Abstract:
The main objective of this research work is to develop, test and evaluate an identification
support system that is able to provide accurate, fast and reliable diagnosis of brain tumor in
MR images. Keeping in consideration that human decision making skills are mainly dependent
on experience and prone to error due to fatigue, Artificial Intelligence (AI) can be utilized as an
effective aid in the field of medicinal sciences for tumor diagnosis through image recognition.
Therefore, this thesis strives to develop such an intelligent system that can be used for the
segmentation and classification of infiltrative brain tumors known as Low Grade and High
Grade in MR images.
In order to tackle the complex task of brain tumor segmentation in MR images, we present
an adaptive algorithm that formulates an energy based stochastic segmentation with a level
set methodology. This hybrid technique efficiently matches, segments and determines the
anatomic structures within an image by using global and local energies. After evaluating the
algorithm on low and high grade images, it was noted that there was an improvement in the
resultant similarity between segmented and truth (original) images.
Once effective segmentation was achieved we could then work on the next step of tumor
identification; classification. In the second part of the process we proposed two classification
frameworks, machine learning and deep learning. In machine learning, we first extracted
22 probabilistic features using gray level co-occurrence matrix methodology that served as
input features for the classifiers. Then we showed the improvement in classification (through
machine learning) accuracy by providing two methodologies in which the first one involved classification directly after feature extraction whereas in the second we reduced the extracted
features using principal component analysis and then applied those reduced features to several
classifiers.
The second framework that we proposed was the brain tumor classification of segmented
MR images through optimized CNN-Deep belief learning model. It scales to various image
sizes by distributing the hyper-parameters and weights among all locations in an image. The
presented model is translation invariant and is compatible with top-down and bottom-up probabilistic inference. This hierarchical classifier was optimized by regularization, that mitigates
the effect of overfitting for small datasets, stochastic gradient decent, which works efficiently
by utilizing only a small set of samples from a whole training set to infer the gradient and fine
tuning of constraints. A comparative analysis, based on accuracy, error/loss and computation
time, was carried out between the pre-processed non-segmented and segmented MR images
after classification was completed. The results showed that the accuracy of proposed optimized CNN-deep belief learning classifier with segmented MR images was higher while the
loss and execution time were reduced.
These methodologies transcend the confines of MR image processing due to their effective
modularity allowing them to be suitable for other medical imaging and computer vision tasks.