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Injectable hydrogels are increasingly explored for the delivery of cells to tissue. These materials exhibit both liquid‐like properties, protecting cells from mechanical stress during injection, and solid‐like properties, providing a stable 3D engraftment niche. Many strategies for modulating injectable hydrogels tune liquid‐ and solid‐like material properties simultaneously, such that formulation changes designed to improve injectability can reduce stability at the delivery site. The ability to independently tune liquid‐ and solid‐like properties would greatly facilitate formulation development. Here, such a strategy is presented in which cells are ensconced in the pores between microscopic granular hyaluronic acid (HA) hydrogels (microgels), where elasticity is tuned with static covalent intra‐microgel crosslinks and flowability with mechanosensitive adamantane‐cyclodextrin (AC) inter‐microgel crosslinks. Using the same AC‐free microgels as a 3D printing support bath, the location of each cell is preserved as it exits the needle, allowing identification of the mechanism driving mechanical trauma‐induced cell death. The microgel AC concentration is varied to find the threshold from microgel yielding‐ to AC interaction‐dominated injectability, and this threshold is exploited to fabricate a microgel with better injection‐protecting performance. This delivery strategy, and the balance between intra‐ and inter‐microgel properties it reveals, may facilitate the development of new cell injection formulations.

With improving biofabrication technology, 3D bioprinted constructs increasingly resemble real tissues. However, the fundamental principles describing how cell-generated forces within these constructs drive deformations, mechanical instabilities, and structural failures have not been established, even for basic biofabricated building blocks. Here we investigate mechanical behaviours of 3D printed microbeams made from living cells and extracellular matrix, bioprinting these simple structural elements into a 3D culture medium made from packed microgels, creating a mechanically controlled environment that allows the beams to evolve under cell-generated forces. By varying the properties of the beams and the surrounding microgel medium, we explore the mechanical behaviours exhibited by these structures. We observe buckling, axial contraction, failure, and total static stability, and we develop mechanical models of cell-ECM microbeam mechanics. We envision these models and their generalizations to other fundamental 3D shapes to facilitate the predictable design of biofabricated structures using simple building blocks in the future.