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163 results on '"Wang, Shunfang"'

1. MSVM-UNet: Multi-Scale Vision Mamba UNet for Medical Image Segmentation

Author

Chen, Chaowei, Yu, Li, Min, Shiquan, and Wang, Shunfang

Subjects
Computer Science - Computer Vision and Pattern Recognition
Abstract

State Space Models (SSMs), especially Mamba, have shown great promise in medical image segmentation due to their ability to model long-range dependencies with linear computational complexity. However, accurate medical image segmentation requires the effective learning of both multi-scale detailed feature representations and global contextual dependencies. Although existing works have attempted to address this issue by integrating CNNs and SSMs to leverage their respective strengths, they have not designed specialized modules to effectively capture multi-scale feature representations, nor have they adequately addressed the directional sensitivity problem when applying Mamba to 2D image data. To overcome these limitations, we propose a Multi-Scale Vision Mamba UNet model for medical image segmentation, termed MSVM-UNet. Specifically, by introducing multi-scale convolutions in the VSS blocks, we can more effectively capture and aggregate multi-scale feature representations from the hierarchical features of the VMamba encoder and better handle 2D visual data. Additionally, the large kernel patch expanding (LKPE) layers achieve more efficient upsampling of feature maps by simultaneously integrating spatial and channel information. Extensive experiments on the Synapse and ACDC datasets demonstrate that our approach is more effective than some state-of-the-art methods in capturing and aggregating multi-scale feature representations and modeling long-range dependencies between pixels., Comment: 8 pages, 5 figures

Published
2024

2. scASDC: Attention Enhanced Structural Deep Clustering for Single-cell RNA-seq Data

Author

Min, Wenwen, Wang, Zhen, Zhu, Fangfang, Xu, Taosheng, and Wang, Shunfang

Subjects
Quantitative Biology - Genomics, Computer Science - Artificial Intelligence, Computer Science - Machine Learning
Abstract

Single-cell RNA sequencing (scRNA-seq) data analysis is pivotal for understanding cellular heterogeneity. However, the high sparsity and complex noise patterns inherent in scRNA-seq data present significant challenges for traditional clustering methods. To address these issues, we propose a deep clustering method, Attention-Enhanced Structural Deep Embedding Graph Clustering (scASDC), which integrates multiple advanced modules to improve clustering accuracy and robustness.Our approach employs a multi-layer graph convolutional network (GCN) to capture high-order structural relationships between cells, termed as the graph autoencoder module. To mitigate the oversmoothing issue in GCNs, we introduce a ZINB-based autoencoder module that extracts content information from the data and learns latent representations of gene expression. These modules are further integrated through an attention fusion mechanism, ensuring effective combination of gene expression and structural information at each layer of the GCN. Additionally, a self-supervised learning module is incorporated to enhance the robustness of the learned embeddings. Extensive experiments demonstrate that scASDC outperforms existing state-of-the-art methods, providing a robust and effective solution for single-cell clustering tasks. Our method paves the way for more accurate and meaningful analysis of single-cell RNA sequencing data, contributing to better understanding of cellular heterogeneity and biological processes. All code and public datasets used in this paper are available at \url{https://github.com/wenwenmin/scASDC} and \url{https://zenodo.org/records/12814320}.

Published
2024

3. Masked adversarial neural network for cell type deconvolution in spatial transcriptomics

Author

Huang, Lin, Liu, Xiaofei, Wang, Shunfang, and Min, Wenwen

Subjects
Computer Science - Machine Learning
Abstract

Accurately determining cell type composition in disease-relevant tissues is crucial for identifying disease targets. Most existing spatial transcriptomics (ST) technologies cannot achieve single-cell resolution, making it challenging to accurately determine cell types. To address this issue, various deconvolution methods have been developed. Most of these methods use single-cell RNA sequencing (scRNA-seq) data from the same tissue as a reference to infer cell types in ST data spots. However, they often overlook the differences between scRNA-seq and ST data. To overcome this limitation, we propose a Masked Adversarial Neural Network (MACD). MACD employs adversarial learning to align real ST data with simulated ST data generated from scRNA-seq data. By mapping them into a unified latent space, it can minimize the differences between the two types of data. Additionally, MACD uses masking techniques to effectively learn the features of real ST data and mitigate noise. We evaluated MACD on 32 simulated datasets and 2 real datasets, demonstrating its accuracy in performing cell type deconvolution. All code and public datasets used in this paper are available at https://github.com/wenwenmin/MACD and https://zenodo.org/records/12804822.

Published
2024

4. stMCDI: Masked Conditional Diffusion Model with Graph Neural Network for Spatial Transcriptomics Data Imputation

Author

Li, Xiaoyu, Min, Wenwen, Wang, Shunfang, Wang, Changmiao, and Xu, Taosheng

Subjects
Quantitative Biology - Genomics, Computer Science - Artificial Intelligence, Computer Science - Machine Learning
Abstract

Spatially resolved transcriptomics represents a significant advancement in single-cell analysis by offering both gene expression data and their corresponding physical locations. However, this high degree of spatial resolution entails a drawback, as the resulting spatial transcriptomic data at the cellular level is notably plagued by a high incidence of missing values. Furthermore, most existing imputation methods either overlook the spatial information between spots or compromise the overall gene expression data distribution. To address these challenges, our primary focus is on effectively utilizing the spatial location information within spatial transcriptomic data to impute missing values, while preserving the overall data distribution. We introduce \textbf{stMCDI}, a novel conditional diffusion model for spatial transcriptomics data imputation, which employs a denoising network trained using randomly masked data portions as guidance, with the unmasked data serving as conditions. Additionally, it utilizes a GNN encoder to integrate the spatial position information, thereby enhancing model performance. The results obtained from spatial transcriptomics datasets elucidate the performance of our methods relative to existing approaches., Comment: Submitted to IJCAI2024

Published
2024

5. Multi-scale and Boundary Fusion Network for Skin Lesion Regions Segmentation

Author

WANG Guokai, ZHANG Xiang, WANG Shunfang

Subjects
skin lesion region segmentation, skip connections, boundary feature, feature fusion, attention mechanism, Electronic computers. Computer science, QA75.5-76.95
Abstract

Accurate segmentation of skin lesion regions is a key step in clinical diagnosis and analysis. Aiming at the poor segmentation effect of the existing networks in skin lesion regions due to the presence of variable size, irregular shape, fuzzy boundaries and obscured lesion regions, a multi-scale and boundary fusion network (MSBF-Net) for skin lesion region segmentation is proposed by improving the original structure based on the U-Net. Specifically, firstly, a split pooling (SplitPool) module is proposed, which effectively solves the problem of spatial information loss while reducing the image resolution. Secondly, a full-scale feature fusion (FSFF) module is proposed, which effectively solves the problem that the previous methods only fuse the deep features to the shallow features, while ignoring the contribution of the detail information in the more shallow features to the network segmentation decision. Meanwhile, the original jump connections of U-Net are redesigned to provide richer contextual information for the decoder. Finally, sub-paths for enhancing the network’s ability to learn boundary features are proposed, and the boundary fusion (BF) module is introduced to fuse the prediction results of the main paths and sub-paths, which effectively solves the problems of irregular shape and boundary ambiguity of the lesion region. Dice and JI reach 90.12% and 83.61% on the ISIC2018 dataset, which are 1.13 percentage points and 1.62 percentage points higher than the baseline network, respectively; Dice and JI reach 94.72% and 90.18% on the PH2 dataset, which are 1.49 percentage points and 2.17 percentage points higher than the baseline network, respectively. Experimental results show that MSBF-Net significantly improves the accuracy of skin lesion region segmentation and exceeds the existing state-of-the-art methods in several indices, further validating the effectiveness of the method.

Published
2024
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17. Parameter Transfer Learning Measured by Image Similarity to Detect CT of COVID-19

Author

Zhao, Chang, Wang, Shunfang, Goos, Gerhard, Founding Editor, Hartmanis, Juris, Founding Editor, Bertino, Elisa, Editorial Board Member, Gao, Wen, Editorial Board Member, Steffen, Bernhard, Editorial Board Member, Woeginger, Gerhard, Editorial Board Member, Yung, Moti, Editorial Board Member, Wei, Yanjie, editor, Li, Min, editor, Skums, Pavel, editor, and Cai, Zhipeng, editor

Published
2021
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31. TsImpute: an accurate two-step imputation method for single-cell RNA-seq data.

Author

Zheng, Weihua, Min, Wenwen, and Wang, Shunfang

Subjects
NEGATIVE binomial distribution, GENE expression, RNA sequencing, CELL aggregation
Abstract

Motivation Single-cell RNA sequencing (scRNA-seq) technology has enabled discovering gene expression patterns at single cell resolution. However, due to technical limitations, there are usually excessive zeros, called "dropouts," in scRNA-seq data, which may mislead the downstream analysis. Therefore, it is crucial to impute these dropouts to recover the biological information. Results We propose a two-step imputation method called tsImpute to impute scRNA-seq data. At the first step, tsImpute adopts zero-inflated negative binomial distribution to discriminate dropouts from true zeros and performs initial imputation by calculating the expected expression level. At the second step, it conducts clustering with this modified expression matrix, based on which the final distance weighted imputation is performed. Numerical results based on both simulated and real data show that tsImpute achieves favorable performance in terms of gene expression recovery, cell clustering, and differential expression analysis. Availability and implementation The R package of tsImpute is available at https://github.com/ZhengWeihuaYNU/tsImpute. [ABSTRACT FROM AUTHOR]

Published
2023
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34. DeepFusion-RBP: Using Deep Learning to Fuse Multiple Features to Identify RNA-binding Protein Sequences

Author

Tang Xianjun, Fu Haoyi, Ruan Xiaoli, Wang Shunfang, and Wang Xu

Subjects
Computational Mathematics, Fuse (automotive), business.industry, Chemistry, Deep learning, Genetics, RNA-binding protein, Artificial intelligence, Computational biology, business, Molecular Biology, Biochemistry
Abstract

Background: RNA-binding protein plays an important role in regulating splicing, RNA transport, and other post-transcriptional processes, identifying special RNA binding domains, and interacting with RNA. Objective: This paper proposes a deep learning framework, DeepFusion-RBP, composed of three submodels. A sliding window is used to obtain sub-sequences, local features are obtained, and then the model is customized for each feature. Methods: The main advantage of this research is using the sliding window method to cut the original sequence. While expanding the data set, this method avoids filling in too much meaningless data. Then, the model is customized for each feature to accurately perform RNA binding protein classification, with specific methods such as LSTM, Conv1D, Amino acid embedding, etc. Results: To test whether the customized model can improve the final prediction effect, we used different combinations of sub-models and test sets of different lengths. The prediction ACC, F1-score and MCC of DeepFusion-RBP are 92.62%, 91.29%, and 84.96%, respectively, with cross-validation. At the same time, DeepFusion-RBP also showed excellent performance on three independent verification sets. Conclusion: The results of 10-fold cross-validation and the independent verification set tests both suggested that the proposed models for different features and intercepting sub-sequences produce a certain improvement in the prediction effect of the model. The data supporting the findings of the article are available at https://github.com/mmwangxu/DeepFusion-RBP-tool.

Published
2021

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