Litcius/Paper detail

Biomimetic Tympanic Membrane Replacement Made by Melt Electrowriting

Max von Witzleben, Thomas Stoppe, Tilman Ahlfeld, Anne Bernhardt, Marie‐Luise Polk, Matthias Bornitz, Marcus Neudert, Michael Gelinsky

2021Advanced Healthcare Materials49 citationsDOIOpen Access PDF

Abstract

The tympanic membrane (TM) transfers sound waves from the air into mechanical motion for the ossicular chain. This requires a high sensitivity to small dynamic pressure changes and resistance to large quasi-static pressure differences. The TM achieves this by providing a layered structure of about 100µm in thickness, a low flexural stiffness, and a high tensile strength. Chronically infected middle ears require reconstruction of a large area of the TM. However, current clinical treatment can cause a reduction in hearing. With the novel additive manufacturing technique of melt electrowriting (MEW), it is for the first time possible to fabricate highly organized and biodegradable membranes within the dimensions of the TM. Scaffold designs of various fiber composition are analyzed mechanically and acoustically. It can be demonstrated that by customizing fiber orientation, fiber diameter, and number of layers the desired properties of the TM can be met. An applied thin collagen layer seals the micropores of the MEW-printed membrane while keeping the favorable mechanical and acoustical characteristics. The determined properties are beneficial for implantation, closely match those of the human TM, and support the growth of a neo-epithelial layer. This proves the possibilities to create a biomimimetic TM replacement using MEW.

Topics & Concepts

Materials scienceFlexural strengthMembraneUltimate tensile strengthFlexural rigidityFiberStiffnessLayer (electronics)Composite materialSound pressureBiomedical engineeringAcousticsGeneticsPhysicsMedicineBiologyEar Surgery and Otitis MediaReconstructive Facial Surgery TechniquesTracheal and airway disorders