Jan Giachino scite author profile

Engineered, centimeter-scale skeletal muscle tissue (SMT) can mimic muscle pathophysiology to study development, disease, regeneration, drug response, and motion. Macroscale SMT requires perfusable channels to guarantee cell survival, and support elements to enable mechanical cell stimulation and uniaxial myofiber formation. Here, stable biohybrid designs of centimeter-scale SMT are realized via extrusion-based bioprinting of an optimized polymeric blend based on gelatin methacryloyl and sodium alginate, which can be accurately coprinted with other inks. A perfusable microchannel network is designed to functionally integrate with perfusable anchors for insertion into a maturation culture template. The results demonstrate that i) coprinted synthetic structures display highly coherent interfaces with the living tissue, ii) perfusable designs preserve cells from hypoxia all over the scaffold volume, iii) constructs can undergo passive mechanical tension during matrix remodeling, and iv) the constructs can be used to study the distribution of drugs. Extrusion-based multimaterial bioprinting with the inks and design realizes in vitro matured biohybrid SMT for biomedical applications.

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Perfusable Biohybrid Designs for Bioprinted Skeletal Muscle Tissue (Adv. Healthcare Mater. 18/2023)

Filippi¹,

Yaşa²,

Giachino³

et al. 2023

Adv Healthcare Materials

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Bioactuators In article 2300151 by Robert K. Katzschmann and co‐workers, a perfusable, biohybrid design enables the extrusion‐based bioprinting of centimeter‐scale skeletal muscle tissue that is cointegrated with synthetic anchors for tissue mechanical stimulation and crossed by longitudinal channels for passive liquid perfusion, which supports cell viability all over the tissue volume and allows for drug delivery and distribution tests.

show abstract

Perfusable biohybrid designs for bioprinted skeletal muscle tissue

Filippi

Yaşa

Giachino

et al. 2023

Preprint

View full text Add to dashboard Cite

Engineered, centimeter-scale skeletal muscle tissue (SMT) can mimic muscle pathophysiology to study development, disease, regeneration, drug response, and motion. Macroscale SMT requires perfusable channels to guarantee cell survival and support elements to enable mechanical cell stimulation and uniaxial myofiber formation. Here, stable biohybrid designs of centimeter-scale SMT are realized via extrusion-based bioprinting of an optimized polymeric blend based on gelatin methacryloyl and sodium alginate, which can be accurately co-printed with other inks. A perfusable microchannel network is designed to functionally integrate with perfusable anchors for insertion into a maturation culture template. The results demonstrate that (i) co-printed synthetic structures display highly coherent interfaces with the living tissue; (ii) perfusable designs preserve cells from hypoxia all over the scaffold volume; and (iii) constructs can undergo passive mechanical tension during matrix remodeling. Extrusion-based multimaterial bioprinting with our inks and design realizes in vitro matured biohybrid SMT for biomedical, nutritional, and robotic applications.

show abstract

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Jan Giachino

Perfusable Biohybrid Designs for Bioprinted Skeletal Muscle Tissue

Perfusable Biohybrid Designs for Bioprinted Skeletal Muscle Tissue (Adv. Healthcare Mater. 18/2023)

Perfusable biohybrid designs for bioprinted skeletal muscle tissue

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