Giotto: a toolbox for integrative analysis and visualization of spatial expression data

Dries, Ruben; Zhu, Qi; Dong, Rui; Eng, Chee-Huat Linus; Li, Huipeng; Liu, Kan; Fu, Yuntian; Zhao, Tianxiao; Sarkar, Arpan; Bao, Feng; George, Rani E.; Pierson, Nico; Cai, Long; Yuan, Guo‐Cheng

doi:10.1186/s13059-021-02286-2

Cited by 581 publications

(471 citation statements)

References 54 publications

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“…The package is available as an easily installable Python package, and can easily be extended with existing in situ transcriptomics pipelines, e.g. starfish ( https://github.com/spacetx/starfish ) or Giotto 36 . SSAM is accompanied with a notebook outlining all the steps presented in this paper.…”

Section: Discussionmentioning

confidence: 99%

Cell segmentation-free inference of cell types from in situ transcriptomics data

et al. 2021

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Multiplexed fluorescence in situ hybridization techniques have enabled cell-type identification, linking transcriptional heterogeneity with spatial heterogeneity of cells. However, inaccurate cell segmentation reduces the efficacy of cell-type identification and tissue characterization. Here, we present a method called Spot-based Spatial cell-type Analysis by Multidimensional mRNA density estimation (SSAM), a robust cell segmentation-free computational framework for identifying cell-types and tissue domains in 2D and 3D. SSAM is applicable to a variety of in situ transcriptomics techniques and capable of integrating prior knowledge of cell types. We apply SSAM to three mouse brain tissue images: the somatosensory cortex imaged by osmFISH, the hypothalamic preoptic region by MERFISH, and the visual cortex by multiplexed smFISH. Here, we show that SSAM detects regions occupied by known cell types that were previously missed and discovers new cell types.

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Section: Discussionmentioning

confidence: 99%

Cell segmentation-free inference of cell types from in situ transcriptomics data

et al. 2021

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“…The implementation of novel analysis tools requires further software ecosystems, including Bioconductor [61], Biopython, and toolkits such as Scanpy [62], Seurat [63], or Giotto [64], in which users can implement their analysis approaches, while anticipating stable and adaptive data structures that are applicable for these emerging technologies. The size of these emerging datasets, particularly in the context of their application to atlas projects (e.g., the Human Tumor Atlas Network [65], Human Cell Atlas [66], Allen Brain Initiative, Brain Initiative Cell Census Network, or ENCODE/Roadmap/4D [46]…”

Section: Discussionmentioning

confidence: 99%

Community-wide hackathons to identify central themes in single-cell multi-omics

et al. 2021

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“…1b and Supplementary Tables 1-2). Our results demonstrate RESEPT outperforms six existing tools, namely Seurat 5 , BayesSpace 7 , SpaGCN 9 , stLearn 8 , STUtility 12 , and Giotto 6 on tissue architecture identification in terms of Adjusted Rand Index (ARI) (Fig. 1c).…”

mentioning

confidence: 74%

“…Recent advances in spatially resolved technologies such as 10x Genomics Visium provide spatial context together with high-throughput gene expression for exploring tissue domains, cell types, cell-cell communications, and their biological consequences 4 . Some graph-based clustering methods ( e.g ., Seurat 5 and Giotto 6 ), statistical methods ( e.g ., BayesSpace 7 ), or deep learning-based methods ( e.g. , stLearn 8 and SpaGCN 9 ) can identify spatial architecture and interpret spatial heterogeneity.…”

Section: Mainmentioning

confidence: 99%

Define and visualize pathological architectures of human tissues from spatially resolved transcriptomics using deep learning

Chang

Wang

et al. 2021

Preprint

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We present RESEPT, a deep-learning framework for characterizing and visualizing tissue architecture from spatially resolved transcriptomics by reconstructing and segmenting a transcriptome mapped RGB image. RESEPT can identify the tissue architecture, and represent corresponding marker genes and biological functions accurately. RESEPT also provides critical insights into the underlying mechanisms driving the complex tissue heterogeneities in Alzheimer’s disease and glioblastoma.

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Giotto: a toolbox for integrative analysis and visualization of spatial expression data

Cited by 581 publications

References 54 publications

Cell segmentation-free inference of cell types from in situ transcriptomics data

Cell segmentation-free inference of cell types from in situ transcriptomics data

Community-wide hackathons to identify central themes in single-cell multi-omics

Define and visualize pathological architectures of human tissues from spatially resolved transcriptomics using deep learning

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