Projects:PathologyAnalysis

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Analysis of Brain Images Presenting Variety of Cerebral Lesion Types

Description

Whereas methodologies for segmentation of normal anatomical structures and tissue types has become standard and highly automated, tools for efficient and reliable segmentation of pathology lag behind. Major efforts on segmentation of lesions mostly focus on wm lesions as in multiple sclerosis and tumor/edema segmentation.

Driven by challenging image analysis problems of the NA-MIC DBP partner UCLA on traumatic brain injury (TBI), we will develop image segmentation methodology that helps clinical researcher to characterize and quantify a variety of different cerebral lesion types. Standard automated image analysis methods are not robust with respect to the TBI-related changes in image contrast, changes in brain shape, cranial fractures, lesions, white matter fiber alterations, and other signatures of head injury.

We are working on an extension of the "atlas-based classification" method ABC for TBI datasets with the clinical goal to efficiently segment healthy brain tissue and cerebral lesions. A main goal will be the automated segmentation of healthy brain tissue and user-assisted segmentation of various cerebral lesion types (hematoma, subarachnoid hemorrhage, contusion and DAI, perifocal (regional) to diffuse (generalized) edema, hemorrhagic diffuse axonal injury (DAI)and more. A strong emphasis will be on the joint analysis of multiple imaging modalities (T1 pre- and T1 postcontrast, T2 (TSE), FLAIR, GRE, SWI, Perfusion, and DTI/DWI) for improved detection and quantitative characterization of lesion types.

Multimodal MRI data of TBI patient.

Experiments: Multi-modal registration and tissue segmentation

We conducted experiments with the application of the ABC tool to multi-modal image data of 5 TBI cases provided by DBP partner UCLA. The tool includes co-registration of multiple modalities via mutual-information linear registration, and a nonlinear registration (high-deformable fluid registration) of a probabilistic normative atlas for segmentation of healthy tissue. The following results show feasibility of multi-modal registration and segmentation of normal tissue. Pathology is segmented via postprocessing using 3D user-supervised level-set evolution.

Case 1: Segmentation of 5channel TBI data with ABC. Lesions and ventricles segmented with additional 3D level-set segmentation.
Case 2: Segmentation of 5channel TBI data with ABC. Lesions and ventricles segmented with additional 3D level-set segmentation.
Case 3: Segmentation of 5channel TBI data with ABC. Lesions and ventricles segmented with additional 3D level-set segmentation.

Current work, jointly with the UCLA DBP partner, centers about a clinical definition of the most common lesion types and a multi-modality MRI characterization definition of these patterns. These characterizations will be used for the development of a segmentation methodology of the broad range of cerebral lesion types based on a user-guided definition of such patterns in current TBI cases.

Experiments: Registration of longitudinal data

The NA-MIC DBP project on TBI analysis (UCLA partner) includes serial multi-modal MRI at acute phase and follow-up after six months. We test mutual-information-based linear registration of multi-modal MRI data within each time point and nonlinear registration (b-spline) of follow-up scans to obtain sets of images mapped into the same coordinate system. Preliminary results demonstrate the large deformations due to mass effect of a large lesion but also significant large regional changes of multi-modal MRI contrast from actute to follow-up.


Longitudinal co-registration of multi-modal MRI.
Segmented white matter and temporal lobe (yellow) at acute phase and after 6 month follow-up.


Conclusion

In this work, we will develop new methodologies and tools for user-guided segmentation of cerebral lesions in multi-modal brain MRI. Driving application is TBI imaging research as conducted by the NA-MIC DBP partner UCLA. Components to be included will be robust clustering as presented in [4], initialization of multi-modal intensity patterns via prior knowledge [4], and evaluation of generative models as presented in [2] and [3]. Developments will also include efficient user-guidance for localization and characterization of subject-specific lesion patterns, and tools to provide quantitative measurements and indices of spatial extent of pathologies currently used in clinical assessment. We will evaluate extension of the commonly used indices derived from 2D images to 3D shape features.

Literature

[1] Bo Wang, Marcel Prastawa, Andrei Irimia, Micah C. Chambers, Paul M. Vespa, John D. van Horn, Guido Gerig, A Patient-Specific Segmentation Framework for Longitudinal MR Images of Traumatic Brain Injury, SPIE Medical Imaging 2012. (submitted)

[2] Prastawa M, Bullitt E, Gerig G, Simulation of brain tumors in MR images, Medical Image Analysis 13 (2009), pp. 297-311, PMID: 19119055

[3] Marcel Prastawa and Guido Gerig, Brain Lesion Segmentation through Physical Model Estimation, In Lecture Notes in Computer Science, Vol. 5358, pp. 562--571. 2008.

[4] Marcel Prastawa, John H. Gilmore, Weili Lin, Guido Gerig, Automatic Segmentation of MR Images of the Developing Newborn Brain, Medical Image Analysis (MedIA). Vol 9, October 2005, pages 457-466


Key Investigators

  • Utah: Bo Wang, Marcel Prastawa, Guido Gerig
  • UCLA: John D. Van Horn, Andrei Irimia, Micah Chambers / Clinical partners: Paul Vespa, M.D., David Hovda, M.D.


References