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Abstract As a model of the intestinal epithelium, intestinal stem cells (ISCs) are grown and differentiated as monolayers on materials where stochastic organization of the crypt and villi cells occurs. An allyl sulfide crosslinked photoresponsive hydrogel with a shear modulus of 1.6 kPa is developed and functionalized with GFOGER, Bm‐binder peptide ligands for monolayer growth of ISCs. The allyl sulfide chemistry allows in situ control of mechanics in the presence of growing ISC monolayers and structured irradiation affords spatial regulation of the hydrogel properties. Specifically, ISC monolayers grown on 1.6 kPa substrates are in situ softened to 0.29 kPa, using circular patterns 50, 75, and 100 µm in diameter, during differentiation, resulting in control over the size and arrangement of de novo crypts and monolayer cellularity. These photoresponsive materials should be useful in applications ranging from studying crypt evolution to drug screening and transport across tissues of changing cellular composition. Spatiotemporal softening enables control over the size and arrangement of de novo crypts within intestinal monolayers. 

Abstract Liquid crystalline elastomers (LCEs) are stimuli‐responsive materials capable of undergoing large deformations. The thermomechanical response of LCEs is attributable to the coupling of polymer network properties and disruption of order between liquid crystalline mesogens. Complex deformations have been realized in LCEs by either programming the nematic director via surface‐enforced alignment or localized mechanical deformation in materials incorporating dynamic covalent chemistries. Here, the preparation of LCEs via thiol‐Michael addition reaction is reported that are amenable to surface‐enforced alignment. Afforded by the thiol‐Michael addition reaction, dynamic covalent bonds are uniquely incorporated in chemistries subject to surface‐enforce alignment. Accordingly, LCEs prepared with complex director profiles are able to be programmed and reprogrammed by (re)activating the dynamic covalent chemistry to realize distinctive shape transformations. 

Abstract 3D organoid models have recently seen a boom in popularity, as they can better recapitulate the complexity of multicellular organs compared to other in vitro culture systems. However, organoids are difficult to image because of the limited penetration depth of high‐resolution microscopes and depth‐dependent light attenuation, which can limit the understanding of signal transduction pathways and characterization of intimate cell‐extracellular matrix (ECM) interactions. To overcome these challenges, phototransfer by allyl sulfide exchange‐expansion microscopy (PhASE‐ExM) is developed, enabling optical clearance and super‐resolution imaging of organoids and their ECM in 3D. PhASE‐ExM uses hydrogels prepared via photoinitiated polymerization, which is advantageous as it decouples monomer diffusion into thick organoid cultures from the hydrogel fabrication. Apart from compatibility with organoids cultured in Matrigel, PhASE‐ExM enables 3.25× expansion and super‐resolution imaging of organoids cultured in synthetic poly(ethylene glycol) (PEG) hydrogels crosslinked via allyl‐sulfide groups (PEG‐AlS) through simultaneous photopolymerization and radical‐mediated chain‐transfer reactions that complete in <70 s. Further, PEG‐AlS hydrogels can be in situ softened to promote organoid crypt formation, providing a super‐resolution imaging platform both for pre‐ and post‐differentiated organoids. Overall, PhASE‐ExM is a useful tool to decipher organoid behavior by enabling sub‐micrometer scale, 3D visualization of proteins and signal transduction pathways.