自愈水凝胶
组织工程
脚手架
生物物理学
化学
材料科学
生物医学工程
高分子化学
医学
生物
作者
R. Kevin Tindell,Michael McPhail,Cheryl Myers,Juergen Neubauer,Justin M. Hintze,David G. Lott,Julianne L. Holloway
出处
期刊:Biomacromolecules
[American Chemical Society]
日期:2022-10-26
卷期号:23 (11): 4469-4480
标识
DOI:10.1021/acs.biomac.1c01149
摘要
The lamina propria within the vocal fold (VF) is a complex multilayered tissue that increases in stiffness from the superficial to deep layer, where this characteristic is crucial for VF sound production. Tissue-engineered scaffolds designed for VF repair must mimic the biophysical nature of the native vocal fold and promote cell viability, cell spreading, and vibration with air flow. In this study, we present a unique trilayered, partially degradable hydrogel scaffold that mimics the multilayered structure of the VF lamina propria. Using thiol-norbornene photochemistry, trilayered hydrogel scaffolds were fabricated via layer-by-layer stacking with increasing polymer concentration from the top to middle to deep layer. Mechanical analysis confirmed that hydrogel modulus increased with increasing polymer concentration. Partially degradable hydrogels promoted high cell viability and cell spreading in three dimensions as assessed via live/dead and cytoskeleton staining, respectively. Importantly, partially degradable hydrogels maintained some degree of the three dimensional polymer network following protease exposure, while still enabling encapsulated cells to remodel their local environment via protease secretion. Finally, the trilayered hydrogel scaffold successfully vibrated and produced sound in proof-of-concept air flow studies. This work represents a critical first step toward the design of a multilayered, hydrogel scaffold for vocal fold tissue engineering.
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