Your search keyword '"T-SNE"' showing total 6 results

1. GECO: gene expression clustering optimization app for non-linear data visualization of patterns

Author

Habowski, AN, Habowski, TJ, and Waterman, ML

Subjects

Genetics, Generic health relevance, Cluster Analysis, Data Visualization, Gene Expression, Sequence Analysis, RNA, Software, RNA-seq, Gene expression, t-SNE, UMAP, PCA, Clustering, App, Data visualization, Mathematical Sciences, Biological Sciences, Information and Computing Sciences, Bioinformatics

Abstract

BackgroundDue to continued advances in sequencing technology, the limitation in understanding biological systems through an "-omics" lens is no longer the generation of data, but the ability to analyze it. Importantly, much of this rich -omics data is publicly available waiting to be further investigated. Although many code-based pipelines exist, there is a lack of user-friendly and accessible applications that enable rapid analysis or visualization of data.ResultsGECO (Gene Expression Clustering Optimization; http://www.theGECOapp.com ) is a minimalistic GUI app that utilizes non-linear reduction techniques to rapidly visualize expression trends in many types of biological data matrices (such as bulk RNA-seq or proteomics). The required input is a data matrix with samples and any type of expression level of genes/protein/other with a unique ID. The output is an interactive t-SNE or UMAP analysis that clusters genes (or proteins/other unique IDs) based on their expression patterns across the multiple samples enabling visualization of expression trends. Customizable settings for dimensionality reduction, data normalization, along with visualization parameters including coloring and filters, ensure adaptability to a variety of user uploaded data.ConclusionThis local and cloud-hosted web browser app enables investigation of any -omic data matrix in a rapid and code-independent manner. With the continued growth of available -omic data, the ability to quickly evaluate a dataset, including specific genes of interest, is more important than ever. GECO is intended to supplement traditional statistical analysis methods and is particularly useful when visualizing clusters of genes with similar trajectories across many samples (ex: multiple cell types, time course, dose response). Users will be empowered to investigate -omic data with a new lens of visualization and analysis that has the potential to uncover genes of interest, cohorts of co-regulated genes programs, and previously undetected patterns of expression.

Published

2021

2. GECO: gene expression clustering optimization app for non-linear data visualization of patterns

Author

A. N. Habowski, T. J. Habowski, and M. L. Waterman

Subjects

RNA-seq, Gene expression, t-SNE, UMAP, PCA, Clustering, Computer applications to medicine. Medical informatics, R858-859.7, Biology (General), QH301-705.5

Abstract

Abstract Background Due to continued advances in sequencing technology, the limitation in understanding biological systems through an “-omics” lens is no longer the generation of data, but the ability to analyze it. Importantly, much of this rich -omics data is publicly available waiting to be further investigated. Although many code-based pipelines exist, there is a lack of user-friendly and accessible applications that enable rapid analysis or visualization of data. Results GECO (Gene Expression Clustering Optimization; http://www.theGECOapp.com ) is a minimalistic GUI app that utilizes non-linear reduction techniques to rapidly visualize expression trends in many types of biological data matrices (such as bulk RNA-seq or proteomics). The required input is a data matrix with samples and any type of expression level of genes/protein/other with a unique ID. The output is an interactive t-SNE or UMAP analysis that clusters genes (or proteins/other unique IDs) based on their expression patterns across the multiple samples enabling visualization of expression trends. Customizable settings for dimensionality reduction, data normalization, along with visualization parameters including coloring and filters, ensure adaptability to a variety of user uploaded data. Conclusion This local and cloud-hosted web browser app enables investigation of any -omic data matrix in a rapid and code-independent manner. With the continued growth of available -omic data, the ability to quickly evaluate a dataset, including specific genes of interest, is more important than ever. GECO is intended to supplement traditional statistical analysis methods and is particularly useful when visualizing clusters of genes with similar trajectories across many samples (ex: multiple cell types, time course, dose response). Users will be empowered to investigate -omic data with a new lens of visualization and analysis that has the potential to uncover genes of interest, cohorts of co-regulated genes programs, and previously undetected patterns of expression.

Published

2021

3. Visualizing histopathologic deep learning classification and anomaly detection using nonlinear feature space dimensionality reduction

Author

Kevin Faust, Quin Xie, Dominick Han, Kartikay Goyle, Zoya Volynskaya, Ugljesa Djuric, and Phedias Diamandis

Subjects

Digital pathology, Deep learning, Convolutional neural networks, t-SNE, Diagnostics, Neuropathology, Computer applications to medicine. Medical informatics, R858-859.7, Biology (General), QH301-705.5

Abstract

Abstract Background There is growing interest in utilizing artificial intelligence, and particularly deep learning, for computer vision in histopathology. While accumulating studies highlight expert-level performance of convolutional neural networks (CNNs) on focused classification tasks, most studies rely on probability distribution scores with empirically defined cutoff values based on post-hoc analysis. More generalizable tools that allow humans to visualize histology-based deep learning inferences and decision making are scarce. Results Here, we leverage t-distributed Stochastic Neighbor Embedding (t-SNE) to reduce dimensionality and depict how CNNs organize histomorphologic information. Unique to our workflow, we develop a quantitative and transparent approach to visualizing classification decisions prior to softmax compression. By discretizing the relationships between classes on the t-SNE plot, we show we can super-impose randomly sampled regions of test images and use their distribution to render statistically-driven classifications. Therefore, in addition to providing intuitive outputs for human review, this visual approach can carry out automated and objective multi-class classifications similar to more traditional and less-transparent categorical probability distribution scores. Importantly, this novel classification approach is driven by a priori statistically defined cutoffs. It therefore serves as a generalizable classification and anomaly detection tool less reliant on post-hoc tuning. Conclusion Routine incorporation of this convenient approach for quantitative visualization and error reduction in histopathology aims to accelerate early adoption of CNNs into generalized real-world applications where unanticipated and previously untrained classes are often encountered.

Published

2018

4. Visualizing histopathologic deep learning classification and anomaly detection using nonlinear feature space dimensionality reduction.

Author

Faust, Kevin, Xie, Quin, Han, Dominick, Goyle, Kartikay, Volynskaya, Zoya, Djuric, Ugljesa, and Diamandis, Phedias

Subjects

*ARTIFICIAL intelligence, *DEEP learning, *COMPUTER vision, *ARTIFICIAL neural networks, *ANOMALY detection (Computer security)

Abstract

Background: There is growing interest in utilizing artificial intelligence, and particularly deep learning, for computer vision in histopathology. While accumulating studies highlight expert-level performance of convolutional neural networks (CNNs) on focused classification tasks, most studies rely on probability distribution scores with empirically defined cutoff values based on post-hoc analysis. More generalizable tools that allow humans to visualize histology-based deep learning inferences and decision making are scarce. Results: Here, we leverage t-distributed Stochastic Neighbor Embedding (t-SNE) to reduce dimensionality and depict how CNNs organize histomorphologic information. Unique to our workflow, we develop a quantitative and transparent approach to visualizing classification decisions prior to softmax compression. By discretizing the relationships between classes on the t-SNE plot, we show we can super-impose randomly sampled regions of test images and use their distribution to render statistically-driven classifications. Therefore, in addition to providing intuitive outputs for human review, this visual approach can carry out automated and objective multi-class classifications similar to more traditional and less-transparent categorical probability distribution scores. Importantly, this novel classification approach is driven by a priori statistically defined cutoffs. It therefore serves as a generalizable classification and anomaly detection tool less reliant on post-hoc tuning. Conclusion: Routine incorporation of this convenient approach for quantitative visualization and error reduction in histopathology aims to accelerate early adoption of CNNs into generalized real-world applications where unanticipated and previously untrained classes are often encountered. [ABSTRACT FROM AUTHOR]

Published

2018

5. GECO: gene expression clustering optimization app for non-linear data visualization of patterns

Author

Amber N Habowski, T. J. Habowski, and Marian L. Waterman

Subjects

Computer science, Computational biology, lcsh:Computer applications to medicine. Medical informatics, Biochemistry, Clustering, 03 medical and health sciences, 0302 clinical medicine, Data visualization, Structural Biology, Cluster Analysis, Cluster analysis, Molecular Biology, lcsh:QH301-705.5, 030304 developmental biology, 0303 health sciences, Biological data, PCA, Sequence Analysis, RNA, business.industry, Applied Mathematics, Dimensionality reduction, UMAP, Expression (mathematics), t-SNE, Computer Science Applications, Visualization, lcsh:Biology (General), 030220 oncology & carcinogenesis, lcsh:R858-859.7, Gene expression, DNA microarray, RNA-seq, App, business, Software

Abstract

Background Due to continued advances in sequencing technology, the limitation in understanding biological systems through an “-omics” lens is no longer the generation of data, but the ability to analyze it. Importantly, much of this rich -omics data is publicly available waiting to be further investigated. Although many code-based pipelines exist, there is a lack of user-friendly and accessible applications that enable rapid analysis or visualization of data. Results GECO (Gene Expression Clustering Optimization; http://www.theGECOapp.com) is a minimalistic GUI app that utilizes non-linear reduction techniques to rapidly visualize expression trends in many types of biological data matrices (such as bulk RNA-seq or proteomics). The required input is a data matrix with samples and any type of expression level of genes/protein/other with a unique ID. The output is an interactive t-SNE or UMAP analysis that clusters genes (or proteins/other unique IDs) based on their expression patterns across the multiple samples enabling visualization of expression trends. Customizable settings for dimensionality reduction, data normalization, along with visualization parameters including coloring and filters, ensure adaptability to a variety of user uploaded data. Conclusion This local and cloud-hosted web browser app enables investigation of any -omic data matrix in a rapid and code-independent manner. With the continued growth of available -omic data, the ability to quickly evaluate a dataset, including specific genes of interest, is more important than ever. GECO is intended to supplement traditional statistical analysis methods and is particularly useful when visualizing clusters of genes with similar trajectories across many samples (ex: multiple cell types, time course, dose response). Users will be empowered to investigate -omic data with a new lens of visualization and analysis that has the potential to uncover genes of interest, cohorts of co-regulated genes programs, and previously undetected patterns of expression.

Published

2021

6. Visualizing histopathologic deep learning classification and anomaly detection using nonlinear feature space dimensionality reduction

Author

Ugljesa Djuric, Phedias Diamandis, Dominick Han, Quin Xie, Kartikay Goyle, Zoya I. Volynskaya, and Kevin Faust

Subjects

0301 basic medicine, Artificial intelligence, Discretization, Computer science, Feature vector, lcsh:Computer applications to medicine. Medical informatics, Machine learning, computer.software_genre, Biochemistry, Convolutional neural network, Machine Learning, 03 medical and health sciences, Structural Biology, Humans, Digital pathology, lcsh:QH301-705.5, Diagnostics, Molecular Biology, Categorical variable, Neuropathology, Cancer, business.industry, Methodology Article, Applied Mathematics, Deep learning, Dimensionality reduction, t-SNE, Computer Science Applications, 030104 developmental biology, lcsh:Biology (General), Softmax function, lcsh:R858-859.7, Embedding, Probability distribution, Convolutional neural networks, Anomaly detection, Neural Networks, Computer, Glioblastoma, business, computer, Curse of dimensionality

Abstract

Background There is growing interest in utilizing artificial intelligence, and particularly deep learning, for computer vision in histopathology. While accumulating studies highlight expert-level performance of convolutional neural networks (CNNs) on focused classification tasks, most studies rely on probability distribution scores with empirically defined cutoff values based on post-hoc analysis. More generalizable tools that allow humans to visualize histology-based deep learning inferences and decision making are scarce. Results Here, we leverage t-distributed Stochastic Neighbor Embedding (t-SNE) to reduce dimensionality and depict how CNNs organize histomorphologic information. Unique to our workflow, we develop a quantitative and transparent approach to visualizing classification decisions prior to softmax compression. By discretizing the relationships between classes on the t-SNE plot, we show we can super-impose randomly sampled regions of test images and use their distribution to render statistically-driven classifications. Therefore, in addition to providing intuitive outputs for human review, this visual approach can carry out automated and objective multi-class classifications similar to more traditional and less-transparent categorical probability distribution scores. Importantly, this novel classification approach is driven by a priori statistically defined cutoffs. It therefore serves as a generalizable classification and anomaly detection tool less reliant on post-hoc tuning. Conclusion Routine incorporation of this convenient approach for quantitative visualization and error reduction in histopathology aims to accelerate early adoption of CNNs into generalized real-world applications where unanticipated and previously untrained classes are often encountered. Electronic supplementary material The online version of this article (10.1186/s12859-018-2184-4) contains supplementary material, which is available to authorized users.

Published

2018