Slicer3:BrainLabModule
Contents
Aim
BrainLab (http://www.brainlab.com) has recently introduced a customized client/server architecture called VectorVision Link (VV Link) to communicate with external IGT environment. This software API, open but not free, allows other programs to receive tracking information and images from the BrainLab system. We propose to create a comprehensive workflow to interface 3D Slicer to BrainLab system and to use it for research. Specifically, we create easy steps for neurosurgeons to use Slicer to perform some research in DTI visualization in OR while using BrainLab as their primary navigation tool. Here is the scenario:
BrainLab system will still run as usual; we won't install any software and hardware on the BrainLab computer and won't affect its FDA status either. Slicer runs on a different computer. These two computers will be connected to each other using a network or router. During surgical procedures, the BrainLab sends real-time tracking data and/or images to Slicer. The tracking information may be used to seed dynamic DTI visualization in Slicer.
Research Plan
3D Slicer currently provides very basic technology for annotating images. This limits users in their ability to properly capture semantic information contained in images and data sets. We propose to address this issue by expanding Slicer's mark up and annotation capabilities. New features will include:
- a rich set of geometric objects for improved visual differentiation between annotations
- markers for measuring anatomical characteristics, such as the volume of an annotated region, to provide patient specific information difficult to extract from visual inspection
- entry fields beyond free-text, such as graphics and external data, to capture comprehensive information and support for emerging domain specific ontologiesand
- a full integration of these capabilities with the mrml tree to support Scenesnapshots, load, save both to disk and XNAT.
We will implement these features by developing two different modules. The first module, called Marker Module, creates different types of markers based on current ITK technology. The user defines the appearance of the marker by specifying its color, size, and shape, such as points and 3D boxes. The user also labels each marker with tags and specifies its function, such as measuring the volume of a region.
The Annotation Module, the second module, provides the interface for annotating images with these markers. Users place the markers on the image and further specify the semantic information through free text, plots, and references to ontology and internet. The annotations are shown both in 3D and 2D viewers. The module also allows annotating entire scenes by linking annotations across images, as well as within an image. All annotations are stored in a database targeted towards medical imaging, called XNAT. The structure of the database is automatically defined by the tags of the markers. Thus, users can query across large image data sets by looking for specific tag values.
Both modules are accompanied by training materials and documentation to ensure usability.
Design of Module
Key Personnel
Haiying Liu
Noby Hata
Ron Kikinnis
Progress
- 03/29/10
- Ron, Noby and Haiying met at Ron's office to discuss the specs of the module and time frame for implementation.
Dependency
The following modules are required for BrainLab module to work properly:
Fiducial
OpenIGTLink
DTMRI
FiducialSeeding