Abstract
Deep learning algorithms have been moderately successful in diagnoses of diseases by analyzing medical images especially through neuroimaging that is rich in annotated data. Transfer learning methods have demonstrated strong performance in tackling annotated data. It utilizes and transfers knowledge learned from a source domain to target domain even when the dataset is small. There are multiple approaches to transfer learning that result in a range of performance estimates in diagnosis, detection, and classification of clinical problems. Therefore, in this paper, we reviewed transfer learning approaches, their design attributes, and their applications to neuroimaging problems. We reviewed two main literature databases and included the most relevant studies using predefined inclusion criteria. Among 50 reviewed studies, more than half of them are on transfer learning for Alzheimer's disease. Brain mapping and brain tumor detection were second and third most discussed research problems, respectively. The most common source dataset for transfer learning was ImageNet, which is not a neuroimaging dataset. This suggests that the majority of studies preferred pre-trained models instead of training their own model on a neuroimaging dataset. Although, about one third of studies designed their own architecture, most studies used existing Convolutional Neural Network architectures. Magnetic Resonance Imaging was the most common imaging modality. In almost all studies, transfer learning contributed to better performance in diagnosis, classification, segmentation of different neuroimaging diseases and problems, than methods without transfer learning. Among different transfer learning approaches, fine-tuning all convolutional and fully-connected layers approach and freezing convolutional layers and fine-tuning fully-connected layers approach demonstrated superior performance in terms of accuracy. These recent transfer learning approaches not only show great performance but also require less computational resources and time.
Highlights
Neuroimaging data provide a rich information source for clinicians to make decisions about diagnosis and treatment of different brain disorders
Most of the studies focused on AD related problems such as Mild Cognitive Impairment (MCI) detection likely because of availability of large datasets for AD such as the Alzheimer’s Disease Neuroimaging Initiative (ADNI) dataset (Saykin et al, 2010)
Among the six transfer learning approaches, Kernel learning was only used in conjunction with traditional machine learning algorithms such as support vector machine (SVM)
Summary
Neuroimaging data provide a rich information source for clinicians to make decisions about diagnosis and treatment of different brain disorders. Utilizing advanced computational methods to analyze neuroimaging data, alongside physician’s interpretation, can enable more accurate clinical decisions These neuroimaging data include Magnetic Resonance Imaging (MRI), functional Magnetic Resonance Imaging (fMRI), Positron Emission Tomography (PET), and Electroencephalography (EEG). MRI, a non-invasive neuroimaging technology, utilizes a magnetic field to generate informative images of the brain (or any other tissue of subject’s body). It produces detailed, three dimensional (3D) anatomical scans of the brain which can be utilized in detection and diagnosis of diseases (Briani et al, 2013). Functional Magnetic Resonance Imaging (fMRI) measures the dynamics of the blood flow to detect brain activities. PET can measure the most metabolically active target for stereotactic biopsy (Wong et al, 2002; Holzgreve et al, 2021)
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