In this work, we present an innovative, high-throughput rotary wet-spinning biofabrication method for manufacturing cellularized constructs composed of highly-aligned hydrogel fibers. The platform is supported by an innovative microfluidic printing head (MPH) bearing a crosslinking bath microtank with a co-axial nozzle placed at the bottom of it for the immediate gelation of extruded core/shell fibers. After a thorough characterization and optimization of the new MPH and the fiber deposition parameters, we demonstrate the suitability of the proposed system for the in vitro engineering of functional myo-substitutes. The samples produced through the described approach were first characterized in vitro and then used as a substrate to ascertain the effects of electro-mechanical stimulation on myogenic maturation. Of note, we found a characteristic gene expression modulation of fast (MyH1), intermediate (MyH2), and slow (MyH7) twitching myosin heavy chain isoforms, depending on the applied stimulation protocol. This feature should be further investigated in the future to biofabricate engineered myo-substitutes with specific functionalities.

Celikkin, N., Presutti, D., Maiullari, F., Volpi, M., Promovych, Y., Gizynski, K., et al. (2023). Combining rotary wet-spinning biofabrication and electro-mechanical stimulation for thein vitroproduction of functional myo-substitutes. BIOFABRICATION, 15(4) [10.1088/1758-5090/ace934].

Combining rotary wet-spinning biofabrication and electro-mechanical stimulation for thein vitroproduction of functional myo-substitutes

Maiullari, Fabio;Fuoco, Claudia;Gargioli, Cesare;Costantini, Marco
2023-08-09

Abstract

In this work, we present an innovative, high-throughput rotary wet-spinning biofabrication method for manufacturing cellularized constructs composed of highly-aligned hydrogel fibers. The platform is supported by an innovative microfluidic printing head (MPH) bearing a crosslinking bath microtank with a co-axial nozzle placed at the bottom of it for the immediate gelation of extruded core/shell fibers. After a thorough characterization and optimization of the new MPH and the fiber deposition parameters, we demonstrate the suitability of the proposed system for the in vitro engineering of functional myo-substitutes. The samples produced through the described approach were first characterized in vitro and then used as a substrate to ascertain the effects of electro-mechanical stimulation on myogenic maturation. Of note, we found a characteristic gene expression modulation of fast (MyH1), intermediate (MyH2), and slow (MyH7) twitching myosin heavy chain isoforms, depending on the applied stimulation protocol. This feature should be further investigated in the future to biofabricate engineered myo-substitutes with specific functionalities.
9-ago-2023
Pubblicato
Rilevanza internazionale
Articolo
Esperti anonimi
Settore BIO/13
English
Con Impact Factor ISI
3D bioprinting
bioreactor
electrical stimulation
mechanical stimulation
skeletal muscle tissue engineering
Celikkin, N., Presutti, D., Maiullari, F., Volpi, M., Promovych, Y., Gizynski, K., et al. (2023). Combining rotary wet-spinning biofabrication and electro-mechanical stimulation for thein vitroproduction of functional myo-substitutes. BIOFABRICATION, 15(4) [10.1088/1758-5090/ace934].
Celikkin, N; Presutti, D; Maiullari, F; Volpi, M; Promovych, Y; Gizynski, K; Dolinska, J; Wiśniewska, A; Opałło, M; Paradiso, A; Rinoldi, C; Fuoco, C...espandi
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/2108/347724
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