AI Article Synopsis
- Scientists are exploring new ways to use deep learning to tell if someone has Alzheimer's disease by looking at brain scans from MRI images.
- They tested different models, and one called SFCN performed the best, even with fewer parts than other models like EfficientNet.
- The study shows that SFCN is really good at figuring out Alzheimer's, suggesting that simpler models can be just as effective as more complicated ones.
Article Abstract
Background: There is a broad interest in deploying deep learning-based classification algorithms to identify individuals with Alzheimer's disease (AD) from healthy controls (HC) based on neuroimaging data, such as T1-weighted Magnetic Resonance Imaging (MRI). The goal of the current study is to investigate whether modern, flexible architectures such as EfficientNet provide any performance boost over more standard architectures.
Methods: MRI data was sourced from the Alzheimer's Disease Neuroimaging Initiative (ADNI) and processed with a minimal preprocessing pipeline. Among the various architectures tested, the minimal 3D convolutional neural network SFCN stood out, composed solely of 3x3x3 convolution, batch normalization, ReLU, and max-pooling. We also examined the influence of scale on performance, testing SFCN versions with trainable parameters ranging from 720 up to 2.9 million.
Results: SFCN achieves a test ROC AUC of 96.0% while EfficientNet got an ROC AUC of 94.9 %. SFCN retained high performance down to 720 trainable parameters, achieving an ROC AUC of 91.4%.
Comparison With Existing Methods: The SFCN is compared to DenseNet and EfficientNet as well as the results of other publications in the field.
Conclusions: The results indicate that using the minimal 3D convolutional neural network SFCN with a minimal preprocessing pipeline can achieve competitive performance in AD classification, challenging the necessity of employing more complex architectures with a larger number of parameters. This finding supports the efficiency of simpler deep learning models for neuroimaging-based AD diagnosis, potentially aiding in better understanding and diagnosing Alzheimer's disease.
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| http://dx.doi.org/10.1016/j.jneumeth.2024.110253 | DOI Listing |
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