We've reported on the use of nanotechnology to develop better composites, fault-detecting paint, and energy-harvesting wearable fabric. It's also a methodology for developing devices that assemble themselves. Though many of those efforts have used carbon nanotubes, Harvard University's Wyss Institute for Biologically Inspired Engineering has harnessed DNA to create self-assembling nanodevices.
The emerging field of DNA nanotechnology is being explored for building tiny, programmable structures for diverse applications. So far, most research has focused on what's called DNA origami. This method uses a long biological strand of DNA as a backbone. Smaller strands are bound to its segments to create different shapes.
Single-stranded tiles (SSTs) made of short strands of interlocking DNA can be programmed to assemble themselves into precisely designed shapes, including letters, numbers, and emoticons. (Source: Wyss Institute at Harvard University)
Researchers at the Wyss Institute took a different approach. A team led by Peng Yin, a Wyss core faculty member and assistant professor of systems biology at Harvard Medical School, used short synthetic strands of DNA to build complex nanostructures. These interlocking building blocks, called single-stranded tiles (SSTs), can be programmed to assemble themselves into precisely designed shapes.
Each SST consists of a unique 42-base DNA strand that folds into a 3nm x 7nm tile and binds to four local neighbors during self-assembly if they have complementary DNA sequences. Through a series of these interlocking connections, a group of SSTs can assemble themselves into different shapes. (You can watch a slideshow presentation with audio narration here.)
The researchers created more than 100 different designs (including numbers, letters, and Chinese characters) out of these tiles to demonstrate the DNA assembly method. For a single structure 100nm long, they used hundreds of tiles.
As synthetically based materials, the SSTs could have some important applications in medicine. They could organize themselves into drug delivery machines that maintain their structural integrity until they reach specific cell targets. Because they are synthetic, they can be tailored to be highly biocompatible.
The researchers, including Wyss postdoctoral fellow Bryan Wei and graduate student Mingjie Dai, say the approach is simple, versatile, and robust. They envision it as being developed for nanoscale devices for highly targeted drug delivery, among other applications.
The National Science Foundation, the National Institutes of Health, the Office of Naval Research, and the Wyss Institute supported this research.
This is fascinating new technology, Ann. I would imagine one of the applications could be targeting chemotherapy to the cancer instead of having to broadcast it to healthy cells as well as cancerous cells.
Isn't this amazing? Targeted drug delivery is definitely one of the possible apps the researchers have in mind, and if that could be done for chemotherapy it would make a lot of people healthier and happier.
Just like Jurassic Park introduced the public to genomic technology, PREY explores the development of nanobots and genetic assembly. Let's hope that reality has a happier ending...
If you are interested, I wrote about this topic in April 2004. It looks like we are almost there.
Thanks williamlweaver, glad you liked the article. Self-assembled devices is becoming quite an an active area of research. I have read Crichton's PREY: pretty scary stuff, in fact I found it his scariest so far because it's so believable, perhaps even inevitable. Thanks for the link to your swarms article--another area of research that's getting a lot of play, especially in robotics.
New versions of BASF's Ecovio line are both compostable and designed for either injection molding or thermoforming. These combinations are becoming more common for the single-use bioplastics used in food service and food packaging applications, but are still not widely available.
The 100-percent solar-powered Solar Impulse plane flies on a piloted, cross-country flight this summer over the US as a prelude to the longer, round-the-world flight by its successor aircraft planned for 2015.
GE Aviation expects to chop off about 25 percent of the total 3D printing time of metallic production components for its LEAP Turbofan engine, using in-process inspection. That's pretty amazing, considering how slow additive manufacturing (AM) build times usually are.
A $1,500, hand-operated, bench-model, plastic injection machine crowdsource-funded via Kickstarter can be used to mold small, quality, plastic parts inexpensively, on demand.
The federal government is launching competitions to kickstart three more manufacturing innovation institutes, including one focused on Lightweight and Modern Metals Manufacturing Innovation.
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