Volatile chemical signals are used by many animals to find food, mates, or hosts. While the keen sense of smell
of dogs has been used for centuries, other animals have not been significantly utilized. Recent studies have indicated that many
insect species have the ability to learn volatile chemical compounds in association with food or other resources. These insects
present a novel approach to volatile chemical detection that could provide a highly sensitive, inexpensive, flexible, and portable
sensor. One characteristic of insects that makes them desirable as a potential chemical detector is their ability to detect
extremely low levels of chemical compounds. A parasitoid wasp, Microplitis croceipes, was used as the model insect for
determining the threshold of response for four compounds: 3-octanone, a compound found in many fungal pathogens;
myrcene, a volatile constituent released by cotton plants fed on by cotton bollworms; and putriscene and cadaverine, two
products of the breakdown of dead animal protein by microorganisms. Eighteen wasps were trained to each of these individual
compounds at one dosage and tested at decreasing dosage levels until their responses were negligible. Each dosage was tested
with 18 freshly trained wasps. The wasp response to the odor was determined by a searching behavior called antennating.
Wasp response was measured by the length of time the wasp antennated when exposed to the odor. The mean wasp response
fell below 10 s at approximately 3.1 × 10-7, 2.9 × 10-7, 3.9 × 10-6, and 4.5 × 10-7 mol L-1 of compound for 3-octanone,
myrcene, cadaverine, and putriscene, respectively. For comparative purposes, the detection limits of an electronic nose, the
Cyranose 320, was determined for two of the four compounds. The response limits of the wasp for the compounds 3-octanone
and myrcene were 74 and 94 times better than the electronic nose, respectively. The response limit of the wasps to putriscene,
3-octanone, and myrcene was approximately 10 times better than to cadaverine.
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