Liquid Crystal Sensor plays nature's game.Thanks to billions of years of evolution, cells are remarkably adept at detecting pathogens or toxic chemicals in the environment. Taking advantage of this natural surveillance capability, researchers have incorporated components of cell membranes into sensors to sniff out dangerous chemical and biological agents. Led by chemical engineer Nicholas L. Abbott at the University of Wisconsin-Madison “University of Wisconsin” redirects here. For other uses, see University of Wisconsin (disambiguation). A public, land-grant institution, UW-Madison offers a wide spectrum of liberal arts studies, professional programs, and student activities. , the researchers placed a layer of phospholipids--the fatty acids constituting cell membranes--on top of a liquid crystal. "These are the same liquid crystals you find in laptop-computer displays," says Abbott. In the new sensing scheme, the lipids attach themselves to the rod-shaped liquid crystal molecules, which lie perpendicular to the surface and appear dark. When the researchers expose the sensor to an aqueous stream containing a protein that binds to lipids, the liquid crystal molecules respond within seconds by switching to a planar A technique developed by Fairchild Instruments that creates transistor sublayers by forcing chemicals under pressure into exposed areas. Planar superseded the mesa process and was a major step toward creating the chip. orientation. Viewed under a microscope, the crystals then transmit polarized A one-way direction of a signal or the molecules within a material pointing in one direction. light and appear bright. "This is a beautiful example of how one can use novel materials to create a signal," says Chad Mirkin, a chemist at Northwestern University Northwestern University, mainly at Evanston, Ill.; coeducational; chartered 1851, opened 1855 by Methodists. In 1873 it absorbed Evanston College for Ladies. in Evanston, Ill. By adding different receptors to the lipids, researchers can tune the sensor to detect specific molecules. For instance, when Abbott and his colleagues attached a receptor called biotin biotin: see vitamin; coenzyme. biotin Organic compound, part of the vitamin B complex, essential for growth and well-being in animals and some microorganisms. to the lipids, the sensor detected a bacterial protein Bacterial protein a protein formed by bacterial activity.[1]. Examples
[2] that binds to biotin. The researchers describe their results in the Dee. 19 Science. Abbott's team has made sensors out of liquid crystals before (SN: 8/18/01, p. 103), but those sensors didn't include membrane components. When attached to fluid lipid molecules, receptors can move about freely instead of being fixed in one place. "That becomes important for binding things like viruses," which attach to several receptors at once on cell surfaces, says Abbott. Mobile receptors in the artificial sensors can reorganize to bind specific targets just as receptors in a cell do. Because the sensors don't require electric power, Abbott envisions deploying networks of coin-size devices for long-term monitoring in the field. Researchers could shine a laser on the sensors to determine the orientation of the liquid crystals. Says Abbott: "You could interrogate (1) To search, sum or count records in a file. See query. (2) To test the condition or status of a terminal or computer system. the sensors from 1,000 feet away on the ground or from a helicopter." Although the sensitivity of the new sensor is not yet as high as that of others in development, the device is part of a new generation of inexpensive, sophisticated sensors, says Mirkin. Existing sensors are not sufficient in this new era of homeland security Noun 1. Homeland Security - the federal department that administers all matters relating to homeland security Department of Homeland Security executive department - a federal department in the executive branch of the government of the United States , he adds. The Wisconsin group is currently increasing the sensitivity of its device and focusing on detecting dangerous molecules, such as cholera toxins and chemical and biowarfare agents. |
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