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tag quantitative pcr disease medicine developmental biology ecology

Innovations Expand Lab Power, Uses Of PCR Technique
Ricki Lewis | Jul 25, 1993 | 8 min read
The gene amplification technique invented by genetics researcher Kary Mullis on a moonlit drive through the northern California hills a decade ago--the polymerase chain reaction (PCR)-- continues to revolutionize the life sciences. Uses in molecular biology research and in diagnostic tests are proliferating, and PCR is even bringing a new molecular approach to such fields as paleontology and epidemiology. The following companies are among those supplying PCR-related products for the resear
PCR Primed To Spur Chain Of Applications
Holly Ahern | Jun 25, 1995 | 10+ min read
What would you do if your research interests revolved around obtaining DNA from a bacterium preserved for millions of years in the gut of a bee stuck in amber, matching up a murderer to crime- scene blood half a century old, or cloning genes from a 1,000- year-old mummy? Most scientists would first consider PCR--the polymerase chain reaction--as a technique for approaching problems such as these. With PCR, minute quantities of nucleic acids can be amplified millions of times into sufficient qua
Going Their Separate Ways: A Profile of Products for Cell Separation
Michelle Vettese-dadey | Sep 12, 1999 | 10+ min read
Date: September 13, 1999Cell Separation Products Magnetic Cell Separation Technologies that isolate rare cell types to high purity are essential to the cell biology researcher. Understanding cell developmental pathways becomes increasingly significant as diagnosis and treatment of disease turns more to the molecular level.1 This diagnosis of cell-related diseases requires methods for detection, isolation, and analysis of individual cells regardless of their frequency.2 The hematopoietic system
2020 Top 10 Innovations
The Scientist | Dec 1, 2020 | 10+ min read
From a rapid molecular test for COVID-19 to tools that can characterize the antibodies produced in the plasma of patients recovering from the disease, this year’s winners reflect the research community’s shared focus in a challenging year.
Top 10 Innovations 2021
2021 Top 10 Innovations
The Scientist | Dec 1, 2021 | 10+ min read
The COVID-19 pandemic is still with us. Biomedical innovation has rallied to address that pressing concern while continuing to tackle broader research challenges.
An illustration of green bacteria floating above neutral-colored intestinal villi
The Inside Guide: The Gut Microbiome’s Role in Host Evolution
Catherine Offord | Jul 1, 2021 | 10+ min read
Bacteria that live in the digestive tracts of animals may influence the adaptive trajectories of their hosts.
CRISPR Can Track Cellular History of a Mammalian Embryo
Sukanya Charuchandra | Aug 10, 2018 | 2 min read
Researchers used the genome-editing technology to analyze the development of mouse tissues.
Surpassing the Law of Averages
Jeffrey M. Perkel | Sep 1, 2009 | 7 min read
By Jeffrey M. Perkel Surpassing the Law of Averages How to expose the behaviors of genes, RNA, proteins, and metabolites in single cells. By necessity or convenience, almost everything we know about biochemistry and molecular biology derives from bulk behavior: From gene regulation to Michaelis-Menten kinetics, we understand biology in terms of what the “average” cell in a population does. But, as Jonathan Weissman of the University of Califo
The Rodent Wars: Is a Rat Just a Big Mouse?
Ricki Lewis | Jul 4, 1999 | 5 min read
Sometimes it seems as if genome projects are cropping up everywhere.1 But until costs come down, limited resources are being largely concentrated into what Joseph Nadeau, professor of genetics at Case Western Reserve University School of Medicine, calls "the genome seven," an apples-and-oranges list of viruses, bacteria, fungi, Arabidopsis thaliana, Drosophila melanogaster, Caenorhabditis elegans, and mouse, with Homo sapiens in its own category.2 Researchers widely acknowledge that in the rod
Roll-Your-Own Microarrays
Jim Kling | Jan 6, 2002 | 3 min read
CDNA microarrays hold great promise for characterizing disease and performing genetic studies, but they're not exactly an out-of-the-box technology just yet. Often the scientists must prepare their own chips. Yet, this process is limited by the amount of space on the array itself—forcing researchers to make choices about which genes to include in their sample. Clinical microarray applications are further limited by the availability of sufficient cell numbers for testing purposes. Illumina

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