Can concentric tube robots follow the leader?

Gilbert, Hunter B.; Webster, Robert J.

doi:10.1109/icra.2013.6631274

Cited by 29 publications

(18 citation statements)

References 26 publications

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“…Concentric tube needle steering does not rely on the surrounding tissue medium to achieve a curved path and, because of this, can be used in both free space [6], [7] and tissue-embedded applications [12]. However, it requires a priori design of the component tubes [13], and so does not offer as much variability in the final trajectory within tissue. Tip steering has the advantage of typically traveling along a “follow the leader” trajectory, where the shaft follows the path of the tip, and steerability is largely unaffected by insertion depth.…”

Section: Introductionmentioning

confidence: 99%

Sliding Mode Control of Steerable Needles

et al. 2013

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Steerable needles can potentially increase the accuracy of needle-based diagnosis and therapy delivery, provided they can be adequately controlled based on medical image information. We propose a novel sliding mode control law that can be used to deliver the tip of a flexible asymmetric-tipped needle to a desired point, or to track a desired trajectory within tissue. The proposed control strategy requires no a priori knowledge of model parameters, has bounded input speeds, and requires little computational resources. We show that if the standard nonholonomic model for tip-steered needles holds, then the control law will converge to desired targets in a reachable workspace, within a tolerance that can be defined by the control parameters. Experimental results validate the control law for target points and trajectory following in phantom tissue and ex vivo liver. Experiments with targets that move during insertion illustrate robustness to disturbances caused by tissue deformation.

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Section: Introductionmentioning

confidence: 99%

Sliding Mode Control of Steerable Needles

et al. 2013

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“…This result can be generalized if the robot design enables the trivial solution of (5) to be applied over m subintervals of s c ∈[0, L c ], each of which can be taken as constant curvature yielding an overall curve of piecewise constant curvature,

u_{r} false(s_{r} false) = u_{c} false(s_{c} false) = {\begin{cases} c_{1}, & \forall s_{c} \in [0, s_{c 1}] \\ c_{2}, & \forall s_{c} \in (s_{c 1}, s_{c 2}] \\ c_{3}, & \forall s_{c} \in (s_{c 2}, s_{c 3}] \\ \dots \\ c_{n}, & \forall s_{c} \in (s_{c, m - 1}, L_{c}] \end{cases}

As shown below, applying these geometric results for follow-the-leader extension on concentric tube robots is straightforward. Follow-the-leader conditions are also considered in [24]. …”

Section: Robot Designmentioning

confidence: 99%

“…This has been considered in detail for arcs in, e.g., [8] and initial results for helices appear in [24]. Without loss of generality and to further reduce the number of design parameters, only arcs are considered in the remainder of this paper.…”

Section: Robot Designmentioning

confidence: 99%

Concentric Tube Robot Design and Optimization Based on Task and Anatomical Constraints

et al. 2015

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Concentric tube robots are catheter-sized continuum robots that are well suited for minimally invasive surgery inside confined body cavities. These robots are constructed from sets of pre-curved superelastic tubes and are capable of assuming complex 3D curves. The family of 3D curves that the robot can assume depends on the number, curvatures, lengths and stiffnesses of the tubes in its tube set. The robot design problem involves solving for a tube set that will produce the family of curves necessary to perform a surgical procedure. At a minimum, these curves must enable the robot to smoothly extend into the body and to manipulate tools over the desired surgical workspace while respecting anatomical constraints. This paper introduces an optimization framework that utilizes procedureor patient-specific image-based anatomical models along with surgical workspace requirements to generate robot tube set designs. The algorithm searches for designs that minimize robot length and curvature and for which all paths required for the procedure consist of stable robot configurations. Two mechanics-based kinematic models are used. Initial designs are sought using a model assuming torsional rigidity. These designs are then refined using a torsionally-compliant model. The approach is illustrated with clinically relevant examples from neurosurgery and intracardiac surgery.

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“…Potential roles for steerable needles in Urologic Surgery include biopsy and ablation delivery to previously unreachable or inaccessible areas combined with precise control and non-linear path control. [36-38]…”

Section: Concentric Tube Robots: Steerable Needles and Beyondmentioning

confidence: 99%

Future robotic platforms in urologic surgery

Herrell

Webster

Simaan

2014

Current Opinion in Urology

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Purpose of review To review recent developments at Vanderbilt University of new robotic technologies and platforms designed for minimally invasive urologic surgery and their design rationale and potential roles in advancing current urologic surgical practice. Recent findings Emerging robotic platforms are being developed to improve performance of a wider variety of urologic interventions beyond the standard minimally invasive robotic urologic surgeries conducted presently with the da Vinci platform. These newer platforms are designed to incorporate significant advantages of robotics to improve the safety and outcomes of transurethral bladder surgery and surveillance, further decrease the invasiveness of interventions by advancing LESS surgery, and allow for previously impossible needle access and ablation delivery. Summary Three new robotic surgical technologies that have been developed at Vanderbilt University are reviewed, including a robotic transurethral system to enhance bladder surveillance and TURBT, a purpose-specific robotic system for LESS, and a needle sized robot that can be used as either a steerable needle or small surgeon-controlled micro-laparoscopic manipulator.

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Can concentric tube robots follow the leader?

Cited by 29 publications

References 26 publications

Sliding Mode Control of Steerable Needles

Sliding Mode Control of Steerable Needles

Concentric Tube Robot Design and Optimization Based on Task and Anatomical Constraints

Future robotic platforms in urologic surgery

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