PEER-REVIEWED PUBLICATION

2025

A new biofunctionalized and micropatterned PDMS is able to promote stretching-induced human myotube maturation

Regagnon T, Raynaud F, et al.

Lab on a Chip

Université de Montpellier, Université Franche-Comté, Service de Physiologie CHU Arnaud de Villeneuve Montpellier

RESEARCH SUMMARY

This study developed a biofunctionalized and micropatterned PDMS membrane platform to enhance human myotube alignment and maturation through combined biochemical guidance and mechanical stimulation. Laminin micropatterning promoted myoblast fusion and anisotropic myotube organization, while cyclic uniaxial stretch significantly improved sarcomeric structure, contractile protein expression, and myotube elongation. Together, these results demonstrate that integrating substrate micropatterning with dynamic mechanical conditioning accelerates skeletal muscle maturation and improves the physiological relevance of in vitro muscle models.

Dynamic mechanical stimulation of differentiated human myotubes was performed using a CellScale MechanoCulture T6 uniaxial stretching system. Following myogenic differentiation on micropatterned PDMS membranes, substrates were mounted into the MechanoCulture T6 and subjected to controlled cyclic uniaxial stretch at defined strain amplitudes and frequencies. The system enabled reproducible application of dynamic tensile deformation to living cell cultures without measuring mechanical properties, serving specifically as a mechanostimulation platform rather than a mechanical testing device. Use of the MechanoCulture T6 was essential for demonstrating that cyclic stretch acts synergistically with substrate micropatterning to drive sarcomeric alignment, myotube elongation, and maturation, thereby validating the mechanosensitivity of the engineered PDMS culture system.

AUTHORS

Théo Regagnon, Fabrice Raynaud, Gilles Subra, Gilles Carnac, Gerald Hugon, Aurélien Flatres, Vincent Humblot, Laurine Raymond, Julie Martin, Elodie Carretero, Margaux Clavié, Nathalie Saint, Sylvie Calas, Cécile Echalier, Pascal Etiennea, Stefan Matecki.

PUBLICATION DETAILS

JOURNAL

Lab on a Chip

YEAR

2025

INSTITUTIONS

Université de Montpellier, Université Franche-Comté, Service de Physiologie CHU Arnaud de Villeneuve Montpellier

COUNTRIES

France

INSTRUMENT USED

MechanoCulture T6

TESTING METHODS

Tensile Testing

RESEARCH APPLICATIONS

MechanotransductionSkeletal Muscle & Volumetric Muscle Loss

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Advanced Materials

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Cell Laden HydrogelsInjectable & Regenerative BiomaterialsMechanotransductionStem Cell MechanobiologyTendon Tissue Engineering & Ligament Mechanics

2025