SEPARATING THE HYPE AND THE BUZZ - Tuesday, September 15, 2009

BREAKTHROUGHS

Three-Dimensional DNA crystalline structures
Recently released in Nature, scientists from New York University have created the first three-dimensional DNA crystalline structures. Prior to this breakthrough, DNA crystalline structures were confined to two dimensions— having axes on one plane. These three-dimensional DNA crystals have potential ramifications for medical drug delivery and nanoelectronics.
See Nanovip.

World's fastest nitride-based transistors
Researchers from ETH Zurich have improved the switching speed of nitride-based transistors. The transistors function at a high level of heat and produce high voltages, up to 108GHz. These transistors may have a large impact on future electronics.
See Nanowerk.

NEWSWORTHY

Nanomedicine gets a boost from nanodiamonds
Researchers at Northwestern University are pioneering the use of nanodiamonds for targeted drug delivery. Using the nanodiamonds in coordination with PEI800 (polyethyleneimine-800) the research team reports a 70 times greater drug delivery efficiency than over PEI800 alone.
See Nanowerk.

Tree power
Forthcoming in Transactions on Nanotechnology, researchers at the University of Washington have successfully powered nano-sized circuits (roughly 130 nanometers) from nothing more than the voltage created by a tree. While there is little thought of using tree power as a resource, there is some interest in creating sensors to monitor forest fires.
See Nanowerk and Nanotech Wire.

Bacteria detection using CNTs
Researchers at the Rovira I Virgili University in Tarragona, Spain, are pioneering methods for bacteria detection using single-walled carbon nanotubes and synthetic DNA. When coming into contact with Salmonella typhi (the cause of typhoid fever), the DNA and CNT release an electric signal that can be instantaneously picked up by a biosensor. This process may help to greatly improve the identification and measurement of harmful microorganisms.
See Nanowerk.

Delivery of drugs into cancer cells
Researchers at UC Santa Barbara have developed a unique and efficient method to deliver drugs to cancer cells. They used cancer cells from mice and introduced gold nanoshells with a peptide lipid coating that encapsulated the drug. Then they introduced a non-harmful infrared laser onto the cells. See A to Z Nano.

Nanoparticles to treat brain cancer cells
Scientists in Illinois are making progress towards achieving nanoparticles that will “seek and destroy” the brain cancer cells, without damaging the nearby healthy cells. The solution involves chemically linked titanium dioxide nanoparticles to the antibody that seeks and attaches to these cells. When cancerous cells were exposed to “nano biohybrids,”80 percent of these cells were killed by nanoparticles.
See A to Z Nano.


HONORABLE MENTIONS

Research on x-ray nano CT-scan
Ge Wang and his colleagues have been working on developing an X-ray nano CT-scan, which promises to reduce the radiation dose currently existing. This nano CT-scan will be able to provide images at the subcellular level revealing deeply imbedded details.
See Nanowerk.

Green algae nanostructure for an environmentally friendly battery
Researchers at Uppsala University have discovered that the distinctive cellulose in green algae, having a unique nanostructure can serve as an effective coating substrate in environmentally friendly batteries. This creates possible productions of environmentally friendly, cost-effective, lightweight energy storage systems.
See Nanowerk and A to Z Nano.

Nanoelectronics and biology combine to make better electronics
Lawrence Livermore National Laboratory researchers have combined biological components with electronic circuits. This could enhance biosensing and diagnostic tools, advance neural prosthetics, and might even increase the efficiency of future computers. The devise uses lipid coated nanowires to build prototype bionanoelectronic devices.
See Nanotech Wire.

Graphite's potential as mass data storage medium is getting closer to reality
Researchers at Rice University have brought graphite’s potential as a mass storage devise closer to reality, creating a potential for reprogrammable gate arrays that could revolutionize integrated circuit design. Standard lithographic methods have been used to deposit 10 nm stripes of amorphous graphite onto silicon. This can help develop dense and stable non-volatile memories for all kinds of digital devices. See A to Z Nano.