Accurate three-dimensional virtual reconstruction of surgical field using calibrated trajectories of an image-guided medical robot

Gong, Yuanzheng; Hu, Danying; Hannaford, Blake; Seibel, Eric J.

doi:10.1117/1.jmi.1.3.035002

Cited by 13 publications

(21 citation statements)

References 56 publications

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“…Gong et al [27] showed the feasibility and quality of 3D target reconstruction in a curved phantom using the SFE mechanically scanned by same platform in this study (Figure 2). …”

Section: Problem Definition and Methodssupporting

confidence: 63%

Semi-autonomous simulated brain tumor ablation with RAVENII Surgical Robot using behavior tree

Gong

Hannaford

et al. 2015

2015 IEEE International Conference on Robotics and Automation (ICRA)

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Medical robots have been widely used to assist surgeons to carry out dexterous surgical tasks via various ways. Most of the tasks require surgeon’s operation directly or indirectly. Certain level of autonomy in robotic surgery could not only free the surgeon from some tedious repetitive tasks, but also utilize the advantages of robot: high dexterity and accuracy. This paper presents a semi-autonomous neurosurgical procedure of brain tumor ablation using RAVEN Surgical Robot and stereo visual feedback. By integrating with the behavior tree framework, the whole surgical task is modeled flexibly and intelligently as nodes and leaves of a behavior tree. This paper provides three contributions mainly: (1) describing the brain tumor ablation as an ideal candidate for autonomous robotic surgery, (2) modeling and implementing the semi-autonomous surgical task using behavior tree framework, and (3) designing an experimental simulated ablation task for feasibility study and robot performance analysis.

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“…Gong et al [27] showed the feasibility and quality of 3D target reconstruction in a curved phantom using the SFE mechanically scanned by same platform in this study (Figure 2). …”

Section: Problem Definition and Methodssupporting

confidence: 63%

Semi-autonomous simulated brain tumor ablation with RAVENII Surgical Robot using behavior tree

Gong

Hannaford

et al. 2015

2015 IEEE International Conference on Robotics and Automation (ICRA)

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“…As the extension work of our previous research [25,30], these advantages of BCBA can be utilized for intraoperatively reconstructing accurate 3D virtual models of the surgical field to extract the tumor coordinates, which requires highly efficient processing. These advantages also can be utilized to provide reliable estimation of camera poses for 3D image-guided surgery [31] and MIS.…”

Section: Discussionmentioning

confidence: 99%

“…To validate and compare two 3D reconstruction algorithms, an object with pre-known geometry was required. In this study, a 3D model was designed and 3D-printed out to mimic the surgical field [30], see Figs. 2(b) and 2(c).…”

Section: (A) Which Is Feasible To Minimal Invasive Surgery (Mis) Itmentioning

confidence: 99%

Bound constrained bundle adjustment for reliable 3D reconstruction

2015

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Abstract:Bundle adjustment (BA) is a common estimation algorithm that is widely used in machine vision as the last step in a feature-based three-dimensional (3D) reconstruction algorithm. BA is essentially a non-convex non-linear least-square problem that can simultaneously solve the 3D coordinates of all the feature points describing the scene geometry, as well as the parameters of the camera. The conventional BA takes a parameter either as a fixed value or as an unconstrained variable based on whether the parameter is known or not. In cases where the known parameters are inaccurate but constrained in a range, conventional BA results in an incorrect 3D reconstruction by using these parameters as fixed values. On the other hand, these inaccurate parameters can be treated as unknown variables, but this does not exploit the knowledge of the constraints, and the resulting reconstruction can be erroneous since the BA optimization halts at a dramatically incorrect local minimum due to its non-convexity. In many practical 3D reconstruction applications, unknown variables with range constraints are usually available, such as a measurement with a range of uncertainty or a bounded estimate. Thus to better utilize these pre-known, constrained, but inaccurate parameters, a bound constrained bundle adjustment (BCBA) algorithm is proposed, developed and tested in this study. A scanning fiber endoscope (the camera) is used to capture a sequence of images above a surgery phantom (the object) of known geometry. 3D virtual models are reconstructed based on these images and then compared with the ground truth. The experimental results demonstrate BCBA can achieve a more reliable, rapid, and accurate 3D reconstruction than conventional bundle adjustment.

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“…By robotically moving the tiny SFE or micro-camera, three-dimensional (3D) virtual reconstructions can be made for minimally-invasive disease surveillance 4 , guiding biopsy 2 , or planning surgical procedures 3 . By attaching the SFE to a calibrated robotic arm and scanning across a phantom of a cavity from debulked brain tumor with fluorescence targets representing residual tumor tissue, accurate 3D virtual reconstructions of the surgical field can be generated 5. …”

Section: Introductionmentioning

confidence: 99%

“…Without the surgeon in the loop, the RAVEN II currently does not provide accurate closed-loop servo control using the mechanical linkages and sensors within the robot arm, requiring an external measurement system for tracking the tip of the robot arm. To provide 0.5-mm accuracy of the scope/probe set during RAVEN procedures with a phantom of the debulked tumor cavity, an external stereo vision tracking system has been added 5 , but limitations restrict its use to more open surgical procedures by requiring constant environment lighting and direct line-of sight to the tip of the scope/tool set. Thus a new navigational system is required when the scope/tool set enters the debulked surgical cavity for residual tumor removal.…”

Section: Introductionmentioning

confidence: 99%

Toward real-time endoscopically-guided robotic navigation based on a 3D virtual surgical field model

Gong

Hannaford

et al. 2015

SPIE Proceedings

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The challenge is to accurately guide the surgical tool within the three-dimensional (3D) surgical field for robotically-assisted operations such as tumor margin removal from a debulked brain tumor cavity. The proposed technique is 3D image-guided surgical navigation based on matching intraoperative video frames to a 3D virtual model of the surgical field. A small laser-scanning endoscopic camera was attached to a mock minimally-invasive surgical tool that was manipulated toward a region of interest (residual tumor) within a phantom of a debulked brain tumor. Video frames from the endoscope provided features that were matched to the 3D virtual model, which were reconstructed earlier by raster scanning over the surgical field. Camera pose (position and orientation) is recovered by implementing a constrained bundle adjustment algorithm. Navigational error during the approach to fluorescence target (residual tumor) is determined by comparing the calculated camera pose to the measured camera pose using a micro-positioning stage. From these preliminary results, computation efficiency of the algorithm in MATLAB code is near real-time (2.5 sec for each estimation of pose), which can be improved by implementation in C++. Error analysis produced 3-mm distance error and 2.5 degree of orientation error on average. The sources of these errors come from 1) inaccuracy of the 3D virtual model, generated on a calibrated RAVEN robotic platform with stereo tracking; 2) inaccuracy of endoscope intrinsic parameters, such as focal length; and 3) any endoscopic image distortion from scanning irregularities. This work demonstrates feasibility of micro-camera 3D guidance of a robotic surgical tool.

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Accurate three-dimensional virtual reconstruction of surgical field using calibrated trajectories of an image-guided medical robot

Cited by 13 publications

References 56 publications

Semi-autonomous simulated brain tumor ablation with RAVENII Surgical Robot using behavior tree

Semi-autonomous simulated brain tumor ablation with RAVENII Surgical Robot using behavior tree

Bound constrained bundle adjustment for reliable 3D reconstruction

Toward real-time endoscopically-guided robotic navigation based on a 3D virtual surgical field model

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