 | Researchers to develop active nanoscale surfaces for biological separations |
The researchers are taking their inspiration from nature, mimicking the very membranes that surround our cells to create platforms for separating biological molecules. These "lipid bilayers," which are made up of two opposing layers of fat molecules, act as the cell's barrier to the outside world. DNA molecules move on these surfaces in two dimensions, much like objects on a conveyor belt. Kane and his colleagues recently discovered that the mobility of DNA molecules is closely coupled to the movement of the underlying lipid bilayer.
"The advantage of these surfaces is that they can be actively modified," Kane said. "Thus by changing the temperature, shining light, or applying an electric field, we propose to change the behavior of the surfaces." In one approach, Kane and his colleagues are building a molecular obstacle course made up of nanoscale domains. When an electric field is applied at one end, DNA molecules will move across the surface and collide with the obstacles, impeding their motion. The researchers have already made surfaces on which they can control the size and positioning of obstacles; next, they plan to test the movement of DNA.
The overarching goal is to understand how biological molecules of all types move across the surface of lipid bilayers. "This particular project is focused on DNA, but the approach could potentially be used for separating other biological molecules, such as proteins," Kane said. He envisions immediate applications in genomics and proteomics, with the new approach providing several improvements over current techniques.
The new surfaces could yield separations with higher resolution and greater efficiency, Kane suggested. And they can be easily fabricated in a normal laboratory, whereas other surfaces require the use of a clean room. The nanoscale surfaces are also dynamic, while the materials in use today cannot be altered once they have been made.
In the more distant future, the surfaces could even be used as biosensors or to deliver DNA molecules for gene therapy applications, Kane said. ###
The funding is part of a National Science Foundation program to develop Nanoscale Interdisciplinary Research Teams (NIRT) to catalyze synergistic research and education in emerging areas of nanoscale science and technology.
Other researchers involved with the project include Professor Steve Granick at the University of Illinois at Urbana-Champaign, Professor Sanat Kumar at Columbia University, Professor Omkaram Nalamasu at Rensselaer, and Chakradhar Padala, a doctoral student in chemical and biological engineering at Rensselaer.
About Rensselaer, Rensselaer Polytechnic Institute, founded in 1824, is the nation's oldest technological university. The university offers bachelor's, master's, and doctoral degrees in engineering, the sciences, information technology, architecture, management, and the humanities and social sciences. Institute programs serve undergraduates, graduate students, and working professionals around the world.
Rensselaer faculty are known for pre-eminence in research conducted in a wide range of fields, with particular emphasis in biotechnology, nanotechnology, information technology, and the media arts and technology. The Institute is well known for its success in the transfer of technology from the laboratory to the marketplace so that new discoveries and inventions benefit human life, protect the environment, and strengthen economic development.
Contact: Jason Gorss gorssj@rpi.edu 518-276-6098 Rensselaer Polytechnic Institute
Technorati Tags: nanofibers or Nanoscientists and Nano or Nanotechnology and nanoparticles or Nanotech and nanotubes or nanochemistry and nanoscale or nanowires and Nanocantilevers or nanometrology and quantum mechanics or biological separations and biological molecules or lipid bilayers
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