Difference between revisions of "2013 Summer Project Week:Epilepsy Surgery"

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<b>Classifier</b>
 
<b>Classifier</b>
 
<li>Once segmented, the images are analyzed using texture descriptors from the intensity histogram and local pixels dependence measures proposed by Haralick were extracted.  
 
<li>Once segmented, the images are analyzed using texture descriptors from the intensity histogram and local pixels dependence measures proposed by Haralick were extracted.  
Subsequently, the set of feature vectors from the segmented images is evaluated using three classifiers in WEKA environment.  
+
Subsequently, the set of feature vectors from the segmented images is evaluated using three classifiers in [http://www.cs.waikato.ac.nz/ml/weka/ WEKA] environment.  
 
<li>Images of 32 patients with TLE were used, 15 of those exhibiting blurring phenomenon in TL and 17 do not.  
 
<li>Images of 32 patients with TLE were used, 15 of those exhibiting blurring phenomenon in TL and 17 do not.  
 
<li>In total, a set of 98 planar images was segmented, and 51 are classified in "with blurring" category and 47 "without blurring" category.
 
<li>In total, a set of 98 planar images was segmented, and 51 are classified in "with blurring" category and 47 "without blurring" category.
Line 105: Line 105:
 
<li>As a result, from preselected 32 texture feature descriptors, 6 were shown to be relevant for classification of TL tissues.  
 
<li>As a result, from preselected 32 texture feature descriptors, 6 were shown to be relevant for classification of TL tissues.  
 
<li>Thus, we observe that using approach of texture analysis of segmented images, can helps the specialist to identify signal change MRIs in the temporal lobes of patients with TLE.
 
<li>Thus, we observe that using approach of texture analysis of segmented images, can helps the specialist to identify signal change MRIs in the temporal lobes of patients with TLE.
 +
<li>Once trained, classifier is easily included in this system, and can help surgery decision.
 
<li>Although these preliminary results are promising, the method still needs to be validated considering TL separatelly and in a larger image database.
 
<li>Although these preliminary results are promising, the method still needs to be validated considering TL separatelly and in a larger image database.
  
Line 111: Line 112:
 
<li>As a nest step, I´ll integrate the code to 3DSlicer.
 
<li>As a nest step, I´ll integrate the code to 3DSlicer.
 
<li>Try new schems of texture analisys to this application.
 
<li>Try new schems of texture analisys to this application.
<li>Extend these idea to cotical dysplasia: next year!
+
<li>Implement few machine learning algorithms, in addition to image processing in C++.
 +
<li>Speed up some time consumming algorithms with GPU programming.
 +
<li>Extend these and other ideas to cotical dysplasia: 2014 !
  
 
==References==
 
==References==
 
*Shaker, M. & Soltanian-Zadeh, H., 2008. Voxel-Based Morphometric Study of Brain Regions from Magnetic Resonance Images in Temporal Lobe Epilepsy. Image Analysis and Interpretation, 2008. SSIAI 2008. IEEE Southwest Symposium on, 209-212.
 
*Shaker, M. & Soltanian-Zadeh, H., 2008. Voxel-Based Morphometric Study of Brain Regions from Magnetic Resonance Images in Temporal Lobe Epilepsy. Image Analysis and Interpretation, 2008. SSIAI 2008. IEEE Southwest Symposium on, 209-212.

Latest revision as of 15:01, 21 June 2013

Home < 2013 Summer Project Week:Epilepsy Surgery

Key Investigators

  • USP - Luiz Murta

Objective

This project will investigate the presence and location of the epileptogenic focus in temporal lobe by analyzing patterns of texture in magnetic resonance imaging (MRI) after segmentation using anisotropic diffusion filters anomalous and geodesic active contour.

  • The Temporal Lobe Epilepsy (TLE) with hippocampal sclerosis affects other mesial temporal lobe structures, showing the change in signal intensity of white matter (WM) and gray matter (GM) in Magnetic Resonance Imaging (MRI) in patients with TLE.
  • Such abnormalities of signal intensity changes in the temporal lobes, or loss of marking between WM and GM are referred as blurring in literature.
  • TLE is the most common type of refractory epilepsy in adults, and thus strong candidate to surgery.

    Purpose
  • To provide a better quality of life for those with TLE, a surgical procedure is usually proposed for extracting the brain region that is the focus of epilepsy.
  • This project aims to implment a semi-automated method capable of locating lesions, that is difficult to be detected by visual inspection, is built to help experts identify tissues presenting blurring in temporal lobes.
  • The proposed software tool was developed in C + +, using three toolkits to support: VTK, ITK and QT.
  • To provide segmentation of the temporal lobes, we used the Geodesic Active Contour method combined with the anomalous anisotropic diffusion filter.

    • Progress

    Examples:
    Ex a.png
    Normal MRI at mesial temporal lobe

    Ex b.png
    MRI containing blurring phenomena on right side as indicated by the yellow arrow


    Methods

    Param.png ImageUI.png
    Default adjustable parameters, and original image,

    Segmented TL córtex SegmB.png SegmR.png


    Results

    Classifier

  • Once segmented, the images are analyzed using texture descriptors from the intensity histogram and local pixels dependence measures proposed by Haralick were extracted. Subsequently, the set of feature vectors from the segmented images is evaluated using three classifiers in WEKA environment.
  • Images of 32 patients with TLE were used, 15 of those exhibiting blurring phenomenon in TL and 17 do not.
  • In total, a set of 98 planar images was segmented, and 51 are classified in "with blurring" category and 47 "without blurring" category.
  • Of all three classifiers:
    -- artificial neural network;
    -- nearest neighbour;
    -- and decision tree
  • tested, the one based on "J48" decision tree had the best, and most interesting results.
  • 32 feature have been used to constructo descriptors vectors of segmented images:
    -- 24 were extracted from the co-occurrence matrix using Haralick texture descriptors and
    -- 8 were intensity statistics obtained from histogram.
  • When evaluating the performance of the three classifiers selected for the learning process, as a basis of 70 training samples and 28 test.
  • It was found that, for decision tree, precision and area under the ROC curve were 71.42 % and 69.30 %, respectively.
    TlNoblur.png HistNoblur.png no blurring TlBlurred.png HistBlurred.png blurring

    Decision Tree

    D_Hist_MeanIntensity <= 0.453
    | D_Hist_stdDev <= 0.138: with_blurring (5.0)
    | D_Hist_stdDev > 0.138
    | | E_Hist_Kurtosis <= 0.497
    | | | E_COOmeanHomogeneity_dist3 <= 0.425
    | | | | D_COOmeanHomogeneity_dist2 <= 0.318: without_blurring (9.0/2.0)
    | | | | D_COOmeanHomogeneity_dist2 > 0.318: with_blurring (5.0)
    | | | E_COOmeanHomogeneity_dist3 > 0.425
    | | | | E_COOmeanHomogeneity_dist3 <= 0.895: without_blurring (26.0/1.0)
    | | | | E_COOmeanHomogeneity_dist3 > 0.895: with_blurring (3.0/1.0)
    | | E_Hist_Kurtosis > 0.497: with_blurring (5.0)
    D_Hist_MeanIntensity > 0.453
    | E_Hist_Kurtosis <= 0.48: with_blurring (12.0)
    | E_Hist_Kurtosis > 0.48
    | | E_COOmeanHomogeneity_dist1 <= 0.432: with_blurring (3.0)
    | | E_COOmeanHomogeneity_dist1 > 0.432: without_blurring (2.0)
     Number of Leaves : 9

    • Conclusions

  • As a result, from preselected 32 texture feature descriptors, 6 were shown to be relevant for classification of TL tissues.
  • Thus, we observe that using approach of texture analysis of segmented images, can helps the specialist to identify signal change MRIs in the temporal lobes of patients with TLE.
  • Once trained, classifier is easily included in this system, and can help surgery decision.
  • Although these preliminary results are promising, the method still needs to be validated considering TL separatelly and in a larger image database.

    To do list:

  • As a nest step, I´ll integrate the code to 3DSlicer.
  • Try new schems of texture analisys to this application.
  • Implement few machine learning algorithms, in addition to image processing in C++.
  • Speed up some time consumming algorithms with GPU programming.
  • Extend these and other ideas to cotical dysplasia: 2014 !

    References

    • Shaker, M. & Soltanian-Zadeh, H., 2008. Voxel-Based Morphometric Study of Brain Regions from Magnetic Resonance Images in Temporal Lobe Epilepsy. Image Analysis and Interpretation, 2008. SSIAI 2008. IEEE Southwest Symposium on, 209-212.
    • Retrieved from "https://www.na-mic.org/w/index.php?title=2013_Summer_Project_Week:Epilepsy_Surgery&oldid=82778"