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DeepFDR: A Deep Learning-based False Discovery Rate Control Method for Neuroimaging Data


Conceitos essenciais
DeepFDR leverages deep learning for spatial FDR control in neuroimaging data, demonstrating superior performance.
Resumo
  • Voxel-based multiple testing is crucial in neuroimaging analysis.
  • Traditional FDR methods ignore spatial dependencies, leading to power loss.
  • DeepFDR utilizes unsupervised deep learning for image segmentation to address voxel-based testing challenges.
  • Numerical studies show DeepFDR's superiority in FDR control and computational efficiency.
  • Proposed method combines deep learning with LIS-based testing procedure effectively.
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Estatísticas
数値研究によると、DeepFDRは既存の手法よりも優れた性能を示しています。
Citações
"DeepFDR not only excels in FDR control and effectively diminishes the false nondiscovery rate, but also boasts exceptional computational efficiency highly suited for tackling large-scale neuroimaging data."

Principais Insights Extraídos De

by Taehyo Kim,H... às arxiv.org 03-12-2024

https://arxiv.org/pdf/2310.13349.pdf
DeepFDR

Perguntas Mais Profundas

How can DeepFDR's approach be applied to other fields beyond neuroimaging

DeepFDR's approach can be applied to other fields beyond neuroimaging by leveraging its deep learning-based false discovery rate control method. In various fields such as genomics, proteomics, and drug discovery, where high-dimensional data analysis is crucial, DeepFDR can be utilized to effectively handle multiple testing problems. For example, in genomics research, analyzing gene expression data from different experimental conditions or disease states often involves conducting numerous hypothesis tests. DeepFDR's ability to capture spatial dependencies among voxel-based tests can be adapted to model the complex relationships between genes and their expressions across different conditions.

Do traditional FDR methods have any advantages over DeepFDR in certain scenarios

Traditional FDR methods may have advantages over DeepFDR in certain scenarios. For instance, traditional methods like the Benjamini-Hochberg (BH) procedure are well-established and widely used in statistical analyses. They may offer simplicity and ease of implementation compared to more complex deep learning models like DeepFDR. Additionally, traditional methods may perform better in scenarios where the assumptions of spatial dependence among voxel-based tests do not hold true or when computational resources are limited. In cases where interpretability and transparency are essential factors for decision-making, traditional FDR methods might be preferred due to their straightforward nature.

How can the use of deep learning impact the future of medical image analysis

The use of deep learning has a significant impact on the future of medical image analysis by revolutionizing how images are processed and interpreted in healthcare settings. With deep learning algorithms like convolutional neural networks (CNNs) being able to automatically learn features from images without explicit programming, medical image analysis becomes more efficient and accurate. These advancements enable tasks such as image segmentation for identifying specific structures or abnormalities within medical images with higher precision than traditional methods. In the future, we can expect further improvements in diagnostic accuracy through automated detection of diseases from medical imaging data using deep learning techniques. This could lead to earlier detection of conditions such as cancer or neurological disorders based on subtle patterns that might go unnoticed by human observers alone.
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