Single-cell Technologies: From Research to Application

Overview

Journal Innovation (Camb)

Publisher Cell Press

Specialty Biomedical Engineering

Date 2022 Nov 10

PMID 36353677

Authors

Lu Wen

Guoqiang Li

Tao Huang

Wei Geng

Hao Pei

Jialiang Yang

Miao Zhu

Pengfei Zhang

Rui Hou

Geng Tian

Wentao Su

Jian Chen

Dake Zhang

Pingan Zhu

Wei Zhang

Xiuxin Zhang

Ning Zhang

Yunlong Zhao

Xin Cao

Guangdun Peng

Xianwen Ren

Nan Jiang

Caihuan Tian

Zi-Jiang Chen

Affiliations

Soon will be listed here.

Abstract

In recent years, more and more single-cell technologies have been developed. A vast amount of single-cell omics data has been generated by large projects, such as the Human Cell Atlas, the Mouse Cell Atlas, the Mouse RNA Atlas, the Mouse ATAC Atlas, and the Plant Cell Atlas. Based on these single-cell big data, thousands of bioinformatics algorithms for quality control, clustering, cell-type annotation, developmental inference, cell-cell transition, cell-cell interaction, and spatial analysis are developed. With powerful experimental single-cell technology and state-of-the-art big data analysis methods based on artificial intelligence, the molecular landscape at the single-cell level can be revealed. With spatial transcriptomics and single-cell multi-omics, even the spatial dynamic multi-level regulatory mechanisms can be deciphered. Such single-cell technologies have many successful applications in oncology, assisted reproduction, embryonic development, and plant breeding. We not only review the experimental and bioinformatics methods for single-cell research, but also discuss their applications in various fields and forecast the future directions for single-cell technologies. We believe that spatial transcriptomics and single-cell multi-omics will become the next booming business for mechanism research and commercial industry.

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