Yuanqi Zeng scite author profile

Background: The emergence of generative adversarial networks (GANs) has provided a new technology and framework for the application of medical images. Specifically, a GAN requires little to no labeled data to obtain highquality data that can be generated through competition between the generator and discriminator networks. Therefore, GANs are rapidly proving to be a state-of-the-art foundation, achieving enhanced performances in various medical applications. Methods: In this article, we introduce the principles of GANs and their various variants, deep convolutional GAN, conditional GAN, Wasserstein GAN, Info-GAN, boundary equilibrium GAN, and cycle-GAN. Results: All various GANs have found success in medical imaging tasks, including medical image enhancement, segmentation, classification, reconstruction, and synthesis. Furthermore, we summarize the data processing methods and evaluation indicators. Finally, we note the limitations of existing methods and the existing challenges that need to be addressed in this field. Conclusion: Although GANs are in initial stage of development in medical image processing, it will have a great prospect in the future.

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Applications of Machine Learning in Drug Target Discovery

Gao

Chen

Zeng

et al. 2020

CDM

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: Drug target discovery is a critical step in drug development. It is the basis of modern drug development to deter-mine the target molecules related to specific diseases in advance. Predicting the drug target by computational methods saves a lot of financial and material resources than in vitro experiments, thereby a number of computational methods are designed for drug target discovery. Recently, machine learning (ML) methods have developed rapidly in biomedicine. In this paper, we present an overview of drug target discovery methods based on machine learning. Due to some machine learning meth-ods integratenetwork analysis to predict drug targets, network-based methods are also introduced in this article. Finally, the challenges and future outlook of drug target discovery are discussed.

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A Review About Transcription Factor Binding Sites Prediction Based on Deep Learning

et al. 2020

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A novel convolution attention model for predicting transcription factor binding sites by combination of sequence and shape

Zhang

Wang

Zeng

et al. 2021

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The discovery of putative transcription factor binding sites (TFBSs) is important for understanding the underlying binding mechanism and cellular functions. Recently, many computational methods have been proposed to jointly account for DNA sequence and shape properties in TFBSs prediction. However, these methods fail to fully utilize the latent features derived from both sequence and shape profiles and have limitation in interpretability and knowledge discovery. To this end, we present a novel Deep Convolution Attention network combining Sequence and Shape, dubbed as D-SSCA, for precisely predicting putative TFBSs. Experiments conducted on 165 ENCODE ChIP-seq datasets reveal that D-SSCA significantly outperforms several state-of-the-art methods in predicting TFBSs, and justify the utility of channel attention module for feature refinements. Besides, the thorough analysis about the contribution of five shapes to TFBSs prediction demonstrates that shape features can improve the predictive power for transcription factors-DNA binding. Furthermore, D-SSCA can realize the cross-cell line prediction of TFBSs, indicating the occupancy of common interplay patterns concerning both sequence and shape across various cell lines. The source code of D-SSCA can be found at https://github.com/MoonLord0525/.

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High-resolution transcription factor binding sites prediction improved performance and interpretability by deep learning method

Zhang

Wang

Zeng

et al. 2021

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Transcription factors (TFs) are essential proteins in regulating the spatiotemporal expression of genes. It is crucial to infer the potential transcription factor binding sites (TFBSs) with high resolution to promote biology and realize precision medicine. Recently, deep learning-based models have shown exemplary performance in the prediction of TFBSs at the base-pair level. However, the previous models fail to integrate nucleotide position information and semantic information without noisy responses. Thus, there is still room for improvement. Moreover, both the inner mechanism and prediction results of these models are challenging to interpret. To this end, the Deep Attentive Encoder-Decoder Neural Network (D-AEDNet) is developed to identify the location of TFs–DNA binding sites in DNA sequences. In particular, our model adopts Skip Architecture to leverage the nucleotide position information in the encoder and removes noisy responses in the information fusion process by Attention Gate. Simultaneously, the Transcription Factor Motif Discovery based on Sliding Window (TF-MoDSW), an approach to discover TFs–DNA binding motifs by utilizing the output of neural networks, is proposed to understand the biological meaning of the predicted result. On ChIP-exo datasets, experimental results show that D-AEDNet has better performance than competing methods. Besides, we authenticate that Attention Gate can improve the interpretability of our model by ways of visualization analysis. Furthermore, we confirm that ability of D-AEDNet to learn TFs–DNA binding motifs outperform the state-of-the-art methods and availability of TF-MoDSW to discover biological sequence motifs in TFs–DNA interaction by conducting experiment on ChIP-seq datasets.

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Yuanqi Zeng

Generative Adversarial Networks in Medical Image Processing

Applications of Machine Learning in Drug Target Discovery

A Review About Transcription Factor Binding Sites Prediction Based on Deep Learning

A novel convolution attention model for predicting transcription factor binding sites by combination of sequence and shape

High-resolution transcription factor binding sites prediction improved performance and interpretability by deep learning method

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