Publications by authors named "Mayuka Kanaya"
In humans, ventricular folds are located superiorly to the vocal folds. Under special circumstances such as voice pathology or singing, they vibrate together with the vocal folds to contribute to the production of voice. In the present study, experimental data measured from physical models of the vocal and ventricular folds were analyzed in the light of nonlinear dynamics.
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- Primates use varied vocalizations to communicate, with the larynx playing a key role by allowing vocal folds to vibrate and modify airflow.
- Madagascan lemurs have a unique anatomical feature: an additional pair of folds in the vestibular region that likely vibrate similarly to the vocal folds, suggesting a novel means of sound production.
- Experiments using a silicone model show that both pairs of folds in lemurs can vibrate together, which lowers vocal frequency and enhances vocal efficiency, demonstrating a unique evolutionary adaptation in their vocal anatomy.
We carried out ex vivo and in vivo experiments to explore the functional role of the ventricular folds in sound production in macaques. In the ex vivo experiments, 29 recordings out of 67 showed that the ventricular folds co-oscillated with the vocal folds. Transitions from normal vocal fold oscillations to vocal-ventricular fold co-oscillations as well as chaotic irregular oscillations were also observed.
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- Scientists studied the vocal membranes in animals like bats and monkeys to see how they help them make sounds.
- They created a model to test if these membranes make it easier to produce vocal sounds by needing less pressure.
- The experiments showed that the model with vocal membranes needed less pressure and had some wild sound patterns too!
To examine the quasi-steady approximation of the glottal flow, widely used in the modeling of vocal fold oscillations, intraglottal pressure distributions were measured in a scaled-up static vocal fold model under time-varying flow conditions. The left and right vocal folds were slightly open and set to a symmetric and oblique configuration with a divergence angle. To realize time-varying flow conditions, the flow rate was sinusoidally modulated with a frequency of 2 and 10 Hz, which correspond to 112.
View Article and Find Full Text PDFThe ventricular folds, located superiorly to the vocal folds, do not usually vibrate during normal phonations. It has been shown, however, that they do vibrate together with the vocal folds under special circumstances such as voice pathology and singing voice. Towards understanding the effect of the ventricular fold oscillations on the vocal fold oscillations, the present study developed a synthetic model that takes into account anatomical features of the human ventricular folds.
View Article and Find Full Text PDFVentricular folds are located in the supraglottal region above the vocal folds. Although the ventricular folds do not vibrate under normal vocalizations, they vibrate under certain conditions, e.g.
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