Toward a Physiologically Relevant 3D Helicoidal-Oriented Cardiac Model: Simultaneous Application of Mechanical Stimulation and Surface Topography

Navaee, Fatemeh; Renaud, Philippe; Piacentini, Niccolò; Durand, Mathilde; Bayat, Dara; Ledroit, Diane; Heub, Sarah; Boder-Pasche, Stéphanie; Kleger, Alexander; Braschler, Thomas; Weder, Gilles

doi:10.3390/bioengineering10020266

Cited by 2 publications

(1 citation statement)

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“…70 In addition, the main stress and strain directions form an obvious helical structure at the macroscopic level. Navaee et al 71 performed periodic uniaxial mechanical stretching of the pre-aligned EHT to simulate the helical arrangement of tissues in vivo , which demonstrated that mechanical stimuli and surface morphology increased the neonatal CMs maturation markers α-actinin and connexin-43, and promoted their maturation and functions. Recently, Takada et al 72 constructed EHT with more uniform arrangement of CMs by implanting hiPSC-CMs into microprocessed fibronectin gels.…”

Section: Methods For Constructing Human Cardiac Organoidsmentioning

confidence: 99%

Cardiac organoid: multiple construction approaches and potential applications

et al. 2023

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Section: Methods For Constructing Human Cardiac Organoidsmentioning

confidence: 99%

Cardiac organoid: multiple construction approaches and potential applications

et al. 2023

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Programmable 3D cell alignment of bioprinted tissue via soft robotic dynamic stimulation

Rosalia,

Mosle,

Sinha

et al. 2024

Preprint

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Recent breakthroughs in biofabrication have enabled the development of engineered tissues for various organ systems, supporting applications in drug testing and regenerative medicine. However, current approaches do not allow for dynamic mechanical maturation of engineered tissue in 3D. Although uniaxial mechanostimulation techniques have shown promise in generating anisotropic tissues, they fail to recapitulate the biomechanics of complex tissues. As a result, existing biofabricated tissues lack the ability to replicate complex 3D alignment patterns essential for functional biomimicry. Here, we present a soft robotics-driven approach for programmable 3D alignment in 3D bioprinted tissue. Our method introduces the co-printing of biological tissue with a silicone-based soft robot via a custom core-double shell nozzle. The application of 3D, exogenous, dynamic expansion and torsional forces to the tissue via the co-printed silicone robot was found to drive cell alignment. Confocal imaging revealed pronounced anisotropy of the stimulated tissue samples compared to the unstimulated controls. In addition, different cellular orientation patterns resulted from each mode of stimulation, demonstrating the versatility of the soft robotic approach in tailoring the pattern of tissue alignment based on programmed mechanostimulation.

show abstract

Toward a Physiologically Relevant 3D Helicoidal-Oriented Cardiac Model: Simultaneous Application of Mechanical Stimulation and Surface Topography

Cited by 2 publications

References 35 publications

Cardiac organoid: multiple construction approaches and potential applications

Cardiac organoid: multiple construction approaches and potential applications

Programmable 3D cell alignment of bioprinted tissue via soft robotic dynamic stimulation

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