| |
|
| |
| Knowing what to look for in a college can be difficult. So is it really possible to wade through the ... - Lisa Koosis |
| |
| In April, ten large pharmaceutical companies and the U.K. Wellcome Trust philanthropy announced the ... - Aaron Hall |
| |
|
|
| The Human Genome Management Information System (HGMIS) was established in 1989 by the DOE Human Geno ... - Aaron Hall |
| |
|
Which college majors are hot--and which schools offer them? These are important questions that stude ... - Stacey Moore |
| |
|
Physics is a science topics that basically explains forces and motion, basically how the world works ... - Jakob Culver |
| |
|
This article offers readers important information on attending an online LPN school. - Sara Reed |
| |
|
| |
|
|
Spinoffs of Human Genome Project technologies continue to impact U.S. Industries, including medicine, environmental technology, agriculture, chemicals, and energy production. U.S. leadership in science and technology reaffirms the value of publicly funded research such as that supported at universities and national laboratories and in industry. Two recent spinoffs from the DOE Human Genome Program follow.
Biochip Agreement Aimed at Commercial Use
Companies to Refine Genome Technology for Mass Production
In June DOE announced that Argonne National Laboratory (ANL), Motorola Inc., and Packard Instrument Company have agreed to develop and mass-produce biochips. Motorola and Packard will contribute a total of $19 million over 5years, making this collaboration one of the largest biotechnology research agreements ever signed by a DOE national laboratory.
Like computer chips that execute millions of mathematical operations per second, biochips can quickly perform thousands of biological reactions. "This process, developed for DOE's Human Genome Program, provides miniaturized, faster, and more economical methods to analyze DNA samples," said former Secretary of Energy Federico Pe?a.
"By combining biochips with robots and computers, we can find one genetic variation among 3 billion DNA bases in a matter of minutes. Conventional methods take days," said Andrei Mirzabekov, a biologist who developed the biochips at ANL and at the Russian Engelhardt Institute of Molecular Biology. "In addition to being faster than conventional gene-sequencing methods, biochips provide a 3-D platform that allows greater sensitivity and accuracy in assaying proteins, RNA, and DNA," he noted.
Argonne's contribution, in conjunction with its Moscow research partner, consists of 19 inventions related to biological microchips that have been licensed exclusively to Motorola and Packard. These inventions are the result of more than $10million in research support since 1994 by DOE, Defense Advanced Research Projects Agency, Russian Academy of Sciences, and Russian Human Genome Program. Motorola will develop manufacturing processes to mass-produce biochips, and Packard will develop and manufacture analytical instruments to process and analyze them.
Biochips have immediate practical applications for analyzing polymorphisms, studying gene expression, and monitoring clinical trials. Richard McKernan, president of Packard, noted that within the next few years commercial biochips should bring "better, more rapidly developed pharmaceuticals; faster and more accurate medical diagnostics; a heightened ability to assess and possibly repair environmental damage; and better, more hardy, and healthier crops." The transition of biochips into the clinical diagnostics market is expected in 4 to 5 years.
Sheath-Flow Fluorescence Detection for DNA Capillary Electrophoresis
In sheath-flow systems, analytes exiting a capillary are transported in a flow of buffer and moved across interrogating laser beams. Higher sensitivity is achieved by avoiding a major source of background noise caused by direct laser action on capillaries in which DNA fragments have been separated.
Norman Dovichi [University of Edmonton, Alberta (UEA)] contributed to the development of detection systems for flow cytometry while at Los Alamos National Laboratory. Subsequently at UEA his team pioneered sheath-flow fluorescence readout technology for DNA capillary electrophoresis. In 1996 Dovichi received the American Chemical Society Award in Chemical Instrumentation for research in this project, which had some early support from DOE and major funding from Canadian sources. |
| Author: Aaron Hall |
| |
Author Bio:
|
|
 |
|
| |
Related Articles |
| |
Web Site Provides HGP Access to Scientific and Public Audiences
|
| |
Drosophila Sequencing Nears Completion
|
| |
Online Bachelors Degrees
|
| |
Early History of Small Genome Sequencing
|
| |
DiGeorge Syndrome Region Cloned
|
| |
Air Bag Suspension Technology Replace Mechanical Leaf Springs
|
| |
Formation of Volcano
|
| |
Ways to Pay for Your College Education
|
| |
SBIR 1999 Human Genome Awards Announced
|
| |
Sinus Headache ?C A Common Sign of Chronic Sinusitis
|
| |
|
|
|
|
Home Page
