Schlicht S, Kaufmann A, Tur B, Kniesburges S, Drummer D (2024)
Publication Type: Conference contribution, Original article
Publication year: 2024
Conference Proceedings Title: Proceedings of the 13th International Conference on Voice Physiology and Biomechanics
Objectives / Introduction:
The experimental investigation of the flow-structure coupling represents a significant challenge in otolaryngology/phoniatrics, which is often performed with human and animal-derived specimens showing a rapid degradation of relevant mechanical and dynamic properties. The synthetic, elastomer-based replication of laryngeal mechanics remains challenging due to the complex, non-linear mechanical properties of the larynx. Complementing previously described approaches relying on the multi-layered molding of laryngeal structures, the presented approach is based on the adhesion-controlled highly dynamic rotational molding of ultra-soft silicones, yielding film thicknesses as low as 10 micrometers with ultra-soft properties and high geometric precision.
Methods:
Relying on rotational frequencies exceeding 30 Hz, the manufacturing of thin-walled laryngeal models becomes feasible. Based on the multi-layered manufacturing, the targeted modification of superficial mechanics with ultra-soft properties is obtained while enabling the replication of complex geometries and undercuts. The subsequent elastomer- and hydrogel-based modification of molded silicone structures allows for adapting the mechanical and dynamic properties of the vocal folds, representing a promising approach for the facilitated modeling of laryngeal dynamics.
Results:
Based on the described method, first prototypes of vocal fold models were manufactured. These prototypes were evaluated in a customized experimental setup by measuring the vocal folds’ dynamics, the subglottal pressure and the generated sound signal.
Conclusions:
While the manufacturing of ultra-soft laryngeal models with a high geometric precision is usually impaired due to
material-specific limitations of ultra-soft polymers, employing the multi-layered manufacturing of elastomers of varying
mechanical properties allows to mimic the biomechanical properties of the vocal folds while minimizing adverse adhesive
effects and the aging of models
APA:
Schlicht, S., Kaufmann, A., Tur, B., Kniesburges, S., & Drummer, D. (2024). Highly dynamic rotational molding of thin-walled larynx models for fluid dynamic modelling. In Proceedings of the 13th International Conference on Voice Physiology and Biomechanics. Erlangen, DE.
MLA:
Schlicht, Samuel, et al. "Highly dynamic rotational molding of thin-walled larynx models for fluid dynamic modelling." Proceedings of the 13th International Conference on Voice Physiology and Biomechanics, Erlangen 2024.
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