”

Section: Resultsmentioning

confidence: 99%

A resonant tactile stiffness sensor for lump localization in robot-assisted minimally invasive surgery

Yun

Wang

Guo

et al. 2019

Proc Inst Mech Eng H

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A miniature resonant tactile sensor for tissue stiffness detection in robot-assisted minimally invasive surgery is proposed in this article. The proposed tactile sensor can detect tissue stiffness based on the principle of the resonant frequency shift when it contacts with tissue of different stiffness. A PZT (lead zirconate titanate) bimorph works simultaneously as the actuator and the sensing element, which is helpful for simplifying the structure. The resonant frequency shift can be deduced by measuring the electrical impedance of the PZT bimorph, since there will be an abrupt change of the impedance when resonance occurs. A unique structure of an Archimedean spiral metal sheet is introduced to restrict the outer size of the sensor within 10 mm and to keep the resonant frequency low. A theoretical model is established. Finite element method analyses are carried out to validate the working principle and it meets the theoretical model quite well. Several silicone samples are tested with the sensor and the results show that the proposed sensor is capable of measuring tissue stiffness within the range of 0–2 MPa, detecting and locating lumps inside tissue.

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Section: Resultsmentioning

confidence: 99%

A resonant tactile stiffness sensor for lump localization in robot-assisted minimally invasive surgery

Yun

Wang

Guo

et al. 2019

Proc Inst Mech Eng H

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“…Since only the point where the force is maximum are used for the estimation of the hard inclusion, this strategy can be considered as a hybrid method between the sweeping method and point by point method. Salman et al proposed an algorithm for a stiff probe that computes an optimal trajectory of sweeping palpation after based on prior knowledge obtained with point by point palpation [41]. They, in particular, have shown that switching from point by point to sweeping can save examination time.…”

Section: Plos Onementioning

confidence: 99%

Conditioned haptic perception for 3D localization of nodules in soft tissue palpation with a variable stiffness probe

Herzig

Maiolino

et al. 2020

PLoS ONE

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This paper provides a solution for fast haptic information gain during soft tissue palpation using a Variable Lever Mechanism (VLM) probe. More specifically, we investigate the impact of stiffness variation of the probe to condition likelihood functions of the kinesthetic force and tactile sensors measurements during a palpation task for two sweeping directions. Using knowledge obtained from past probing trials or Finite Element (FE) simulations, we implemented this likelihood conditioning in an autonomous palpation control strategy. Based on a recursive Bayesian inferencing framework, this new control strategy adapts the sweeping direction and the stiffness of the probe to detect abnormal stiff inclusions in soft tissues. This original control strategy for compliant palpation probes shows a sub-millimeter accuracy for the 3D localization of the nodules in a soft tissue phantom as well as a 100% reliability detecting the existence of nodules in a soft phantom.

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“…These methods model the stiffness map using a Gaussian process regression (GPR) and reduce the exploration time by directing the robot to stiff regions. While the objective of most prior works is to find the high stiffness regions [2], [4], [5], our recent work on active search explicitly encodes finding the location and the shape of the tumor as its objective [6].…”

Section: B Tumor Search Approachesmentioning

confidence: 99%

“…This work has been funded through the National Robotics Initiative by NSF grant IIS-1426655. While the works in literature deal with force sensing [10], [11], tumor localization [2], [4]- [6], [12] and graphical image overlays [13]- [16], there is a gap in literature when it comes to systems that deal with all these issues at the same time. For example, Yamamoto et al [16] deal with tumor localization and visual overlay, but they assume the organ is flat and place the organ on a force sensing plate, which is not representative of a surgical scenario.…”

Section: Introductionmentioning

confidence: 99%

A surgical system for automatic registration, stiffness mapping and dynamic image overlay

Zevallos

Srivatsan

Salman

et al. 2018

2018 International Symposium on Medical Robotics (ISMR)

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In this paper we develop a surgical system using the da Vinci research kit (dVRK) that is capable of autonomously searching for tumors and dynamically displaying the tumor location using augmented reality. Such a system has the potential to quickly reveal the location and shape of tumors and visually overlay that information to reduce the cognitive overload of the surgeon. We believe that our approach is one of the first to incorporate state-of-the-art methods in registration, force sensing and tumor localization into a unified surgical system. First, the preoperative model is registered to the intra-operative scene using a Bingham distribution-based filtering approach. An active level set estimation is then used to find the location and the shape of the tumors. We use a recently developed miniature force sensor to perform the palpation. The estimated stiffness map is then dynamically overlaid onto the registered preoperative model of the organ. We demonstrate the efficacy of our system by performing experiments on phantom prostate models with embedded stiff inclusions.

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Trajectory-Optimized Sensing for Active Search of Tissue Abnormalities in Robotic Surgery

Cited by 22 publications

References 25 publications

A resonant tactile stiffness sensor for lump localization in robot-assisted minimally invasive surgery

A resonant tactile stiffness sensor for lump localization in robot-assisted minimally invasive surgery

Conditioned haptic perception for 3D localization of nodules in soft tissue palpation with a variable stiffness probe

A surgical system for automatic registration, stiffness mapping and dynamic image overlay

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