Influence of the Localization Strategy on the Accuracy of a Neurosurgical Robot System

Šuligoj, Filip; Jerbić, Bojan; Šekoranja, Bojan; Vidaković, Josip; Švaco, Marko

doi:10.21278/tof.42203

Cited by 6 publications

(3 citation statements)

References 25 publications

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“…Based on the localization of 20 points uniformly distributed inside the phantom, the mean Euclidean error is 1.19±0.76mm. However, authors expect larger positioning errors when scanning uneven surfaces, due to changes in orientation of the robot end-effector [36].…”

Section: Resultsmentioning

confidence: 99%

RobUSt–An Autonomous Robotic Ultrasound System for Medical Imaging

et al. 2021

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Medical ultrasound (US) systems are widely used for the diagnosis of internal tissues. However, there are challenges associated with acquiring and interpreting US images, such as incorrect US probe placement and limited available spatial information. In this study, we expand the capabilities of medical US imaging using a robotic framework with a high level of autonomy. A 3D camera is used to capture the surface of an anthropomorphic phantom as a point cloud, which is then used for path planning and navigation of the US probe. Robotic positioning of the probe is realised using an impedance controller, which maintains stable contact with the surface during US scanning and compensates for uneven and moving surfaces. Robotic US positioning accuracy is measured to be 1.19±0.76mm. The mean force along US probe z-direction is measured to be 6.11±1.18N on static surfaces and 6.63±2.18N on moving surfaces. Overall lowest measured force of 1.58N demonstrates constant probe-to-surface contact during scanning. Acquired US images are used for the 3D reconstruction and multi-modal visualization of the surface and the inner anatomical structures of the phantom. Finally, K-means clustering is used to segment different tissues. Best segmentation accuracy of the jugular vein according to Jaccard similarity coefficient is measured to be 0.89. With such an accuracy, this system could substantially improve autonomous US acquisition and enhance the diagnostic confidence of clinicians.

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Section: Resultsmentioning

confidence: 99%

RobUSt–An Autonomous Robotic Ultrasound System for Medical Imaging

et al. 2021

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“…The screw caps have a mechanical interface for standard medical retroreflective snap-fit spherical markers (NDI – Northern Digital Inc., Waterloo, Canada). When it comes to software features, RONNA G4 uses a new and improved algorithm for autonomous localization of fiducial markers in the image space ( 24 ), an algorithm for robot position planning with respect to the patient in the physical space ( 25 ), a novel pair-point correspondence algorithm for the patient registration from the image space to the physical space ( 30 ), and a novel method for determining an optimal robot localization strategy in the physical space ( 31 ). Other major features that differentiate the RONNA G4 from the current state of-the-art robotic neuronavigation systems are a specifically designed universal mobile platform ( 32 ) and a new and accurate non-contact localization system ( 18 ).…”

Section: Discussionmentioning

confidence: 99%

Clinical application of the RONNA G4 system – preliminary validation of 23 robotic frameless brain biopsies

Dlaka¹,

Švaco²,

Chudy³

et al. 2021

Croat Med J

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Aims To report the outcomes of robot-assisted brain biopsies performed using a novel RONNA G4 system. The system was developed by a research group from the Faculty of Mechanical Engineering and Naval Architecture and a team of neurosurgeons from Dubrava University Hospital, University of Zagreb School of Medicine. Methods This prospective study included 49 biopsies analyzed during one year: 23 robotic frameless and 26 frame-based Leksell stereotactic biopsies. We analyzed the presenting symptoms, tumor range and location, postoperative complications, pathohistological diagnosis, diagnostic yield, as well as operation and hospitalization duration. The target point error was calculated to assess the accuracy of the RONNA system. Results No postoperative mortality, morbidity, or infections were observed. In the frameless robotic biopsy group, only one pathohistological diagnosis was inconclusive. Therefore, the diagnostic yield was 95.6% (22/23), similar to that of the framebased Leksell stereotactic biopsy group (95.1% or 25/26). The average target point error in the frameless robotic biopsy group was 2.15 ± 1.22 mm (range 0.39-5.85). Conclusion The RONNA G4 robotic system is a safe and accurate tool for brain biopsy, although further research warrants a larger patient sample, comparison with other robotic systems, and a systematic analysis of the entry and target point errors.

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“…Finally, the minimal enclosing circle is fitted to acquire the centre coordinates and the radius of the circular marker. Since the RONNA robot is an articulated six‐joint revolute robot, we have experimentally evaluated multiple localisation strategies; the evaluation results are presented in our earlier research 30 . The strategy that significantly improves the robot positioning accuracy is the orientation correction strategy (OCS) in which the tool orientation (three Euler angles) is kept constant in the localisation and operation phases.…”

Section: Sequence Of Operations In Neurosurgical Procedures With Ronnamentioning

confidence: 99%

Frameless stereotactic brain biopsy: A prospective study on robot‐assisted brain biopsies performed on 32 patients by using the RONNA G4 system

Dlaka

Švaco

Chudy

et al. 2021

Robotics Computer Surgery

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Background We present a novel robotic neuronavigation system (RONNA G4), used for precise preoperative planning and frameless neuronavigation, developed by a research group from the University of Zagreb and neurosurgeons from the University Hospital Dubrava, Zagreb, Croatia. The aim of study is to provide comprehensive error measurement analysis of the system used for the brain biopsy. Methods Frameless stereotactic robot‐assisted biopsies were performed on 32 consecutive patients. Post‐operative CT and MRI scans were assessed to precisely measure and calculate target point error (TPE) and entry point error (EPE). Results The application accuracy of the RONNA system for TPE was 1.95 ± 1.11 mm, while for EPE was 1.42 ± 0.74 mm. The total diagnostic yield was 96.87%. Linear regression showed statistical significance between the TPE and EPE, and the angle of the trajectory on the bone. Conclusion The RONNA G4 robotic system is a precise and highly accurate autonomous neurosurgical assistant for performing frameless brain biopsies.

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Influence of the Localization Strategy on the Accuracy of a Neurosurgical Robot System

Cited by 6 publications

References 25 publications

RobUSt–An Autonomous Robotic Ultrasound System for Medical Imaging

RobUSt–An Autonomous Robotic Ultrasound System for Medical Imaging

Clinical application of the RONNA G4 system – preliminary validation of 23 robotic frameless brain biopsies

Frameless stereotactic brain biopsy: A prospective study on robot‐assisted brain biopsies performed on 32 patients by using the RONNA G4 system

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