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Quantitative analysis of the effects of ultrasound from an odor sprayer on moth flight behavior

Skals, Niels LU ; Plepys, Dainius LU ; El-Sayed, A M ; Löfstedt, Christer LU and Surlykke, Ann (2003) In Journal of Chemical Ecology 29(1). p.71-82
Abstract
A piezoelectric sprayer was recently developed for precision release of odor stimuli in olfactory research. The device replaces conventional dispensers used to release semiochemicals in studies of moth flight toward odor sources. However, the device generates high-frequency sounds in the range that some moths can hear. Ultrasound from the standard set-up sprayer had a considerable impact on flight behavior of the silver Y moth, Autographa gamma, tested in a flight tunnel. It was affected at all behavioral stages when the dispenser was driven at 120 kHz. Only 5% of the moths reached the source when exposed to 120-kHz sound from the dispenser compared to 65% in the control group without sound. The proportion taking flight was also reduced.... (More)
A piezoelectric sprayer was recently developed for precision release of odor stimuli in olfactory research. The device replaces conventional dispensers used to release semiochemicals in studies of moth flight toward odor sources. However, the device generates high-frequency sounds in the range that some moths can hear. Ultrasound from the standard set-up sprayer had a considerable impact on flight behavior of the silver Y moth, Autographa gamma, tested in a flight tunnel. It was affected at all behavioral stages when the dispenser was driven at 120 kHz. Only 5% of the moths reached the source when exposed to 120-kHz sound from the dispenser compared to 65% in the control group without sound. The proportion taking flight was also reduced. Hearing threshold curves obtained electrophysiologically revealed that moths were sensitive to the frequency range at which the sprayer was operated and that sound intensity from the sprayer was up to 40 dB above the moths' electrophysiological hearing threshold. The audiogram for A. gamma was similar to audiograms obtained for other noctuids. Hearing sensitivity was highest at around 15 kHz, where the threshold was 35 dB SPL (sound pressure level). The threshold increased with frequency up to 94 dB SPL at 160 kHz. We improved the sprayer to operate at 300 kHz, which is beyond the hearing ability of most insects with ears. At this high frequency, the moths' sensitivity to ultrasound is reduced considerably, and we did not observe any effect on flight behavior compared to a control group without sound. Accordingly, this new piezoelectric sprayer can be used with ultrasound-sensitive insects and insensitive insects alike. (Less)
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author
; ; ; and
organization
publishing date
type
Contribution to journal
publication status
published
subject
in
Journal of Chemical Ecology
volume
29
issue
1
pages
71 - 82
publisher
Springer
external identifiers
  • wos:000180392100006
  • pmid:12647854
  • scopus:0037267588
ISSN
1573-1561
DOI
10.1023/A:1021924529533
language
English
LU publication?
yes
id
b011add9-3ce0-4552-92cf-8fc0ae71ec00 (old id 153028)
date added to LUP
2016-04-01 12:11:22
date last changed
2022-01-27 00:04:14
@article{b011add9-3ce0-4552-92cf-8fc0ae71ec00,
  abstract     = {{A piezoelectric sprayer was recently developed for precision release of odor stimuli in olfactory research. The device replaces conventional dispensers used to release semiochemicals in studies of moth flight toward odor sources. However, the device generates high-frequency sounds in the range that some moths can hear. Ultrasound from the standard set-up sprayer had a considerable impact on flight behavior of the silver Y moth, Autographa gamma, tested in a flight tunnel. It was affected at all behavioral stages when the dispenser was driven at 120 kHz. Only 5% of the moths reached the source when exposed to 120-kHz sound from the dispenser compared to 65% in the control group without sound. The proportion taking flight was also reduced. Hearing threshold curves obtained electrophysiologically revealed that moths were sensitive to the frequency range at which the sprayer was operated and that sound intensity from the sprayer was up to 40 dB above the moths' electrophysiological hearing threshold. The audiogram for A. gamma was similar to audiograms obtained for other noctuids. Hearing sensitivity was highest at around 15 kHz, where the threshold was 35 dB SPL (sound pressure level). The threshold increased with frequency up to 94 dB SPL at 160 kHz. We improved the sprayer to operate at 300 kHz, which is beyond the hearing ability of most insects with ears. At this high frequency, the moths' sensitivity to ultrasound is reduced considerably, and we did not observe any effect on flight behavior compared to a control group without sound. Accordingly, this new piezoelectric sprayer can be used with ultrasound-sensitive insects and insensitive insects alike.}},
  author       = {{Skals, Niels and Plepys, Dainius and El-Sayed, A M and Löfstedt, Christer and Surlykke, Ann}},
  issn         = {{1573-1561}},
  language     = {{eng}},
  number       = {{1}},
  pages        = {{71--82}},
  publisher    = {{Springer}},
  series       = {{Journal of Chemical Ecology}},
  title        = {{Quantitative analysis of the effects of ultrasound from an odor sprayer on moth flight behavior}},
  url          = {{http://dx.doi.org/10.1023/A:1021924529533}},
  doi          = {{10.1023/A:1021924529533}},
  volume       = {{29}},
  year         = {{2003}},
}