DNA Nanotechnology Applications in Medicine
Author: McGill University
Published: 17 Mar 2010
Contents: Synopsis - Introduction - Main - Related Publications
Synopsis: Development of nanotubes that could one day deliver drugs to specific diseased cancer cells.
Introduction
DNA nanotechnology breakthrough offers promising applications in medicine - McGill researchers create DNA nanotubes able to carry and selectively release materials.Main Content
A team of McGill Chemistry Department researchers led by Dr. Hanadi Sleiman has achieved a major breakthrough in the development of nanotubes - tiny "magic bullets" that could one day deliver drugs to specific diseased cells. Sleiman explains that the research involves taking DNA out of its biological context. So rather than being used as the genetic code for life, it becomes a kind of building block for tiny nanometer-scale objects.
Using this method, the team created the first examples of DNA nanotubes that encapsulate and load cargo, and then release it rapidly and completely when a specific external DNA strand is added. One of these DNA structures is only a few nanometers wide but can be extremely long, about 20,000 nanometers. (A nanometer is one-10,000th the diameter of a human hair.)
Until now, DNA nanotubes could only be constructed by rolling a two-dimensional sheet of DNA into a cylinder. Sleiman's method allows nanotubes of any shape to be formed and they can either be closed to hold materials or porous to release them. Materials such as drugs could then be released when a particular molecule is present.
One of the possible future applications for this discovery is cancer treatment. However, Sleiman cautions, "we are still far from being able to treat diseases using this technology; this is only a step in that direction. Researchers need to learn how to take these DNA nano-structures, such as the nanotubes here, and bring them back to biology to solve problems in nanomedicine, from drug delivery, to tissue engineering to sensors," she said.
The team's discovery was published on March 14, 2010 in Nature Chemistry. The research was made possible with funding from the National Science and Engineering Research Council and the Canadian Institute for Advanced Research.