Abstract EN:

The dissertation include the detection, classification and visualization of brain trauma lesions from Computed Tomography. Various geometrical methods have been studied such as hybrid, feature extraction, level sets, watershed and region growing which are analyzed based upon their methodological aspects and their constraints evaluations. The pixel intensities, gradient magnitude, affinity map and catchment basins of these methods are validated based upon various ranges of constraints evaluations for which we have found out and contributed. We have also contributed for the deduction of the most appropriate method of detection for specific feature in the trauma lesions. We contribute a new methodology for the featurebased contour extraction of the lesion available that uses bilateral filtering, anisotropic diffusion properties, watershed and mathematical morphology operators based mainly on the gradient function. The gradient of the gray level values of watershed pixels are transformed after flooding and substituted by the gradient magnitude of the diffusion anisotropy. The evaluations of the classification of these lesions are undertaken by pattern recognition. We propose to classify these traumatic brain injuries from CT scans by pattern recognition. The k-means and the Markov random field algorithms have been implemented and experimented for each feature of the various lesions. Entropies of these CT scans have been calculated to get an optimized statistical evaluation for each feature lesion such as brain atropy, subdural hygroma, subdural haematoma, extracranial haematoma and nonhaemorraghic contusion. These methods are compared to assess their performance and statistical accuracy with respect to the featurebased lesion sets. These featurebased lesion sets are analyzed and evaluated statistically from the intensity to the pixel values and estimated calculated volumes. The numerical interpretations of each specific feature enables a proper assessment of the evolutionary stages of the featurebased lesions. Our last contributions are based mainly on the clinical aspects from these evaluated interpretations of the featurebased lesion sets. Herewith are the future directions of the research work. A multilayer neural work with sparse distributions and switching linear dynamical system for feature detection and classification simultaneously. The second direction is an implementation of a brain atlas of trauma case to typical case through a pixelbased structuring for heterogeneous regrouping of the anatomy and realtime visualization.