Third-generation (gen-3), single-molecule sequencing technology is not only about making quantifiable enhancements to second-generation (gen-2) capabilities, but also about improving data quality ...

Third Generation Sequencing, also known as long-read sequencing, represents a breakthrough in the realm of genomics. Unlike the previous methods which required DNA fragmentation, TGS reads long ...

The majority of patients with the most common advanced or metastatic cancers in the United States do not undergo ...

Lycium barbarum, commonly known as goji berry, is renowned for its pectin polysaccharides (LBPPs), which offer a range of ...

While third generation sequencing comes with many notable advantages, it also faces several prominent disadvantages. Among these is the relatively low accuracy: despite improvements driven by ...

From bulk and single cell methods to spatial and multiomic methods, advancements in sequencing and -omics research are accelerating at an exciting pace. Next-generation sequencing (NGS) provides ...

Can you share specific examples where next-generation protein sequencing has significantly advanced proteomics research and improved our understanding of complex biological processes?

Next-generation sequencing (NGS) technologies revolutionize genomic and clinical research with rapid, high-throughput DNA and RNA sequencing, enabling groundbreaking discoveries and personalized ...

Third-generation sequencing technologies, such as those developed by Oxford Nanopore Technologies and Pacific Biosciences, allow for the sequencing of long, continuous DNA fragments in real-time.

Patients with cancer are increasingly having tumor DNA sequenced to identify disease markers and potential targets, but some investigators question whether every cancer patient can benefit.