CranialVault and its CRAVE tools: A clinical computer assistance system for deep brain stimulation (DBS) therapy

D’Haese, Pierre-François; Pallavaram, Srivatsan; Li, Rui; Remple, Michael S.; Kao, Chris; Neimat, Joseph S.; Konrad, Peter E.; Dawant, Benoît M.

doi:10.1016/j.media.2010.07.009

Cited by 97 publications

(68 citation statements)

References 43 publications

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“…This goal requires the removal of individual patient variations (i.e., size of the brain and skull) and reformatting clinical data into a common, uniform pattern, such as an atlas or standard view, so that pathological variations can be recognizable when removed from the individual patient context; 2) The second goal is then to take those patterns, warp them back to an individual patient's morphology or function, and see if abnormalities apply to a specific patient, i.e. to help with diagnosis or etiology of the disease, or to treat a specific disease (D'Hasese et al 2010). For example, this may involve taking a standard brain view or atlas and warping to an individual patient scan to identify a specific region of the brain for treatment targeting.…”

Section: Neuroinformatics Goals For Clinical Datamentioning

confidence: 99%

“…However, in many of these databases the data [i.e., brain magnetic resonance imaging (MRI) or computed tomography (CT)] were acquired specifically for particular research purposes, with the requisite cross-site validation and calibration efforts, to enable coherent assembly of the data across a particular class of patients. Another example is a tightly-defined database of neuroimaging and physiological data, designed to be helpful for planning an individual surgical intervention on patients (D'Hasese et al 2010). These well-defined data sets are critical for the development of imaging biomarkers that will aid in assessing treatment response, and making prognostic and diagnostic assessments of future patients.…”

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confidence: 99%

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Neuroinformatics in Clinical and Translational Medicine—Novel Approaches

Gollub

Turner

2010

Neuroinform

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Section: Neuroinformatics Goals For Clinical Datamentioning

confidence: 99%

mentioning

confidence: 99%

Neuroinformatics in Clinical and Translational Medicine—Novel Approaches

Gollub

Turner

2010

Neuroinform

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“…Our dataset contains images of 201 individuals from the data repository we have created over a decade for deep brain stimulation (DBS) surgeries [3]. All these images are T1-weighted sagittal MR image volumes with approximately 256×256×170 1 mm 3 isotropic voxels.…”

Section: Introductionmentioning

confidence: 99%

Automatic selection of landmarks in T1-weighted head MRI with regression forests for image registration initialization

et al. 2017

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Medical image registration establishes a correspondence between images of biological structures and it is at the core of many applications. Commonly used deformable image registration methods are dependent on a good preregistration initialization. The initialization can be performed by localizing homologous landmarks and calculating a point-based transformation between the images. The selection of landmarks is however important. In this work, we present a learningbased method to automatically find a set of robust landmarks in 3D MR image volumes of the head to initialize non-rigid transformations. To validate our method, these selected landmarks are localized in unknown image volumes and they are used to compute a smoothing thin-plate splines transformation that registers the atlas to the volumes. The transformed atlas image is then used as the preregistration initialization of an intensity-based non-rigid registration algorithm. We show that the registration accuracy of this algorithm is statistically significantly improved when using the presented registration initialization over a standard intensity-based affine registration.

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“…The procedure consists in implanting deep brain electrodes with an optimal placement and optimal electrical stimulation parameters that alleviate the symptoms while avoiding structures that trigger side effects. 2 To improve targeting, preoperative patient-specific models are built from multimodal medical images 3,4 such as preoperative magnetic resonance images (MRI) registered with an anatomical [5][6][7] or histological atlas. 8,9 A patient-specific model allows neurosurgeons to visualize on a three-dimensional (3-D) virtual representation of the cerebral structures of interest such as basal ganglia.…”

Section: Introductionmentioning

confidence: 99%

Image-guided preoperative prediction of pyramidal tract side effect in deep brain stimulation: proof of concept and application to the pyramidal tract side effect induced by pallidal stimulation

et al. 2016

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, "Imageguided preoperative prediction of pyramidal tract side effect in deep brain stimulation: proof of concept and application to the pyramidal tract side effect induced by pallidal stimulation," J. Abstract. Deep brain stimulation of the medial globus pallidus (GPm) is a surgical procedure for treating patients suffering from Parkinson's disease. Its therapeutic effect may be limited by the presence of pyramidal tract side effect (PTSE). PTSE is a contraction time-locked to the stimulation when the current spreading reaches the motor fibers of the pyramidal tract within the internal capsule. The objective of the study was to propose a preoperative predictive model of PTSE. A machine learning-based method called PyMAN (PTSE model based on artificial neural network) accounting for the current used in stimulation, the three-dimensional electrode coordinates and the angle of the trajectory, was designed to predict the occurrence of PTSE. Ten patients implanted in the GPm have been tested by a clinician to create a labeled dataset of the stimulation parameters that trigger PTSE. The kappa index value between the data predicted by PyMAN and the labeled data was 0.78. Further evaluation studies are desirable to confirm whether PyMAN could be a reliable tool for assisting the surgeon to prevent PTSE during the preoperative planning.

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CranialVault and its CRAVE tools: A clinical computer assistance system for deep brain stimulation (DBS) therapy

Cited by 97 publications

References 43 publications

Neuroinformatics in Clinical and Translational Medicine—Novel Approaches

Neuroinformatics in Clinical and Translational Medicine—Novel Approaches

Automatic selection of landmarks in T1-weighted head MRI with regression forests for image registration initialization

Image-guided preoperative prediction of pyramidal tract side effect in deep brain stimulation: proof of concept and application to the pyramidal tract side effect induced by pallidal stimulation

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