Copy Number Variants

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Cover of 'Copy Number Variants'

Table of Contents

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Book Overview
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Chapter 1 Identification of Copy Number Variants from SNP Arrays Using PennCNV
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Chapter 2 Using SAAS-CNV to Detect and Characterize Somatic Copy Number Alterations in Cancer Genomes from Next Generation Sequencing and SNP Array Data
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Chapter 3 Statistical Detection of Genome Differences Based on CNV Segments
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Chapter 4 Whole-Genome Shotgun Sequence CNV Detection Using Read Depth
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Chapter 5 Read Depth Analysis to Identify CNV in Bacteria Using CNOGpro
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Chapter 6 Using HaMMLET for Bayesian Segmentation of WGS Read-Depth Data
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Chapter 7 Split-Read Indel and Structural Variant Calling Using PINDEL
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Chapter 8 Detecting Small Inversions Using SRinversion
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Chapter 9 Detection of CNVs in NGS Data Using VS-CNV
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Chapter 10 Structural Variant Breakpoint Detection with novoBreak
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Chapter 11 Use of RAPTR-SV to Identify SVs from Read Pairing and Split Read Signatures
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Chapter 12 Versatile Identification of Copy Number Variants with Canvas
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Chapter 13 A Randomized Iterative Approach for SV Discovery with SVelter
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Chapter 14 Analysis of Population-Genetic Properties of Copy Number Variations
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Chapter 15 Validation of Genomic Structural Variants Through Long Sequencing Technologies
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Chapter 16 Structural Variation Detection and Analysis Using Bionano Optical Mapping

Attention for Chapter 6: Using HaMMLET for Bayesian Segmentation of WGS Read-Depth Data

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Chapter title	Using HaMMLET for Bayesian Segmentation of WGS Read-Depth Data
Chapter number	6
Book title	Copy Number Variants
Published in	Methods in molecular biology, January 2018
DOI	10.1007/978-1-4939-8666-8_6
Pubmed ID	30039365
Book ISBNs	978-1-4939-8665-1, 978-1-4939-8666-8
Authors	John Wiedenhoeft, Alexander Schliep, Wiedenhoeft, John, Schliep, Alexander
Abstract	CNV detection requires a high-quality segmentation of genomic data. In many WGS experiments, sample and control are sequenced together in a multiplexed fashion using DNA barcoding for economic reasons. Using the differential read depth of these two conditions cancels out systematic additive errors. Due to this detrending, the resulting data is appropriate for inference using a hidden Markov model (HMM), arguably one of the principal models for labeled segmentation. However, while the usual frequentist approaches such as Baum-Welch are problematic for several reasons, they are often preferred to Bayesian HMM inference, which normally requires prohibitively long running times and exceeds a typical user's computational resources on a genome scale data. HaMMLET solves this problem using a dynamic wavelet compression scheme, which makes Bayesian segmentation of WGS data feasible on standard consumer hardware.

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Mendeley readers

Mendeley readers

The data shown below were compiled from readership statistics for 7 Mendeley readers of this research output. Click here to see the associated Mendeley record.

Geographical breakdown

Country	Count	As %
Unknown	7	100%

Demographic breakdown

Readers by professional status	Count	As %
Student > Ph. D. Student	2	29%
Researcher	2	29%
Student > Doctoral Student	1	14%
Unknown	2	29%

Readers by discipline	Count	As %
Computer Science	2	29%
Business, Management and Accounting	1	14%
Social Sciences	1	14%
Unknown	3	43%