A Compact Stereotactic System for Image-guided Surgical Intervention

Overview

Journal J Neural Eng

Specialties Biomedical Engineering
Neurology

Date 2020 Nov 3

PMID 33142275

Citations 2

Authors

Aaron E Rusheen

Abhijeet S Barath

Abhinav Goyal

J Hudson Barnett

Benjamin T Gifford

Kevin E Bennet

Charles D Blaha

Stephan J Goerss

Yoonbae Oh

Kendall H Lee

Affiliations

Soon will be listed here.

Abstract

. Stereotactic technology enables fine navigation to small structures in the human body. While current stereotactic systems facilitate accurate targeting, they are mechanically cumbersome and limited in scope. Here, we hypothesized that a stereotactic system could be developed with a reduced footprint while maintaining broad targeting capabilities in order to improve versatility in frame placement location and surgical workflow.. We designed a stereotactic system around the center-of-arc principle, with mechanical properties that would enable a compact design and ample targeting and trajectory maneuverability. To examine the opportunity for a low-cost rapidly-deployable system we developed two fabrication variants, one using three dimensional (3D)-printing and the other using conventional machining. Mechanical and image-guided accuracies were tested in phantom studies using magnetic resonance imaging (MRI) and computed tomography. Using human cadaver head specimens, we assessed the system's surgical workflow and its ability to reliably and accurately implant electrodes in deep brain stimulation (DBS) surgery.. We developed a small 7.7 × 5.4 cmdevice platform that rigidly mounts to curvilinear bone and supports the attachment of surgical instrumentation. Attachment of two surgical instruments, an imaging localizer and a compact targeting device, demonstrated successful MRI-guided intervention in phantom studies with a vector error of 1.79 ± 0.41 mm. Evaluation of the 3D-printed system for DBS surgery confirmed ease of device platform attachment and instrument functionality, as well as demonstrated a surgical targeting accuracy of 1.83 ± 0.15 mm. In addition, we found the surgical time to be 78.3 ± 5.4 min for bilateral electrode implantation.. We developed a light and compact stereotactic system whose accuracy is on par with those used clinically. This technology is suitable for clinical translation and its flexibility in positioning will seamlessly expand the capabilities for stereotaxy to treat a wide range of conditions, both within neurosurgery and beyond.

Citing Articles

Expansion of stereotactic work envelope using transformation matrices and geometric algebra for neurosurgery.

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Development and validation of a rapidly deployable CT-guided stereotactic system for external ventricular drainage: preclinical study.

Barath A, Rusheen A, Rojas Cabrera J, Shin H, Blaha C, Bennet K Sci Rep. 2021; 11(1):17492.

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