Single cell sequencing is a next-generation sequencing (NGS) method that examines the genomes or transcriptomes of individual cells, giving a high-resolution view of cell-to-cell variation. Single-cell RNA sequencing (scRNA-seq) technologies allow the dissection of gene expression at single-cell resolution, which greatly revolutionizes transcriptomic studies.
Single-cell RNA sequencing has emerged as an important technology that can reveal gene expression differences between different cell types. This webinar will demonstrate how bioinformatics s...
CRISPR-Cas9 gene editing is a powerful technique that enables genetic modification with greater speed and accuracy than previous approaches. In this webinar, Dr. Chen highlights the advantag...
As the spread of infectious diseases, current pandemic, and growing antimicrobial resistance (AMR) continues globally, next-generation sequencing (NGS) and specifically metagenomics became a...
With the completion of the human genome nearly two decades ago, consumers, patients, and physicians are wondering when genetic testing will go PRIME TIME. While the diagnostic utility of gen...
In this presentation Dr. Kevin Halling describes the use of RNA-seq testing for identifying clinically significant gene fusions in tumors that can be used to help establish diagnosis and gui...
Complex genomes, including the human genome, contain ‘dark’ regions that standard short-read sequencing technologies do not adequately resolve—overlooking many variants tha...
Realizing the promise of Precision Medicine requires both a deep understanding of the landscape of genomic evidence and an understanding of the molecular drivers that influence all aspects o...
As genomics plays an ever expanding role in healthcare and research, educational programs focused on applied genomics have not kept pace with the demand for trained students. In this talk, w...
In recent years Nanotherapeutics has revolutionized the healthcare strategies and envisioned to have a tremendous impact to offer better health facilities. It involves design, fabrication, r...
Achieving a diagnosis in rare disease patients can be challenging for even the most experienced clinician or scientist, creating a barrier to delivering truly personalised care. An exome seq...
The introduction of improved, more cost efficient target capture technologies has accelerated the adoption of Whole Exome Sequencing (WES) in clinical diagnostics. The ability to provide mor...
Estrogen metabolism is the ability to favorably excrete potentially toxic estrogens through urine and sweat. Impaired estrogen metabolism is associated with Endometriosis and Polycystic Ovar...
Graphene-based Biology-gated Transistors (Cardean Transistors) directly read molecular signals of active biology using advanced electronics. This proprietary tech breakthrough can be used as...
Triple-negative breast cancer (TNBC) is an aggressive disease that accounts for 10-20% of all breast cancer cases diagnosed annually in the U.S.1. Despite its prevalence, TNBC remains resist...
Within the clinical arena, the oncology community has led the way in the early adoption of next generation sequencing. NGS is in widespread use in clinical cancer research and is now beginni...
Careful and deliberate packaging of the genome is essential to ensuring correct and timely transcriptional programs. Chromatin conformation capture (3C and Hi-C) is a powerful approach for c...
The introduction of PacBio HiFi sequence reads, which are both long (up to 25 kb currently) and accurate (>99%) at the individual single-molecule sequence read level, has allowed for adva...
Karyomapping, a technique for preimplantation genetic diagnosis (PGD) of single gene disorders, involves using very few or single cells, and comes with challenges due to limited amounts of s...
Modern biomedical research is being driven by large scale genetic and proteomic research to identify new targets for the study of disease mechanisms. While these techniques have been incredi...
The versatility of standard PCR and qPCR is well known. Digital PCR is now taking this to a whole new level. The power of partitioning enables you to explore new frontiers which have been li...
Long-read DNA sequencing technologies such as the Pacific Biosciences (PacBio) and Oxford Nanopore (ONT) platforms, have demonstrated enhanced detection of genomic variation, including Singl...
Single cell RNA sequencing (scRNA-seq) emerged to characterize gene expression differences between individual cells, allowing a higher resolution look at mRNA abundance than bulk RNA- seq. H...
Structural variation within plant genomes has fueled domestication and selection of traits critical for modern breeding of crop plants. Nevertheless, dissecting the diversity of structural v...
Learning Objectives: 1. Learn why the complexity and repetitive structure of the human genome makes it impossible to detect all structural variants using short-read sequencing 2. Learn how h...
Single-cell RNA sequencing has emerged as an important technology that can reveal gene expression differences between different cell types. This webinar will demonstrate how bioinformatics s...
CRISPR-Cas9 gene editing is a powerful technique that enables genetic modification with greater speed and accuracy than previous approaches. In this webinar, Dr. Chen highlights the advantag...
As the spread of infectious diseases, current pandemic, and growing antimicrobial resistance (AMR) continues globally, next-generation sequencing (NGS) and specifically metagenomics became a...
With the completion of the human genome nearly two decades ago, consumers, patients, and physicians are wondering when genetic testing will go PRIME TIME. While the diagnostic utility of gen...
In this presentation Dr. Kevin Halling describes the use of RNA-seq testing for identifying clinically significant gene fusions in tumors that can be used to help establish diagnosis and gui...
Complex genomes, including the human genome, contain ‘dark’ regions that standard short-read sequencing technologies do not adequately resolve—overlooking many variants tha...
Realizing the promise of Precision Medicine requires both a deep understanding of the landscape of genomic evidence and an understanding of the molecular drivers that influence all aspects o...
As genomics plays an ever expanding role in healthcare and research, educational programs focused on applied genomics have not kept pace with the demand for trained students. In this talk, w...
In recent years Nanotherapeutics has revolutionized the healthcare strategies and envisioned to have a tremendous impact to offer better health facilities. It involves design, fabrication, r...
Achieving a diagnosis in rare disease patients can be challenging for even the most experienced clinician or scientist, creating a barrier to delivering truly personalised care. An exome seq...
The introduction of improved, more cost efficient target capture technologies has accelerated the adoption of Whole Exome Sequencing (WES) in clinical diagnostics. The ability to provide mor...
Estrogen metabolism is the ability to favorably excrete potentially toxic estrogens through urine and sweat. Impaired estrogen metabolism is associated with Endometriosis and Polycystic Ovar...
Graphene-based Biology-gated Transistors (Cardean Transistors) directly read molecular signals of active biology using advanced electronics. This proprietary tech breakthrough can be used as...
Triple-negative breast cancer (TNBC) is an aggressive disease that accounts for 10-20% of all breast cancer cases diagnosed annually in the U.S.1. Despite its prevalence, TNBC remains resist...
Within the clinical arena, the oncology community has led the way in the early adoption of next generation sequencing. NGS is in widespread use in clinical cancer research and is now beginni...
Careful and deliberate packaging of the genome is essential to ensuring correct and timely transcriptional programs. Chromatin conformation capture (3C and Hi-C) is a powerful approach for c...
The introduction of PacBio HiFi sequence reads, which are both long (up to 25 kb currently) and accurate (>99%) at the individual single-molecule sequence read level, has allowed for adva...
Karyomapping, a technique for preimplantation genetic diagnosis (PGD) of single gene disorders, involves using very few or single cells, and comes with challenges due to limited amounts of s...
Modern biomedical research is being driven by large scale genetic and proteomic research to identify new targets for the study of disease mechanisms. While these techniques have been incredi...
The versatility of standard PCR and qPCR is well known. Digital PCR is now taking this to a whole new level. The power of partitioning enables you to explore new frontiers which have been li...
Long-read DNA sequencing technologies such as the Pacific Biosciences (PacBio) and Oxford Nanopore (ONT) platforms, have demonstrated enhanced detection of genomic variation, including Singl...
Single cell RNA sequencing (scRNA-seq) emerged to characterize gene expression differences between individual cells, allowing a higher resolution look at mRNA abundance than bulk RNA- seq. H...
Structural variation within plant genomes has fueled domestication and selection of traits critical for modern breeding of crop plants. Nevertheless, dissecting the diversity of structural v...
Learning Objectives: 1. Learn why the complexity and repetitive structure of the human genome makes it impossible to detect all structural variants using short-read sequencing 2. Learn how h...