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Field guidelines for genetic experimental designs in high-throughput sequencing[electronic resource] /

紀錄類型:	書目-電子資源 : Monograph/item
杜威分類號:	572.8633
書名/作者:	Field guidelines for genetic experimental designs in high-throughput sequencing/ edited by Ana M. Aransay, Jose Luis Lavin Trueba.
其他作者:	Aransay, Ana M.
出版者:	Cham : : Springer International Publishing :, 2016.
面頁冊數:	xi, 399 p. : : ill., digital ;; 24 cm.
Contained By:	Springer eBooks
標題:	Nucleotide sequence.
標題:	Combinatorial chemistry.
標題:	Biomedicine.
標題:	Human Genetics.
標題:	Systems Biology.
標題:	Biostatistics.
ISBN:	9783319313504
ISBN:	9783319313481
內容註:	The High Throughput Sequencing technologies triple-W discussion: Why to use HTS, What is the optimal HTS method to use, Which data analysis workflow to follow -- Whole genome sequencing recommendations -- Counseling for targeted DNA region re-sequencing -- Transcriptome profiling strategies -- Differential mRNA Alternative Splicing -- microRNA discovery and expression analysis in animals -- Analysis of Long Non-coding RNAs in RNA-seq data -- Ribosome profiling -- Genome-wide analysis of DNA methylation patterns by high-throughput sequencing -- Characterization of DNA-protein interactions: Design and analysis of ChIP-seq experiments -- PAR-CLIP: A genomic technique to dissect RNA-protein interactions -- Metagenomic design and sequencing -- A hitchhiker's guide to Metatranscriptomics -- Eukaryotic Single-Cell mRNA Sequencing -- Eukaryotic Single-Cell DNA Sequencing -- Submitting data to a public repository, the final step of a successful HTS experiment.
摘要、提要註:	High throughput sequencing (HTS) technologies have conquered the genomics and epigenomics worlds. The applications of HTS methods are wide, and can be used to sequence everything from whole or partial genomes, transcriptomes, non-coding RNAs, ribosome profiling, to single-cell sequencing. Having such diversity of alternatives, there is a demand for information by research scientists without experience in HTS that need to choose the most suitable methodology or combination of platforms and to define their experimental designs to achieve their specific objectives. Field Guidelines for Genetic Experimental Designs in High-Throughput Sequencing aims to collect in a single volume all aspects that should be taken into account when HTS technologies are being incorporated into a research project and the reasons behind them. Moreover, examples of several successful strategies will be analyzed to make the point of the crucial features. This book will be of use to all scientist that are unfamiliar with HTS and want to incorporate such technologies to their research.
電子資源:	http://dx.doi.org/10.1007/978-3-319-31350-4

Field guidelines for genetic experimental designs in high-throughput sequencing[electronic resource] /
Field guidelines for genetic experimental designs in high-throughput sequencing[electronic resource] /edited by Ana M. Aransay, Jose Luis Lavin Trueba. - Cham :Springer International Publishing :2016. - xi, 399 p. :ill., digital ;24 cm.

The High Throughput Sequencing technologies triple-W discussion: Why to use HTS, What is the optimal HTS method to use, Which data analysis workflow to follow -- Whole genome sequencing recommendations -- Counseling for targeted DNA region re-sequencing -- Transcriptome profiling strategies -- Differential mRNA Alternative Splicing -- microRNA discovery and expression analysis in animals -- Analysis of Long Non-coding RNAs in RNA-seq data -- Ribosome profiling -- Genome-wide analysis of DNA methylation patterns by high-throughput sequencing -- Characterization of DNA-protein interactions: Design and analysis of ChIP-seq experiments -- PAR-CLIP: A genomic technique to dissect RNA-protein interactions -- Metagenomic design and sequencing -- A hitchhiker's guide to Metatranscriptomics -- Eukaryotic Single-Cell mRNA Sequencing -- Eukaryotic Single-Cell DNA Sequencing -- Submitting data to a public repository, the final step of a successful HTS experiment.

High throughput sequencing (HTS) technologies have conquered the genomics and epigenomics worlds. The applications of HTS methods are wide, and can be used to sequence everything from whole or partial genomes, transcriptomes, non-coding RNAs, ribosome profiling, to single-cell sequencing. Having such diversity of alternatives, there is a demand for information by research scientists without experience in HTS that need to choose the most suitable methodology or combination of platforms and to define their experimental designs to achieve their specific objectives. Field Guidelines for Genetic Experimental Designs in High-Throughput Sequencing aims to collect in a single volume all aspects that should be taken into account when HTS technologies are being incorporated into a research project and the reasons behind them. Moreover, examples of several successful strategies will be analyzed to make the point of the crucial features. This book will be of use to all scientist that are unfamiliar with HTS and want to incorporate such technologies to their research.

ISBN: 9783319313504

Standard No.: 10.1007/978-3-319-31350-4doiSubjects--Topical Terms:

222714
Nucleotide sequence.

LC Class. No.: QP625.N89

Dewey Class. No.: 572.8633

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520 $a High throughput sequencing (HTS) technologies have conquered the genomics and epigenomics worlds. The applications of HTS methods are wide, and can be used to sequence everything from whole or partial genomes, transcriptomes, non-coding RNAs, ribosome profiling, to single-cell sequencing. Having such diversity of alternatives, there is a demand for information by research scientists without experience in HTS that need to choose the most suitable methodology or combination of platforms and to define their experimental designs to achieve their specific objectives. Field Guidelines for Genetic Experimental Designs in High-Throughput Sequencing aims to collect in a single volume all aspects that should be taken into account when HTS technologies are being incorporated into a research project and the reasons behind them. Moreover, examples of several successful strategies will be analyzed to make the point of the crucial features. This book will be of use to all scientist that are unfamiliar with HTS and want to incorporate such technologies to their research.
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