Nerve gas litmus test could sense airborne chemical weapons
13 Mar 2012
Nerve gases are colourless, odourless, tasteless and deadly. While today's soldiers carry masks and other protective gear, they don't have reliable ways of knowing when they need them in time. That could change, thanks to a new litmus-like paper sensor made at the University of Michigan.
The paper strips are designed to change colour from blue to pink within 30 second of exposure to trace amounts of nerve gas.
"To detect these agents now, we rely on huge, expensive machines that are hard to carry and hard to operate," said Jinsang Kim, an associate professor in the departments of materials science and engineering, chemical engineering and biomedical engineering in addition to the program in macromolecular science and engineering.
"We wanted to develop an equipment-free, motion-free, highly sensitive technology that uses just our bare eyes."
A paper on their sensor is published online in Advanced Functional Materials. It will appear in a forthcoming print edition.
The new sensors combine a group of atoms from a nerve gas antidote with a molecule that changes colour when it's under mechanical stress. The antidote's functional group binds to the nerve gas, and the resulting stress triggers the colour-changing molecule to turn from blue to pink.
In their experiment, the researchers used a less toxic "nerve agent simulant" related to Sarin gas. Their sensors were able to detect its presence at a concentration of 160 parts per billion, which is five times less than the amount that would kill a monkey.
"We believe these paper strips would detect real and potent nerve gases faster and in even lower concentrations considering their high vapor pressure and more volatile properties," Kim said.
"It feels so gratifying when we, as scientists and engineers, can provide solutions to our society through research."
The university is pursuing patent protection for the intellectual property, and is seeking commercialization partners to help bring the technology to market.
The paper, Colorimetric Detection of Warfare Gases by Polydiacetylenes Toward Equipment-Free Detection, on the research is funded by the National Science Foundation and the National Research Foundation of Korea.
The paper strips are designed to change colour from blue to pink within 30 second of exposure to trace amounts of nerve gas.
"To detect these agents now, we rely on huge, expensive machines that are hard to carry and hard to operate," said Jinsang Kim, an associate professor in the departments of materials science and engineering, chemical engineering and biomedical engineering in addition to the program in macromolecular science and engineering.
"We wanted to develop an equipment-free, motion-free, highly sensitive technology that uses just our bare eyes."
A paper on their sensor is published online in Advanced Functional Materials. It will appear in a forthcoming print edition.
The new sensors combine a group of atoms from a nerve gas antidote with a molecule that changes colour when it's under mechanical stress. The antidote's functional group binds to the nerve gas, and the resulting stress triggers the colour-changing molecule to turn from blue to pink.
In their experiment, the researchers used a less toxic "nerve agent simulant" related to Sarin gas. Their sensors were able to detect its presence at a concentration of 160 parts per billion, which is five times less than the amount that would kill a monkey.
"We believe these paper strips would detect real and potent nerve gases faster and in even lower concentrations considering their high vapor pressure and more volatile properties," Kim said.
"It feels so gratifying when we, as scientists and engineers, can provide solutions to our society through research."
The university is pursuing patent protection for the intellectual property, and is seeking commercialization partners to help bring the technology to market.
The paper, Colorimetric Detection of Warfare Gases by Polydiacetylenes Toward Equipment-Free Detection, on the research is funded by the National Science Foundation and the National Research Foundation of Korea.