Xavier Barceló scite author profile

The integration of biological systems into robotic devices might provide them with capabilities acquired from natural systems and significantly boost their performance. These abilities include real‐time bio‐sensing, self‐organization, adaptability, or self‐healing. As many muscle‐based bio‐hybrid robots and bio‐actuators arise in the literature, the question of whether these features can live up to their expectations becomes increasingly substantial. Herein, the force generation and adaptability of skeletal‐muscle‐based bio‐actuators undergoing long‐term training protocols are analyzed. The 3D‐bioprinting technique is used to fabricate bio‐actuators that are functional, responsive, and have highly aligned myotubes. The bio‐actuators are 3D‐bioprinted together with two artificial posts, allowing to use it as a force measuring platform. In addition, the force output evolution and dynamic gene expression of the bio‐actuators are studied to evaluate their degree of adaptability according to training protocols of different frequencies and mechanical stiffness, finding that their force generation could be modulated to different requirements. These results shed some light into the fundamental mechanisms behind the adaptability of muscle‐based bio‐actuators and highlight the potential of using 3D bioprinting as a rapid and cost‐effective tool for the fabrication of custom‐designed soft bio‐robots.

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How to design, develop and build a fully-integrated melt electrowriting 3D printer

Eichholz

Gonçalves²,

Barceló³

et al. 2022

Additive Manufacturing

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Design, Optimization and Characterization of Bio-Hybrid Actuators Based on 3D-Bioprinted Skeletal Muscle Tissue

Mestre

Patiño

Guix

et al. 2019

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Bioprinting of structurally organized meniscal tissue within anisotropic melt electrowritten scaffolds

et al. 2023

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Xavier Barceló

Force Modulation and Adaptability of 3D‐Bioprinted Biological Actuators Based on Skeletal Muscle Tissue

How to design, develop and build a fully-integrated melt electrowriting 3D printer

Design, Optimization and Characterization of Bio-Hybrid Actuators Based on 3D-Bioprinted Skeletal Muscle Tissue

Bioprinting of structurally organized meniscal tissue within anisotropic melt electrowritten scaffolds

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