Johnsson, Lennart2022-06-17December 22021-12December 2Portions of this document appear in: Sakoglu, Unal, Lohit Bhupati, Nazanin Beheshti, Nikolaos Tsekos, and Lennart Johnsson. "An adaptive space-filling curve trajectory for ordering 3D datasets to 1D: Application to brain magnetic resonance imaging data for classification." In International Conference on Computational Science, pp. 635-646. Springer, Cham, 2020.https://hdl.handle.net/10657/9276Alzheimer’s disease is progressively degenerative with a character of memory loss, mood and behavior changes, and deepening confusion about time and place. It is estimated that worldwide about 50 million people are affected by AD. The lifetime per patient care cost of AD is estimated to be about $250k and the total cost of care of AD patients could exceed $1 trillion by 2050. In this research, we use novel data reduction techniques in determining functional brain connectivity from Resting-State fMRI data and show that small Machine Leaning models can with good accuracy classify subjects with respect to Alzheimer’s disease (AD) or Mild Cognitive Impairment (MCI) or being Cognitive Normal (CN). In fMRI, brain activity is captured from Blood Oxygen Level-Dependent (BOLD) magnetization detected by the MRI scanner. The functional connectivity is inferred from correlations of the observed BOLD signals from typically cubic voxels with sides in the 3 – 4 mm range. The BOLD signals are typically sampled every 2 – 3 seconds for a duration of five to six minutes generating a data set of 5 – 10 million voxel BOLD signal values per subject. To reduce the computational effort classification is typically carried out based on signal aggregates for anatomical regions defined in brain atlases. In this research, we use the 90 region Automated Anatomical Labeling atlas, AAL-90, in establishing Regions of Interest, ROIs that are subsets of voxels in the AAL-90 atlas. The functional connectivity is measured by the correlation of BOLD signal aggregates for the ROIs. In the data reduction step, we represent the 4D data set for a region with a vector that on average reduces the data set for a region from about 100,000 voxel signal values to 100 to 200 values in our spatial representation and in the order of 15,000 – 30,000 in our spatial-temporal representation. We show that a small Convolutional Neural Network (CNN) with a model size of about 168 kiB and a Transformer model of only 37 kiB yields classification accuracies of 80 – 90% for AD, MCI, and CN subject classification. We further show that our region data aggregation technique is more robust to BOLD signal artifacts than the commonly used aggregation technique. The training time for the CNN and Transformer on a data set of 551 subjects required 184 and 23.73 seconds respectively. The experiments are conducted on Opuntia Cluster using Pytorch.1.5.0, Python 3.7.7, and CUDA 10.1 on a 2.8GHz Intel Xeon E5-2670v2 processor with 2 CPU sockets and 20 cores, and NVIDIA K40 GPU.application/pdfengThe author of this work is the copyright owner. UH Libraries and the Texas Digital Library have their permission to store and provide access to this work. UH Libraries has secured permission to reproduce any and all previously published materials contained in the work. Further transmission, reproduction, or presentation of this work is prohibited except with permission of the author(s).fMRI, Alzheimers, Classification, CNN, Transformer, Deep Learning2022-06-17Thesisborn digital