Researchers have developed a nanoscale machine made of DNA that can randomly move in any direction across bumpy surfaces. The “walker” could potentially roam the human body in search of cancerous cells and tag them for medical imaging or drug targeting.
Previously, nanoparticle walkers were only able to walk on precise and programmed one- and two-dimensional paths. This walker was able to move 36 steps, and its movement in a random fashion is different from movement seen in other studies.
“This is an important step forward in developing nanoscale nucleic acid machines that can autonomously act under a variety of conditions, including in the body,” says Andrew Ellington, professor of molecular biosciences at the University of Texas at Austin.
“DNA nanotechnology is especially interesting because it explores the world of ‘matter computers,’ where computations (including walking) are carried out by physical objects, rather than by electronic or magnetic shuttles. DNA walkers may eventually allow protective cells to walk the surface of organs, constantly computing whether a cancer is present.”
More immediate practical applications may include deploying the DNA walker in the body so that it can amplify signals from cancer cells to make them more easily identified and targeted by doctors. There also may be implications for future delivery of nanoscale therapeutics.
Although it may be a long march from diagnosing cancer to curing it,
“All breakthroughs begin with baby steps. Only in this case, they are the steps of a DNA walker,” says coauthor Cheulhee Jung.
The walker is made from a single piece of DNA with two legs connected by a torso. Like a human, it moves by putting one leg forward, then lifting the other leg and putting it forward. The walker autonomously and randomly decides where to put its leg on each step.
The study demonstrated that as the nanoscale machine walked, it did not go over the same area twice.
C. Jung, P. B. Allen & A. D. Ellington
A stochastic DNA walker that traverses a microparticle surface
Nature Nanotechnology (2015) doi:10.1038/nnano.2015.246
Image: Delft University of Technology
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