Cartilage equivalents from hydrogels containing chondrocytes exhibit excellent potential in hyaline cartilage regeneration, yet current approaches have limited success at reconstituting the architecture to culture nondifferentiated chondrocytes in vitro. In this study, specially designed lacunar hyaluronic acid microcarriers (LHAMCs) with mechanotransductive conditions that rapidly form stable hyaluronic acid (HA) N‐hydroxy succinimide ester (NHS‐ester) are reported. Specifically, carboxyl‐functionalized HA is linked to collagen type I via amide‐crosslinking, and gas foaming produced by ammonium bicarbonate forms concave surface of the microcarriers. The temporal 3D culture of chondrocytes on LHAMCs uniquely remodels the extracellular matrix to induce hyaline cartilaginous microtissue regeneration and prevents an anaerobic‐to‐aerobic metabolism transition in response to the geometric constraints. Furthermore, by inhibiting the canonical Wnt pathway, LHAMCs prevent β‐catenin translocation to the nucleus, repressing chondrocyte dedifferentiation. Additionally, the subcutaneous implantation model indicates that LHAMCs display favorable cytocompatibility and drive robust hyaline chondrocyte‐derived neocartilage formation. These findings reveal a novel strategy for regulating chondrocyte dedifferentiation. The current study paves the way for a better understanding of geometrical insight clues into mechanotransduction interaction in regulating cell fate, opening new avenues for advancing tissue engineering.
Cartilage Tissue Engineering
In article number 2212114, Wenguo Cui, Qi Gu, Ming‐Zhu Zhang, and co‐workers introduce novel cartilage lacuna‐inspired microcarriers with geometric constraints to repress chondrocyte dedifferentiation by inhibiting Wnt signaling. The biomimetic microcarriers display favorable cytocompatibility and drive robust hyaline chondrocyte‐derived neocartilage formation. This study paves the way for deciphering the geometrical insights into the interactional mechanism of mechanotransduction in regulating cell fate.
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