Battling against biological threats with ultrasonics
A tweezers-like device uses ultrasonics to detect bioterror agents; when a small sample such as a powdery anthrax mix is placed inside the device, an array of piezoelectric transducers would generate an ultrasonic force field onto the sample; security officials would be able to detect anthrax from innocuous powders in the mix through differences in compressibility and density
Homeland security officials and first responders may be able quickly to separate and detect deadly biological weapons such as anthrax from samples using a microscopic tweezers-like device that relies on the power of ultrasound.
Siobhan Wagner writes that the sonotweezers are being developed by a collaborative research team comprising partners from Bristol, Dundee, Southampton, and Glasgow universities. The team believes that its technology could have a variety of applications beyond homeland security and foresee it being used in everything from tissue engineering to stem-cell research.
In 2009 the group received a four-year, £4 million grant from the U.K. Engineering and Physical Sciences Research Council (EPSRC) to complete its research by 2013.
Team leader Bruce Drinkwater, professor of ultrasonics in the Department of Mechanical Engineering at Bristol, said their sonotweezers would be based on a silicon chip. Integrated within a cavity of this chip would be an array of piezoelectric transducers. Drinkwater added that electronics would also be integrated on the chip to excite the transducers with varying voltage levels, phase and pulse shape.
When a small sample such as a powdery anthrax mix is placed inside the chip cavity, the transducers would generate an ultrasonic force field onto the sample. Drinkwater explained that security officials would be able to detect anthrax from innocuous powders in the mix through differences in compressibility and density. “The different compressibility of powder relative to the cell means the force is different so you are able to differentiate them,” he said.
The ability to differentiate cells by ultrasonic force has potential applications in stem-cell research. Drinkwater added that stem-cell researchers currently need an effective method to separate and classify stem cells that will go on to form different parts of the body such as skin or lungs.
“There is a big demand to be able to separate those at the earliest stage possible,” he said. “At the moment we don’t know if the ultrasonic force on different types of cells will be different but if it is, we can separate them and that would be a hugely important application because at the moment it is almost impossible to distinguish different types of stem cells.”
With tissue engineering, the ultrasonic forces exerted by the transducers would be used to move groups of cells — ranging from micron to millimeter size — to build up artificial tissue. These tissues could be used for testing the effects of new drugs.
