Bio-Rad Laboratories, Inc. Release: Droplet Digital PCR Provides Accurate Quantification of Next-Generation Sequencing Libraries
Get the latest biotech news where you want it. Sign up for the free GenePool newsletter today!
Seattle, WA – August 19, 2013 – A study published today found that Droplet Digital PCR (ddPCR™) can be used as an accurate and precise method for quality control of next-generation sequencing (NGS) libraries. NGS library QC is essential to optimizing sequencing data yield, thereby increasing efficiency and throughput while lowering cost. The research was published in the in the August issue of Biotechniques.
"While real-time PCR has traditionally been used to quantify libraries, we determined that the only truly accurate way to reproducibly quantify our NGS libraries is with ddPCR," said Dr. Jason Bielas, lead author and Assistant Member in the Public Health Sciences Division at Fred Hutchinson Cancer Research Center in Seattle, Wash.
Quantifying NGS Libraries and Why It Matters
Various commercial NGS technologies require users to load a precise number of viable DNA library molecules onto the instrument to optimize data yield. Performing a sequencing run with either too many or too few library molecules results in compromised data and sometimes no data at all – wasting sample, expensive reagents, user time, and instrument time.
Moreover, fewer bases might be sequenced if library molecules are not the appropriate length to fully utilize the sequencing platform, thus limiting throughput. Given this, quantifying library molecules and determining fragment size range have become crucial steps in library preparation.
NGS instrument manufacturers recommend quantifying libraries using real-time quantitative PCR (qPCR) and determining their size range using gel or capillary electrophoresis. Each of these has its limitations, though, and the steps recommended to address them, can be time-consuming and expensive.
Advantages of ddPCR for Quantifying NGS Libraries
To simultaneously quantify and determine the size distribution of target DNA with a single ddPCR assay, Dr. Bielas and his team exploited a relationship between droplet fluorescence and amplicon size. They confirmed the accuracy and precision of this method by applying it to NGS library preparation.
The ddPCR assay they designed – known as QuantiSize – was developed using the QX100 ddPCR system from Bio-Rad Laboratories. QuantiSize offers the ability to determine the absolute quantity and the detailed size distribution of target DNA in a single ddPCR reaction well, thus avoiding the drawbacks of other independent quantification and size determination methods.
"Now that we have discovered this new correlation, we can also use ddPCR to extract more information on the characteristics of DNA based on the range of fluorescence that can occur within each droplet," said Bielas.
Having demonstrated the efficacy of this technique, Dr. Bielas is now planning to leverage the relationship between ddPCR fluorescence and amplicon size to explore mutagenic deletion events in both the human nuclear and mitochondrial genomes.
About Fred Hutchinson Cancer Research Center
At Fred Hutchinson Cancer Research Center, home to three Nobel laureates, interdisciplinary teams of world-renowned scientists seek new and innovative ways to prevent, diagnose and treat cancer, HIV/AIDS and other life-threatening diseases. Fred Hutch's pioneering work in bone marrow transplantation led to the development of immunotherapy, which harnesses the power of the immune system to treat cancer with minimal side effects. An independent, nonprofit research institute based in Seattle, Fred Hutch houses the nation's first and largest cancer prevention research program, as well as the clinical coordinating center of the Women's Health Initiative and the international headquarters of the HIV Vaccine Trials Network. Private contributions are essential for enabling Fred Hutch scientists to explore novel research opportunities that lead to important medical breakthroughs. For more information visit http://www.fredhutch.org or follow Fred Hutch on Facebook, Twitter or YouTube.
About Bio-Rad
Bio-Rad Laboratories, Inc. (NYSE: BIO and BIOb) has been at the center of scientific discovery for 60 years, manufacturing and distributing a broad range of products for life science research and clinical diagnostic markets. The company is renowned for its commitment to quality and customer service among university and research institutions, hospitals, public health and commercial laboratories, as well as the biotechnology, pharmaceutical, and food safety industries. Founded in 1952, Bio-Rad is based in Hercules, California, and serves more than 100,000 research and industry customers through its global network of operations. The company employs approximately 7,600 people worldwide and had revenues exceeding $2 billion in 2012. Visit us at http://www.bio-rad.com.
Help employers find you! Check out all the jobs and post your resume.
Seattle, WA – August 19, 2013 – A study published today found that Droplet Digital PCR (ddPCR™) can be used as an accurate and precise method for quality control of next-generation sequencing (NGS) libraries. NGS library QC is essential to optimizing sequencing data yield, thereby increasing efficiency and throughput while lowering cost. The research was published in the in the August issue of Biotechniques.
"While real-time PCR has traditionally been used to quantify libraries, we determined that the only truly accurate way to reproducibly quantify our NGS libraries is with ddPCR," said Dr. Jason Bielas, lead author and Assistant Member in the Public Health Sciences Division at Fred Hutchinson Cancer Research Center in Seattle, Wash.
Quantifying NGS Libraries and Why It Matters
Various commercial NGS technologies require users to load a precise number of viable DNA library molecules onto the instrument to optimize data yield. Performing a sequencing run with either too many or too few library molecules results in compromised data and sometimes no data at all – wasting sample, expensive reagents, user time, and instrument time.
Moreover, fewer bases might be sequenced if library molecules are not the appropriate length to fully utilize the sequencing platform, thus limiting throughput. Given this, quantifying library molecules and determining fragment size range have become crucial steps in library preparation.
NGS instrument manufacturers recommend quantifying libraries using real-time quantitative PCR (qPCR) and determining their size range using gel or capillary electrophoresis. Each of these has its limitations, though, and the steps recommended to address them, can be time-consuming and expensive.
Advantages of ddPCR for Quantifying NGS Libraries
To simultaneously quantify and determine the size distribution of target DNA with a single ddPCR assay, Dr. Bielas and his team exploited a relationship between droplet fluorescence and amplicon size. They confirmed the accuracy and precision of this method by applying it to NGS library preparation.
The ddPCR assay they designed – known as QuantiSize – was developed using the QX100 ddPCR system from Bio-Rad Laboratories. QuantiSize offers the ability to determine the absolute quantity and the detailed size distribution of target DNA in a single ddPCR reaction well, thus avoiding the drawbacks of other independent quantification and size determination methods.
"Now that we have discovered this new correlation, we can also use ddPCR to extract more information on the characteristics of DNA based on the range of fluorescence that can occur within each droplet," said Bielas.
Having demonstrated the efficacy of this technique, Dr. Bielas is now planning to leverage the relationship between ddPCR fluorescence and amplicon size to explore mutagenic deletion events in both the human nuclear and mitochondrial genomes.
About Fred Hutchinson Cancer Research Center
At Fred Hutchinson Cancer Research Center, home to three Nobel laureates, interdisciplinary teams of world-renowned scientists seek new and innovative ways to prevent, diagnose and treat cancer, HIV/AIDS and other life-threatening diseases. Fred Hutch's pioneering work in bone marrow transplantation led to the development of immunotherapy, which harnesses the power of the immune system to treat cancer with minimal side effects. An independent, nonprofit research institute based in Seattle, Fred Hutch houses the nation's first and largest cancer prevention research program, as well as the clinical coordinating center of the Women's Health Initiative and the international headquarters of the HIV Vaccine Trials Network. Private contributions are essential for enabling Fred Hutch scientists to explore novel research opportunities that lead to important medical breakthroughs. For more information visit http://www.fredhutch.org or follow Fred Hutch on Facebook, Twitter or YouTube.
About Bio-Rad
Bio-Rad Laboratories, Inc. (NYSE: BIO and BIOb) has been at the center of scientific discovery for 60 years, manufacturing and distributing a broad range of products for life science research and clinical diagnostic markets. The company is renowned for its commitment to quality and customer service among university and research institutions, hospitals, public health and commercial laboratories, as well as the biotechnology, pharmaceutical, and food safety industries. Founded in 1952, Bio-Rad is based in Hercules, California, and serves more than 100,000 research and industry customers through its global network of operations. The company employs approximately 7,600 people worldwide and had revenues exceeding $2 billion in 2012. Visit us at http://www.bio-rad.com.
Help employers find you! Check out all the jobs and post your resume.