A critical step in detecting variants from next-generation sequencing data is post hoc filtering of putative variants called or predicted by computational tools. Here, we highlight four critical parameters that could enhance the accuracy of called single nucleotide variants and insertions/deletions: quality and deepness, refinement and improvement of initial mapping, allele/strand balance, and examination of spurious genes. Use of these sequence features appropriately in variant filtering could greatly improve validation rates, thereby saving time and costs in next-generation sequencing projects
abstract: Analyzing human DNA sequence data allows researchers to identify variants associated with ...
Background: Accurate calling of SNPs and genotypes from next-generation sequencing data is an essent...
The evolution of next-generation sequencing technologies has facilitated the detection of causal gen...
<div><p>A critical step in detecting variants from next-generation sequencing data is <em>post hoc</...
Next-generation sequencing (NGS) has enabled the high-throughput discovery of germline and somatic m...
Sequencing has revolutionized biology by permitting the analysis of genomic variation at an unpreced...
<div><p>A diversity of tools is available for identification of variants from genome sequence data. ...
Minor variants have significant implications in quasispecies evolution, early cancer detection and n...
Discovery of genome-wide variation has taken a huge leap forward with the introduction of next-gener...
Next-generation sequencing (NGS) has enabled the high-throughput discovery of germline and somatic m...
Next-Generation Sequencing has become an important tool in the field of human genetics. The coding s...
Massive parallel sequencing (NGS) is useful in detecting and later classifying somatic driver mutati...
Next-generation sequencing technology (NGS) enables the discovery of nearly all genetic variants pre...
International audienceHigh-throughput sequencing technologies have become fundamental for the identi...
Meaningful analysis of next-generation sequencing (NGS) data, extensively produced by genomics studi...
abstract: Analyzing human DNA sequence data allows researchers to identify variants associated with ...
Background: Accurate calling of SNPs and genotypes from next-generation sequencing data is an essent...
The evolution of next-generation sequencing technologies has facilitated the detection of causal gen...
<div><p>A critical step in detecting variants from next-generation sequencing data is <em>post hoc</...
Next-generation sequencing (NGS) has enabled the high-throughput discovery of germline and somatic m...
Sequencing has revolutionized biology by permitting the analysis of genomic variation at an unpreced...
<div><p>A diversity of tools is available for identification of variants from genome sequence data. ...
Minor variants have significant implications in quasispecies evolution, early cancer detection and n...
Discovery of genome-wide variation has taken a huge leap forward with the introduction of next-gener...
Next-generation sequencing (NGS) has enabled the high-throughput discovery of germline and somatic m...
Next-Generation Sequencing has become an important tool in the field of human genetics. The coding s...
Massive parallel sequencing (NGS) is useful in detecting and later classifying somatic driver mutati...
Next-generation sequencing technology (NGS) enables the discovery of nearly all genetic variants pre...
International audienceHigh-throughput sequencing technologies have become fundamental for the identi...
Meaningful analysis of next-generation sequencing (NGS) data, extensively produced by genomics studi...
abstract: Analyzing human DNA sequence data allows researchers to identify variants associated with ...
Background: Accurate calling of SNPs and genotypes from next-generation sequencing data is an essent...
The evolution of next-generation sequencing technologies has facilitated the detection of causal gen...