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Patient-Specific Virtual Reality Simulation for Minimally Invasive Neurosurgery

  • Ralf A. Kockro
  • Luis Serra
Chapter
Part of the Comprehensive Healthcare Simulation book series (CHS)

Abstract

The Dextroscope is a surgical planning system that takes advantage of some of the key aspects of virtual reality to maximize the potential of multimodal patient data: two-handed input in 3D and stereoscopic volume-rendering visualization of 3D data. 3D patient models are manipulated in 3D by the surgeon in an easy, intuitive, and flexible manner, without the limitations imposed by mouse and keyboard. It features additionally comprehensive software tools for data segmentation, simulated bone drilling, and simulation of intraoperative views. The Dextrobeam was introduced for use as an educational tool for students and practitioners of anatomy and surgery. It was used in a number of international medical courses and teaching departments.

In order to take full advantage in the operating room of the 3D models created by the Dextroscope, the DEX-Ray augmented reality navigation system was developed. It featured a handheld tracked probe incorporating a video camera, which overlaid 3D virtual patient information over a video stream, to achieve unambiguous intraoperative image guidance.

The Dextroscope was applied mainly to neurosurgery, but it was also used in other specialties presenting a surgical challenge – an anatomical or structural complexity that requires planning of the surgical (or interventional) approach, for example, ENT, orthopedic, trauma, craniofacial, and liver surgery.

Keywords

3D human–computer interaction Virtual reality Neurosurgery Surgical planning software Medical education Dextroscope Dextrobeam DEX-Ray Surgery planning Augmented reality surgery navigation 3D interactions Stereoscopic display 

Notes

Acknowledgments

The Dextroscope, Dextrobeam, DEX-Ray, and DextroVision were developed by Volume Interactions Pte Ltd, a company member of the Bracco Group (Milan, Italy). Volume Interactions was based in Singapore and was a spin-off from the Kent Ridge Digital Labs (now Institute for Infocom Research) in Singapore.

The Dextroscope and Dextrobeam products received USA FDA 510(K)-Class II (2002) clearance, CE Marking-Class I (2002), China SFDA Registration-Class II (2004) and Taiwan Registration-type P (Radiology) (2007). DEX-Ray and DextroVision were research prototypes.

Supplementary material

Video 13.1

Interactions in the Dextroscope

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Copyright information

© Springer International Publishing AG, part of Springer Nature 2018

Authors and Affiliations

  1. 1.Department of NeurosurgeryHirslanden HospitalZurichSwitzerland
  2. 2.Galgo Medical SLBarcelonaSpain

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