Artikel
Diffusion tensor imaging data in brain tumor surgery
Diffusion Tensor Imaging – Dateneinbindung in der neurochirugischen Operationsplanung von Hirntumoren
Suche in Medline nach
Autoren
Veröffentlicht: | 11. April 2007 |
---|
Gliederung
Text
Objective: The goal of modern neurosurgical technics is the implementation of functional data into neurosurgical procedures. Therefore, the planning of surgical approaches has to combine morphological and functional data. DTI provides a reliable tool to visualize fiber tracts that can be integrated by image fusion with MRI in neuronavigational systems. This is especially helpful in glioma surgery, where the definition of clear tumor margins is difficult. The development of a three-dimensional representation of white matter fiber tracts may improve our knowledge and the reliability of fiber tracking.
Methods: Fourty patients with low and high grade gliomas in the vicinity of the pyramidal tract were analyzed with respect to dislocation, edema, infiltration and disruption. Preoperative visual analysis and mean fractional anisotropy have been evaluated with respect to neurological deficits. The intraoperative verification of the pyramidal tract was approached by intraoperative stimulation of the fiber tract. In addition, a new three-dimensional visualization technique of the white matter has been developed by use of diffusion tensor patterns, matching the fiber texture of the brain. The new technique allows six degrees of freedom to visualize tensor parameters compared to common techniques with only two degrees of freedom. This approach is expected to provide information about the reliability of the DT datasets which are important for the data interpretation.
Results: The evaluation of fourty patients demonstrates that a correlation to the clinical symptoms can be detected only in patients with a disruption of the pyramidal tract. This averages about 50%. Infiltration of the fibers by tumor cells cannot predict clinical symptoms. Intraoperative stimulation of the pyramidal tract is diffult to interpret in a neuronavigational system. Brain shift and edema cause unsolved problems. The three-dimensional diffusion tensor pattern is a promising technique for visualizing the brain fiber texture in explorative 3D datasets providing a more complete perception of the tumor adjacent tissue for the neurosurgeon.
Conclusions: Functional data, e.g., DTI provide an important tool for the planning of surgical approaches in brain tumors. The reliability of fiber tracking can be improved by three-dimensional visualization of the fibers and statistic approaches in future applications. Diffusion tensor patterns may be an appropriate method for gaining data that resemble the real morphological situation.