Frequency doubling by active in vivo motility of mechanosensory neurons in the mosquito ear
Windmill, James F. C. and Jackson, Joseph C. and Pook, Victoria G. and Robert, Daniel (2018) Frequency doubling by active in vivo motility of mechanosensory neurons in the mosquito ear. Royal Society Open Science, 5. 171082. ISSN 2054-5703 (https://doi.org/10.1098/rsos.171082)
Preview |
Text.
Filename: Windmill_etal_RSOS_2017_Frequency_doubling_by_active_in_vivo_motility_of_mechanosensory_neurons_in_the_mosquito_ear.pdf
Final Published Version License: Download (902kB)| Preview |
Abstract
Across vertebrate and invertebrate species, non-linear active mechanisms are employed to increase the sensitivity and acuity of hearing. In mosquitoes, the antennal hearing organs are known to use active force feedback to enhance auditory acuity to female generated sounds. This sophisticated form of signal processing involves active nonlinear events that are proposed to rely on the motile properties of mechanoreceptor neurons. The fundamental physical mechanism for active auditory mechanics is theorised to rely on a synchronization of motile neurons, with a characteristic frequency doubling of the force generated by an ensemble of motile mechanoreceptors. There is however no direct biomechanical evidence at the mechanoreceptor level, hindering further understanding of the fundamental mechanisms of sensitive hearing. Here, using in situ and in vivo atomic force microscopy, we measure and characterise the mechanical response of mechanosensory neuron units during forced oscillations of the hearing organ. Mechanoreceptor responses exhibit the hallmark of nonlinear feedback for force generation, with movements at twice the stimulus frequency, associated with auditory amplification. Simultaneous electrophysiological recordings exhibit similar response features, notably a frequency doubling of the firing rate. This evidence points to the nature of the mechanism, whereby active hearing in mosquitoes emerges from the double-frequency response of the auditory neurons. These results open up the opportunity to directly investigate active cellular mechanics in auditory systems, and they also reveal a pathway to study the nanoscale biomechanics and its dynamics of cells beyond the sense of hearing.
ORCID iDs
Windmill, James F. C. ORCID: https://orcid.org/0000-0003-4878-349X, Jackson, Joseph C., Pook, Victoria G. and Robert, Daniel;-
-
Item type: Article ID code: 62786 Dates: DateEvent10 January 2018Published28 November 2017Accepted7 August 2017SubmittedSubjects: Technology > Electrical engineering. Electronics Nuclear engineering
Technology > Engineering (General). Civil engineering (General) > BioengineeringDepartment: Faculty of Engineering > Electronic and Electrical Engineering
Technology and Innovation Centre > Sensors and Asset ManagementDepositing user: Pure Administrator Date deposited: 10 Jan 2018 16:00 Last modified: 21 Dec 2024 01:14 URI: https://strathprints.strath.ac.uk/id/eprint/62786