The morphology of the stylohyal-tympanic bone articulation found in laryngeally echolocating bats is highly indicative of a function associated with signal production.One untested hypothesis is that this morphology allows the transfer of a sound signal from the larynx to the tympanic bones (auditory bulla) via the hyoid apparatus during signal production by the larynx. We used µCT data and finite element analysis to model the propagation of sound through the hyoid chain into the tympanic bones to test this hypothesis. We modeled sound pressure (dB) wave propagation from the basihyal to the tympanic bones, vibratory behavior (m) of the stylohyal-tympanic bone unit, and the stylohyal and tympanic bones when the stylohyal bone is allowed to pivot on the tympanic bone. Sound pressure wave propagation was modeled using the harmonic acoustics solver in ANSYS and vibratory behavior was modeled using coupled modal and harmonic response analyses in ANSYS. For both analyses (harmonic acoustics and harmonic response), the input excitation on the basihyal and thyrohyals was modeled as the estimated pressure (Pa) imposed by the collision of the vibrating thyroid cartilage of the larynx against these bones during signal production.Our models support the hypothesis that this stereotypical hyoid morphology found in laryngeally echolocating bats can transfer sound to the auditory bullae at an amplitude that is likely heard for the species Artibeus jamaicensis and Rhinolophus pusillus.
The hyoid apparatus in laryngeally echolocating bats is unique as it forms a mechanical connection between the larynx and auditory bullae which has been hypothesized to transfer the outgoing echolocation call to the middle ear during call emission. Previous finite element modeling (FEM) found that hyoid-borne sound can reach the bulla at an amplitude likely heard by echolocating bats; however, that study did not model how or if the signal could reach the inner ear (or cochlea). One route that sound could take is via stimulation of the eardrum – similarly to that of air-conducted sound. We used µCT data to build models of the hyoid apparatus and middle ear from six species of bats with variable morphology. Using FEM, we ran harmonic response analyses to measure the vibroacoustic response of the tympanic membrane due to hyoid-borne sound generated during echolocation and found that hyoid-borne sound in all six species stimulated the eardrum within a range likely heard by bats. Although there was variation in the efficiency between models, there are no obvious morphological patterns to account for it. This suggests that hyoid morphology in laryngeal echolocators is likely driven by other associated functions.
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