KEYWORDS: Liver, Data modeling, Image registration, Computing systems, Surgery, Data processing, Image-guided intervention, Data acquisition, Process modeling, Data integration
Acquiring and incorporating intraoperative data into image-guided surgical systems has been shown to increase the
accuracy of these systems and the accuracy of image-guided surgical procedures. Even with the advent of powerful
computers and parallel clusters, the ability to integrate highly resolved computer model information in the planning and
execution of image-guided surgery is challenging. More often than not, the computational times required to process
preoperative models and incorporate intraoperative data for feedback are too cumbersome and do not meet the real time
constraints of surgery, for both planning and intraoperative guidance. To decrease the computational time for the
surgeon and minimize the resources in the operating room, we have developed a dual compute node framework for
image-guided surgical procedures: (i) a high-capability compute resource which acts as a server to facilitate preoperative
planning, and (ii) a low-capability compute resource which acts as a server node/compute node to process the
intraoperative data and rapidly integrate the model-based analysis for therapeutic/surgical feedback. In this framework,
the preoperative planning utilities and intraoperative guidance system act as client-nodes/graphics-nodes that are assisted
by the model-assistant. Processed data is transferred back to the graphics node for planning display or intraoperative
feedback depending on which resource is engaged. In order to efficiently manage the data and the computational
resources we also developed a novel software manager. This dual-capability resource compute node concept and the
software manager are reported in this work, and the low-capability resource compute node is investigated within the
context of image-guided liver surgery using data acquired during hepatic tumor resection therapies. Preliminary results
indicate that the dual node concept can significantly decrease the computational resources and time required for image-guided
surgical procedures.
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