(595g) Biofabrication of Muscle Fibers Enhanced with Plant Viral Nanoparticles Using Surface Chaotic Flows | AIChE

(595g) Biofabrication of Muscle Fibers Enhanced with Plant Viral Nanoparticles Using Surface Chaotic Flows

Authors 

Frias-Sanchez, A. I. - Presenter, Tecnológico de Monterrey
Quevedo-Moreno, D. A., Tecnologico de Monterrey
Samandari, M., College of Engineering, University of Tehran
Tavares-Negrete, J. A., Tecnológico de Monterrey
Sánchez Rodríguez, V. H., Departamento de Mecatrónica y Eléctrica, Tecnologico de Monterrey, Escuela de Ingeniería y Ciencias
González-Gamboa, I., University of California, San Diego
Ponz, F., Instituto Nacional de Investigación y Tecnología Agraria y Alimentaria
Álvarez, M. M., Centro de Biotecnología-FEMSA, Tecnológico de Monterrey, Escuela de Ingeniería y Ciencias
Trujillo de Santiago, G., Tecnológico De Monterrey
Multiple human tissues exhibit fibrous nature. Therefore, the fabrication of hydrogel filaments for tissue engineering is a trending topic. Current tissue models are made of materials that often require further enhancement for appropriate cell attachment, proliferation and differentiation. Here we present a simple strategy, based on the use surface chaotic flows amenable of mathematical modeling, to fabricate continuous, long and thin filaments of gelatin methacryloyl (GelMA). The fabrication of these filaments is achieved by chaotic advection in a finely controlled and miniaturized version of the journal bearing (JB) system. A drop of GelMA pregel was injected on a higher-density viscous fluid (glycerin) and a chaotic flow is applied through an iterative process. The hydrogel drop is exponentially deformed and elongated to generate a fiber, which was then polymerized under UV-light exposure. Computational fluid dynamic (CFD) simulations are conducted to determine the characteristics of the flow and design the experimental conditions for fabrication of the fibers. GelMA fibers were effectively used as scaffolds for C2C12 myoblast cells. Experimental results demonstrate an accurate accordance with CFD simulations for the predicted length of the fibers. Plant-based viral nanoparticles (i.e., Turnip mosaic virus; TuMV) were then integrated to the hydrogel fibers as a secondary nano-scaffold for cells for enhanced muscle tissue engineering. The addition of TuMV significantly increased the metabolic activity of the cell-seeded fibers (p*<0.05), strengthened cell attachment throughout the first 28 days, improved cell alignment, and promoted the generation of structures that resemble natural mammal muscle tissues. Chaotic 2D-printing is proven to be a viable method for the fabrication of hydrogel fibers. The combined use of thin and long GelMA hydrogel fibers enhanced with flexuous virions offers a promising alternative for scaffolding of muscle cells and show potential to be used as cost-effective models for muscle tissue engineering purposes.