Your search keyword '"Zhu, Yitan"' showing total 10 results

1. Converting tabular data into images for deep learning with convolutional neural networks.

Author

Zhu, Yitan, Brettin, Thomas, Xia, Fangfang, Partin, Alexander, Shukla, Maulik, Yoo, Hyunseung, Evrard, Yvonne A., Doroshow, James H., and Stevens, Rick L.

Subjects

*CONVOLUTIONAL neural networks, *SPEECH, *GENE expression, *CANCER cells, *DRUG use testing

Abstract

Convolutional neural networks (CNNs) have been successfully used in many applications where important information about data is embedded in the order of features, such as speech and imaging. However, most tabular data do not assume a spatial relationship between features, and thus are unsuitable for modeling using CNNs. To meet this challenge, we develop a novel algorithm, image generator for tabular data (IGTD), to transform tabular data into images by assigning features to pixel positions so that similar features are close to each other in the image. The algorithm searches for an optimized assignment by minimizing the difference between the ranking of distances between features and the ranking of distances between their assigned pixels in the image. We apply IGTD to transform gene expression profiles of cancer cell lines (CCLs) and molecular descriptors of drugs into their respective image representations. Compared with existing transformation methods, IGTD generates compact image representations with better preservation of feature neighborhood structure. Evaluated on benchmark drug screening datasets, CNNs trained on IGTD image representations of CCLs and drugs exhibit a better performance of predicting anti-cancer drug response than both CNNs trained on alternative image representations and prediction models trained on the original tabular data. [ABSTRACT FROM AUTHOR]

Published

2021

2. Ensemble transfer learning for the prediction of anti-cancer drug response.

Author

Zhu, Yitan, Brettin, Thomas, Evrard, Yvonne A., Partin, Alexander, Xia, Fangfang, Shukla, Maulik, Yoo, Hyunseung, Doroshow, James H., and Stevens, Rick L.

Abstract

Transfer learning, which transfers patterns learned on a source dataset to a related target dataset for constructing prediction models, has been shown effective in many applications. In this paper, we investigate whether transfer learning can be used to improve the performance of anti-cancer drug response prediction models. Previous transfer learning studies for drug response prediction focused on building models to predict the response of tumor cells to a specific drug treatment. We target the more challenging task of building general prediction models that can make predictions for both new tumor cells and new drugs. Uniquely, we investigate the power of transfer learning for three drug response prediction applications including drug repurposing, precision oncology, and new drug development, through different data partition schemes in cross-validation. We extend the classic transfer learning framework through ensemble and demonstrate its general utility with three representative prediction algorithms including a gradient boosting model and two deep neural networks. The ensemble transfer learning framework is tested on benchmark in vitro drug screening datasets. The results demonstrate that our framework broadly improves the prediction performance in all three drug response prediction applications with all three prediction algorithms. [ABSTRACT FROM AUTHOR]

Published

2020

3. Bayesian nonparametric clustering for large data sets.

Author

Zuanetti, Daiane Aparecida, Müller, Peter, Zhu, Yitan, Yang, Shengjie, and Ji, Yuan

Abstract

We propose two nonparametric Bayesian methods to cluster big data and apply them to cluster genes by patterns of gene-gene interaction. Both approaches define model-based clustering with nonparametric Bayesian priors and include an implementation that remains feasible for big data. The first method is based on a predictive recursion which requires a single cycle (or few cycles) of simple deterministic calculations for each observation under study. The second scheme is an exact method that divides the data into smaller subsamples and involves local partitions that can be determined in parallel. In a second step, the method requires only the sufficient statistics of each of these local clusters to derive global clusters. Under simulated and benchmark data sets the proposed methods compare favorably with other clustering algorithms, including k-means, DP-means, DBSCAN, SUGS, streaming variational Bayes and an EM algorithm. We apply the proposed approaches to cluster a large data set of gene-gene interactions extracted from the online search tool "Zodiac." [ABSTRACT FROM AUTHOR]

Published

2019

4. Convex Analysis of Mixtures for Separating Non-negative Well-grounded Sources

Author

Electrical and Computer Engineering, Zhu, Yitan, Wang, Niya, Miller, David J., Wang, Yue, Electrical and Computer Engineering, Zhu, Yitan, Wang, Niya, Miller, David J., and Wang, Yue

Abstract

Blind Source Separation (BSS) is a powerful tool for analyzing composite data patterns in many areas, such as computational biology. We introduce a novel BSS method, Convex Analysis of Mixtures (CAM), for separating non-negative well-grounded sources, which learns the mixing matrix by identifying the lateral edges of the convex data scatter plot. We propose and prove a sufficient and necessary condition for identifying the mixing matrix through edge detection in the noise-free case, which enables CAM to identify the mixing matrix not only in the exact-determined and over-determined scenarios, but also in the under-determined scenario. We show the optimality of the edge detection strategy, even for cases where source well-groundedness is not strictly satisfied. The CAM algorithm integrates plug-in noise filtering using sector-based clustering, an efficient geometric convex analysis scheme, and stability-based model order selection. The superior performance of CAM against a panel of benchmark BSS techniques is demonstrated on numerically mixed gene expression data of ovarian cancer subtypes. We apply CAM to dissect dynamic contrast-enhanced magnetic resonance imaging data taken from breast tumors and time-course microarray gene expression data derived from in-vivo muscle regeneration in mice, both producing biologically plausible decomposition results.

Published

2016

5. A Nonparametric Bayesian Model for Nested Clustering.

Author

Lee, Juhee, Müller, Peter, Zhu, Yitan, and Ji, Yuan

Published

2016

6. Publisher Correction: Converting tabular data into images for deep learning with convolutional neural networks.

Author

Zhu, Yitan, Brettin, Thomas, Xia, Fangfang, Partin, Alexander, Shukla, Maulik, Yoo, Hyunseung, Evrard, Yvonne A., Doroshow, James H., and Stevens, Rick L.

Subjects

*DEEP learning, *CONVOLUTIONAL neural networks

Published

2021

7. Convex Analysis of Mixtures for Separating Non-negative Well-grounded Sources.

Author

Zhu, Yitan, Wang, Niya, Miller, David J., and Wang, Yue

Abstract

Blind Source Separation (BSS) is a powerful tool for analyzing composite data patterns in many areas, such as computational biology. We introduce a novel BSS method, Convex Analysis of Mixtures (CAM), for separating non-negative well-grounded sources, which learns the mixing matrix by identifying the lateral edges of the convex data scatter plot. We propose and prove a sufficient and necessary condition for identifying the mixing matrix through edge detection in the noise-free case, which enables CAM to identify the mixing matrix not only in the exact-determined and over-determined scenarios, but also in the under-determined scenario. We show the optimality of the edge detection strategy, even for cases where source well-groundedness is not strictly satisfied. The CAM algorithm integrates plug-in noise filtering using sector-based clustering, an efficient geometric convex analysis scheme, and stability-based model order selection. The superior performance of CAM against a panel of benchmark BSS techniques is demonstrated on numerically mixed gene expression data of ovarian cancer subtypes. We apply CAM to dissect dynamic contrast-enhanced magnetic resonance imaging data taken from breast tumors and time-course microarray gene expression data derived from in-vivo muscle regeneration in mice, both producing biologically plausible decomposition results. [ABSTRACT FROM AUTHOR]

Published

2016

8. TCGA-Assembler: open-source software for retrieving and processing TCGA data.

Author

Zhu, Yitan, Qiu, Peng, and Ji, Yuan

Subjects

*CANCER genetics, *OPEN source software

Abstract

A letter to the editor is presented in response to an article in previous issue, related to TCGA (The Cancer Genome Atlas)-Assembler, open-source software to retrieve and process TCGA data.

Published

2014

9. Deciphering Genomic Underpinnings of Quantitative MRI-based Radiomic Phenotypes of Invasive Breast Carcinoma.

Author

Zhu, Yitan, Li, Hui, Guo, Wentian, Drukker, Karen, Lan, Li, Giger, Maryellen L., and Ji, Yuan

Published

2015

10. Radiogenomics of breast cancer using dynamic contrast enhanced MRI and gene expression profiling.

Author

Yeh AC, Li H, Zhu Y, Zhang J, Khramtsova G, Drukker K, Edwards A, McGregor S, Yoshimatsu T, Zheng Y, Niu Q, Abe H, Mueller J, Conzen S, Ji Y, Giger ML, and Olopade OI

Subjects

Aged, Apoptosis, Breast Neoplasms genetics, Female, Humans, Phenotype, Breast Neoplasms diagnostic imaging, Gene Expression Profiling methods, Genomics methods, Magnetic Resonance Imaging methods

Abstract

Background: Imaging techniques can provide information about the tumor non-invasively and have been shown to provide information about the underlying genetic makeup. Correlating image-based phenotypes (radiomics) with genomic analyses is an emerging area of research commonly referred to as "radiogenomics" or "imaging-genomics". The purpose of this study was to assess the potential for using an automated, quantitative radiomics platform on magnetic resonance (MR) breast imaging for inferring underlying activity of clinically relevant gene pathways derived from RNA sequencing of invasive breast cancers prior to therapy., Methods: We performed quantitative radiomic analysis on 47 invasive breast cancers based on dynamic contrast enhanced 3 Tesla MR images acquired before surgery and obtained gene expression data by performing total RNA sequencing on corresponding fresh frozen tissue samples. We used gene set enrichment analysis to identify significant associations between the 186 gene pathways and the 38 image-based features that have previously been validated., Results: All radiomic size features were positively associated with multiple replication and proliferation pathways and were negatively associated with the apoptosis pathway. Gene pathways related to immune system regulation and extracellular signaling had the highest number of significant radiomic feature associations, with an average of 18.9 and 16 features per pathway, respectively. Tumors with upregulation of immune signaling pathways such as T-cell receptor signaling and chemokine signaling as well as extracellular signaling pathways such as cell adhesion molecule and cytokine-cytokine interactions were smaller, more spherical, and had a more heterogeneous texture upon contrast enhancement. Tumors with higher expression levels of JAK/STAT and VEGF pathways had more intratumor heterogeneity in image enhancement texture. Other pathways with robust associations to image-based features include metabolic and catabolic pathways., Conclusions: We provide further evidence that MR imaging of breast tumors can infer underlying gene expression by using RNA sequencing. Size and shape features were appropriately correlated with proliferative and apoptotic pathways. Given the high number of radiomic feature associations with immune pathways, our results raise the possibility of using MR imaging to distinguish tumors that are more immunologically active, although further studies are necessary to confirm this observation.

Published

2019