Induction of Four‐Dimensional Spatiotemporal Geometric Transformations in High Cell Density Tissues via Shape‐Changing Hydrogels

Developing and healing tissues begin as cellular condensations. Spatiotemporal changes in tissue geometry, transformations in the spatial distribution of the cells, and extracellular matrix are essential for its evolution into a functional tissue. 4D materials, 3D materials capable of geometric changes, may have the potential to recreate the aforementioned biological phenomenon. However, most reported 4D materials are non‐degradable and/or not biocompatible, limiting their application in regenerative medicine, and to date, there are no systems controlling the geometry of high density cellular condensations and differentiation. Here, 4D high cell density tissues based on shape‐changing hydrogels are described. By sequential photocrosslinking of oxidized and methacrylated alginate (OMA) and methacrylated gelatin (GelMA), bilayered hydrogels presenting controllable geometric changes without any external stimuli are fabricated. Fibroblasts and human adipose‐derived stem cells (ASCs) are encapsulated at concentrations up to 1.0 × 108 cells mL–1 in the 4D constructs, and controllable shape changes are achieved in concert with ASCs differentiated down chondrogenic and osteogenic lineages. Bioprinting of the high density cell‐laden OMA and GelMA permits the formation of more complex constructs with defined 4D geometric changes, which may further expand the promise of this approach in regenerative medicine applications. This study reports engineering of 4D high cell density constructs recapitulating the spatiotemporal rearrangement of native tissues. Bilayered and bioprinted high cell density constructs (1.0 × 108 cells mL–1) with a minimal amount of biodegradable and photocrosslinkable polymers enable self‐geometric change mediated by differential swelling properties of each component.