Whole Genome Sequencing: is the process of determining the complete DNA sequence of an organism's genome. In order to do so, you must entail all of an organism's chromosomal DNA as well as DNA contained in the mitochondria and, for plants, in the chloroplast.
Genetic disease is the leading cause of death for infants in the intensive care units. Traditional testing is too slow to provide physicians a timely diagnosis to help guide the management of...
Genetic testing currently plays a relatively niche role in healthcare, with testing typically limited to single genes and targeting a relatively narrow range of diseases, including paediatric...
A recent clinical trial of the AR inhibitor enzalutamide in patients with TNBC included an exploratory endpoint using RNA sequencing to identify a genomic signature of patients likely to resp...
Clinical whole genome sequencing (cWGS) is rapidly gaining acceptance as cost is decreasing and success rates in identifying disease-causing variants are increasing. While the application of...
Recent advances in DNA sequencing have now made it possible to characterize genomes, transcriptomes and even methylomes which is transforming both basic research and clinical practice. Whole...
DATE: November 16, 2016
TIME: 8:00am PT, 11:00am ET
Breast cancer is the most commonly diagnosed cancer in women and is the second leading cause of cancer death among wo...
Whole genome and exome sequencing is being widely used to identify disease-causing variants in patients with hereditary and rare diseases. Discovering the true disease-causing variants often...
Targeted sequencing assays are increasingly used to identify tumor mutations that guide therapeutic decisions. Interpretation of a cancer variant’s origin and therapeutic impact poses a...
In order to realize the benefits of personalized cancer therapy, increasing demands are placed upon clinical laboratories to provide timely, comprehensive, clinically actionable, and analytic...
DNA methylation is an essential mechanism of epigenetic gene regulation with broad relevance in development and disease. Its localization on genomic DNA and general stability make this epigen...
Technological advances allow for the large scale sequencing of the whole human genome. Most studies have generated population-based information on human diversity using low to intermediate co...
It is estimated that by the end of this year more than 1 million people worldwide will have had their genome sequenced. Genomic sequencing is increasingly being integrated into clinical care,...
The rapid implementation of next generation sequencing is changing how genetics and genomics are applied in a clinical setting. However, the quickly evolving technology can be challenging to...
Human breast tumors have been shown to exhibit extensive inter- and intra-tumor heterogeneity. While recent advances in genomic technologies have allowed us to deconvolute this heterogeneity,...
Technological advances have made genomic sequencing more affordable, efficient, and available. Questions related to the implementation and effects of large-scale sequencing in healthcare have...
Emerging technologies facilitate basic science research, but their value in regulatory applications requires rigorous assessment and consensus within the research community. Next-generation s...
New approaches to generate high-quality representations of human genomes and transcriptomes are now becoming available. In contrast to short-read “Whole-Genome” re-sequencing meth...
Advances in DNA sequencing technology are about to transform healthcare. Since completion of the human genome reference sequence ten years ago, there has been a 1-million fold im...
It has been estimated that every human being carries ~20 rare “natural human gene knockouts”-DNA variants in protein-coding regions of the genome that partially or completely inac...
Cancer remains the second leading cause of death in the United States. Most tumors arise from a myriad of genetic changes that dysregulate cell growth and prompt survival. Ident...
Recent advances in next-generation sequencing (NGS) have helped to accelerate the pace of discovery in the field of genetic disease research and testing. The ability to analyze multiple genes...
Medical genetics is a specialty of medicine that encompasses patients at all ages (prenatal, pediatric, adult), as well as all organ systems. As the genetic causes of more diseases have been ...
A century and a half after we first probed heritability, we risk forgetting one of Mendel's own basic findings, in rushing to broaden clinical genomics to lifelong care for all. Embracing...
The advent of the microarray technology in 2000 has paved the way for advanced translational research methods that use molecular markers such as microRNA, proteins, metabolites and copy numbe...
Genetic disease is the leading cause of death for infants in the intensive care units. Traditional testing is too slow to provide physicians a timely diagnosis to help guide the management of...
Genetic testing currently plays a relatively niche role in healthcare, with testing typically limited to single genes and targeting a relatively narrow range of diseases, including paediatric...
A recent clinical trial of the AR inhibitor enzalutamide in patients with TNBC included an exploratory endpoint using RNA sequencing to identify a genomic signature of patients likely to resp...
Clinical whole genome sequencing (cWGS) is rapidly gaining acceptance as cost is decreasing and success rates in identifying disease-causing variants are increasing. While the application of...
Recent advances in DNA sequencing have now made it possible to characterize genomes, transcriptomes and even methylomes which is transforming both basic research and clinical practice. Whole...
DATE: November 16, 2016
TIME: 8:00am PT, 11:00am ET
Breast cancer is the most commonly diagnosed cancer in women and is the second leading cause of cancer death among wo...
Whole genome and exome sequencing is being widely used to identify disease-causing variants in patients with hereditary and rare diseases. Discovering the true disease-causing variants often...
Targeted sequencing assays are increasingly used to identify tumor mutations that guide therapeutic decisions. Interpretation of a cancer variant’s origin and therapeutic impact poses a...
In order to realize the benefits of personalized cancer therapy, increasing demands are placed upon clinical laboratories to provide timely, comprehensive, clinically actionable, and analytic...
DNA methylation is an essential mechanism of epigenetic gene regulation with broad relevance in development and disease. Its localization on genomic DNA and general stability make this epigen...
Technological advances allow for the large scale sequencing of the whole human genome. Most studies have generated population-based information on human diversity using low to intermediate co...
It is estimated that by the end of this year more than 1 million people worldwide will have had their genome sequenced. Genomic sequencing is increasingly being integrated into clinical care,...
The rapid implementation of next generation sequencing is changing how genetics and genomics are applied in a clinical setting. However, the quickly evolving technology can be challenging to...
Human breast tumors have been shown to exhibit extensive inter- and intra-tumor heterogeneity. While recent advances in genomic technologies have allowed us to deconvolute this heterogeneity,...
Technological advances have made genomic sequencing more affordable, efficient, and available. Questions related to the implementation and effects of large-scale sequencing in healthcare have...
Emerging technologies facilitate basic science research, but their value in regulatory applications requires rigorous assessment and consensus within the research community. Next-generation s...
New approaches to generate high-quality representations of human genomes and transcriptomes are now becoming available. In contrast to short-read “Whole-Genome” re-sequencing meth...
Advances in DNA sequencing technology are about to transform healthcare. Since completion of the human genome reference sequence ten years ago, there has been a 1-million fold im...
It has been estimated that every human being carries ~20 rare “natural human gene knockouts”-DNA variants in protein-coding regions of the genome that partially or completely inac...
Cancer remains the second leading cause of death in the United States. Most tumors arise from a myriad of genetic changes that dysregulate cell growth and prompt survival. Ident...
Recent advances in next-generation sequencing (NGS) have helped to accelerate the pace of discovery in the field of genetic disease research and testing. The ability to analyze multiple genes...
Medical genetics is a specialty of medicine that encompasses patients at all ages (prenatal, pediatric, adult), as well as all organ systems. As the genetic causes of more diseases have been ...
A century and a half after we first probed heritability, we risk forgetting one of Mendel's own basic findings, in rushing to broaden clinical genomics to lifelong care for all. Embracing...
The advent of the microarray technology in 2000 has paved the way for advanced translational research methods that use molecular markers such as microRNA, proteins, metabolites and copy numbe...
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