Source-Free Collaborative Domain Adaptation via Multi-Perspective
Feature Enrichment for Functional MRI Analysis
- URL: http://arxiv.org/abs/2308.12495v1
- Date: Thu, 24 Aug 2023 01:30:18 GMT
- Title: Source-Free Collaborative Domain Adaptation via Multi-Perspective
Feature Enrichment for Functional MRI Analysis
- Authors: Yuqi Fang, Jinjian Wu, Qianqian Wang, Shijun Qiu, Andrea Bozoki,
Huaicheng Yan, Mingxia Liu
- Abstract summary: Resting-state MRI functional (rs-fMRI) is increasingly employed in multi-site research to aid neurological disorder analysis.
Many methods have been proposed to reduce fMRI heterogeneity between source and target domains.
But acquiring source data is challenging due to concerns and/or data storage burdens in multi-site studies.
We design a source-free collaborative domain adaptation framework for fMRI analysis, where only a pretrained source model and unlabeled target data are accessible.
- Score: 55.03872260158717
- License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
- Abstract: Resting-state functional MRI (rs-fMRI) is increasingly employed in multi-site
research to aid neurological disorder analysis. Existing studies usually suffer
from significant cross-site/domain data heterogeneity caused by site effects
such as differences in scanners/protocols. Many methods have been proposed to
reduce fMRI heterogeneity between source and target domains, heavily relying on
the availability of source data. But acquiring source data is challenging due
to privacy concerns and/or data storage burdens in multi-site studies. To this
end, we design a source-free collaborative domain adaptation (SCDA) framework
for fMRI analysis, where only a pretrained source model and unlabeled target
data are accessible. Specifically, a multi-perspective feature enrichment
method (MFE) is developed for target fMRI analysis, consisting of multiple
collaborative branches to dynamically capture fMRI features of unlabeled target
data from multiple views. Each branch has a data-feeding module, a
spatiotemporal feature encoder, and a class predictor. A mutual-consistency
constraint is designed to encourage pair-wise consistency of latent features of
the same input generated from these branches for robust representation
learning. To facilitate efficient cross-domain knowledge transfer without
source data, we initialize MFE using parameters of a pretrained source model.
We also introduce an unsupervised pretraining strategy using 3,806 unlabeled
fMRIs from three large-scale auxiliary databases, aiming to obtain a general
feature encoder. Experimental results on three public datasets and one private
dataset demonstrate the efficacy of our method in cross-scanner and cross-study
prediction tasks. The model pretrained on large-scale rs-fMRI data has been
released to the public.
Related papers
- Robust Fiber ODF Estimation Using Deep Constrained Spherical
Deconvolution for Diffusion MRI [7.9283612449524155]
A common practice to model the measured DW-MRI signal is via fiber orientation distribution function (fODF)
measurement variabilities (e.g., inter- and intra-site variability, hardware performance, and sequence design) are inevitable during the acquisition of DW-MRI.
Most existing model-based methods (e.g., constrained spherical deconvolution (CSD)) and learning based methods (e.g., deep learning (DL)) do not explicitly consider such variabilities in fODF modeling.
We propose a novel data-driven deep constrained spherical deconvolution method to
arXiv Detail & Related papers (2023-06-05T14:06:40Z) - Shared Space Transfer Learning for analyzing multi-site fMRI data [83.41324371491774]
Multi-voxel pattern analysis (MVPA) learns predictive models from task-based functional magnetic resonance imaging (fMRI) data.
MVPA works best with a well-designed feature set and an adequate sample size.
Most fMRI datasets are noisy, high-dimensional, expensive to collect, and with small sample sizes.
This paper proposes the Shared Space Transfer Learning (SSTL) as a novel transfer learning approach.
arXiv Detail & Related papers (2020-10-24T08:50:26Z) - Fader Networks for domain adaptation on fMRI: ABIDE-II study [68.5481471934606]
We use 3D convolutional autoencoders to build the domain irrelevant latent space image representation and demonstrate this method to outperform existing approaches on ABIDE data.
arXiv Detail & Related papers (2020-10-14T16:50:50Z) - Deep Representational Similarity Learning for analyzing neural
signatures in task-based fMRI dataset [81.02949933048332]
This paper develops Deep Representational Similarity Learning (DRSL), a deep extension of Representational Similarity Analysis (RSA)
DRSL is appropriate for analyzing similarities between various cognitive tasks in fMRI datasets with a large number of subjects.
arXiv Detail & Related papers (2020-09-28T18:30:14Z) - Modeling Shared Responses in Neuroimaging Studies through MultiView ICA [94.31804763196116]
Group studies involving large cohorts of subjects are important to draw general conclusions about brain functional organization.
We propose a novel MultiView Independent Component Analysis model for group studies, where data from each subject are modeled as a linear combination of shared independent sources plus noise.
We demonstrate the usefulness of our approach first on fMRI data, where our model demonstrates improved sensitivity in identifying common sources among subjects.
arXiv Detail & Related papers (2020-06-11T17:29:53Z) - MS-Net: Multi-Site Network for Improving Prostate Segmentation with
Heterogeneous MRI Data [75.73881040581767]
We propose a novel multi-site network (MS-Net) for improving prostate segmentation by learning robust representations.
Our MS-Net improves the performance across all datasets consistently, and outperforms state-of-the-art methods for multi-site learning.
arXiv Detail & Related papers (2020-02-09T14:11:50Z) - Multi-site fMRI Analysis Using Privacy-preserving Federated Learning and
Domain Adaptation: ABIDE Results [13.615292855384729]
To train a high-quality deep learning model, the aggregation of a significant amount of patient information is required.
Due to the need to protect the privacy of patient data, it is hard to assemble a central database from multiple institutions.
Federated learning allows for population-level models to be trained without centralizing entities' data.
arXiv Detail & Related papers (2020-01-16T04:49:33Z)
This list is automatically generated from the titles and abstracts of the papers in this site.
This site does not guarantee the quality of this site (including all information) and is not responsible for any consequences.