Add to ORKGIn response to ultrasonic stimuli, tethered flying crickets perform evasive steering movements that are directed away from the sound source (negative phonotaxis). In this study we haVe investigated the responsiveness to ultrasound of neurons that descend from the cricket brain, and whether flight activity facilitates the responsiveness of these neurons. 1. Ultrasonic stimuli evoke descending activity in the cervical connectives both ipsilateral and contralateral to the sound source. 2. Both the amount of descending activity and the latency of this response in the cervical connectives are linearly correlated with ultrasonic stimulus intensity, regardless of the cricket's behavioral state. 3. Flight activity significantly increases the a...
Animals that communicate acoustically serve as models for investigating how organisms respond to sou...
Phonotaxis in female cricket Acheta domesticus can be selective or unselective in response to model ...
The responses of single brain neurones to artificial calling song, to moving striped patterns and to...
Decision making in invertebrates often relies on simple neural circuits composed of only a few ident...
An ultrasonic stimulus induced negative phonotactic steering in the yaw axis of tethered, flying Aus...
Sensory responses of various descending brain neurons, their modulation during standing or walking, ...
Tethered, flying Australian field crickets (Teleogryllus oceanicus) stimulated with ultrasound respo...
The ultrasound-induced negative phonotactic response of tethered, flying Australian field crickets h...
Tethered, flying Australian field crickets (Teleogryllus oceanicus) stimulated with ultrasound respo...
Decision making in invertebrates often relies on simple neural circuits composed of only a few ident...
Crickets communicate using loud (100 dB SPL) sound signals that could adversely affect their own aud...
The detection of specific temporal patterns in communication signals may be of vital importance for ...
Crickets provide a useful model system to study how animals analyze sound frequency. While much is k...
Animals need to flexibly respond to stimuli from their environment without compromising behavioural ...
The recognition and localization of sound signals is fundamental to acoustic communication. Complex ...
Animals that communicate acoustically serve as models for investigating how organisms respond to sou...
Phonotaxis in female cricket Acheta domesticus can be selective or unselective in response to model ...
The responses of single brain neurones to artificial calling song, to moving striped patterns and to...
Decision making in invertebrates often relies on simple neural circuits composed of only a few ident...
An ultrasonic stimulus induced negative phonotactic steering in the yaw axis of tethered, flying Aus...
Sensory responses of various descending brain neurons, their modulation during standing or walking, ...
Tethered, flying Australian field crickets (Teleogryllus oceanicus) stimulated with ultrasound respo...
The ultrasound-induced negative phonotactic response of tethered, flying Australian field crickets h...
Tethered, flying Australian field crickets (Teleogryllus oceanicus) stimulated with ultrasound respo...
Decision making in invertebrates often relies on simple neural circuits composed of only a few ident...
Crickets communicate using loud (100 dB SPL) sound signals that could adversely affect their own aud...
The detection of specific temporal patterns in communication signals may be of vital importance for ...
Crickets provide a useful model system to study how animals analyze sound frequency. While much is k...
Animals need to flexibly respond to stimuli from their environment without compromising behavioural ...
The recognition and localization of sound signals is fundamental to acoustic communication. Complex ...
Animals that communicate acoustically serve as models for investigating how organisms respond to sou...
Phonotaxis in female cricket Acheta domesticus can be selective or unselective in response to model ...
The responses of single brain neurones to artificial calling song, to moving striped patterns and to...