text-only page produced automatically by LIFT Text Transcoder Skip all navigation and go to page contentSkip top navigation and go to directorate navigationSkip top navigation and go to page navigation
National Science Foundation
Discoveries
design element
Discoveries
Search Discoveries
About Discoveries
Discoveries by Research Area
Arctic & Antarctic
Astronomy & Space
Biology
Chemistry & Materials
Computing
Earth & Environment
Education
Engineering
Mathematics
Nanoscience
People & Society
Physics
 

Email this pagePrint this page

Discovery
Blueprint for the affordable genome

Stampede supercomputer powers innovations in DNA sequencing technologies

two stages in the temporal evolution of synthetic DNA nanostructures  imaged through Stampede

A sequence of simulations illustrates the temporal evolution of synthetic DNA nanostructures.
Credit and Larger Version

June 23, 2014

The following is part two in a series of stories that highlight recent discoveries enabled by the Stampede supercomputer. Read part one, three, four and five to find out how Stampede is making a difference through science and engineering.

Aleksei Aksimentiev, a professor of physics at the University of Illinois-Urbana Champaign, used the National Science Foundation-supported Stampede supercomputer to explore a cutting-edge method of DNA sequencing. The method uses an electric field to drive a strand of DNA through a small hole, or "nanopore," either in silicon or a biological membrane.

By controlling this process precisely and measuring the change in ionic current as the DNA strands move through the pore of the membrane, the sequencer can read each base pair in order.

"Stampede is by far the best computer system my group has used over the past 10 years," Aksimentiev said. "Being able to routinely obtain 40-80 nanoseconds of molecular dynamic simulations in 24 hours, regardless of the systems' size, has been essential for us to make progress with rapidly evolving projects."

Aksimentiev and his group showed that localized heating can be used to stretch DNA, which significantly increases the accuracy of nanopore DNA sequencing. In addition, he and his team used an all-atom molecular dynamics method to accurately describe DNA origami objects, making it possible to engineer materials for future applications in biosensing, drug delivery and nano-electronics. These results were published in ACS Nano and the Proceedings of the National Academy of Sciences.

--  Aaron Dubrow, NSF (703) 292-4489 adubrow@nsf.gov

Investigators
Aleksei Aksimentiev

Related Institutions/Organizations
University of Texas at Austin
University of Illinois at Urbana-Champaign

Locations
Champaign , Illinois

Related Programs
Extreme Science and Engineering Discovery Environment

Related Awards
#1134872 Enabling, Enhancing, and Extending Petascale Computing for Science and Engineering
#0955959 CAREER: Deciphering Ionic Current Signatures of Polymer Transport through a Nanopore

Years Research Conducted
2010 - 2014

Total Grants
$51,925,000

border=0/


Email this pagePrint this page
Back to Top of page