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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 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. 

The cellular organization within organoid models is important to regulate tissue-specific function, yet few engineering approaches can control or direct cellular organization. Here, a photodegradable hydrogel is used to create softened regions that direct crypt formation within intestinal organoids, where the dimensions of the photosoftened regions generate predictable and defined crypt architectures. Guided by in vivo metrics of crypt morphology, this photopatterning method is used to control the width and length of in vitro organoid crypts, which ultimately defines the curvature of the epithelium. By tracking expression of differentiated Paneth-cell markers in real time, we show that epithelial curvature directs the localization of Paneth cells within engineered crypts, providing user-directed control over organoid functionality. We anticipate that our improved control over organoid architecture and thus Paneth-cell localization will lead to more consistent in vitro organoid models for both mechanistic studies and translational applications. 

Hydrogels are extensively used as tunable, biomimetic three-dimensional cell culture matrices, but optically deep, high-resolution images are often difficult to obtain, limiting nanoscale quantification of cell–matrix interactions and outside-in signalling. Here we present photopolymerized hydrogels for expansion microscopy that enable optical clearance and tunable ×4.6–6.7 homogeneous expansion of not only monolayer cell cultures and tissue sections, but cells embedded within hydrogels. The photopolymerized hydrogels for expansion microscopy formulation relies on a rapid photoinitiated thiol/acrylate mixed-mode polymerization that is not inhibited by oxygen and decouples monomer diffusion from polymerization, which is particularly beneficial when expanding cells embedded within hydrogels. Using this technology, we visualize human mesenchymal stem cells and their interactions with nascently deposited proteins at <120 nm resolution when cultured in proteolytically degradable synthetic polyethylene glycol hydrogels. Results support the notion that focal adhesion maturation requires cellular fibronectin deposition; nuclear deformation precedes cellular spreading; and human mesenchymal stem cells display cell-surface metalloproteinases for matrix remodelling. 

Organoids recapitulate many aspects of the complex three-dimensional (3D) organization found within native tissues and even display tissue and organ-level functionality. Traditional approaches to organoid culture have largely employed a top-down tissue engineering strategy, whereby cells are encapsulated in a 3D matrix, such as Matrigel, alongside well-defined biochemical cues that direct morphogenesis. However, the lack of spatiotemporal control over niche properties renders cellular processes largely stochastic. Therefore, bottom-up tissue engineering approaches have evolved to address some of these limitations and focus on strategies to assemble tissue building blocks with defined multi-scale spatial organization. However, bottom-up design reduces the capacity for self-organization that underpins organoid morphogenesis. Here, we introduce an emerging framework, which we term middle-out strategies, that relies on existing design principles and combines top-down design of defined synthetic matrices that support proliferation and self-organization with bottom-up modular engineered intervention to limit the degrees of freedom in the dynamic process of organoid morphogenesis. We posit that this strategy will provide key advances to guide the growth of organoids with precise geometries, structures and function, thereby facilitating an unprecedented level of biomimicry to accelerate the utility of organoids to more translationally relevant applications. 

Stiffness and forces are two fundamental quantities essential to living cells and tissues. However, it has been a challenge to quantify both 3D traction forces and stiffness (or modulus) using the same probe in vivo. Here, we describe an approach that overcomes this challenge by creating a magnetic microrobot probe with controllable functionality. Biocompatible ferromagnetic cobalt-platinum microcrosses were fabricated, and each microcross (about 30 micrometers) was trapped inside an arginine–glycine–aspartic acid–conjugated stiff poly(ethylene glycol) (PEG) round microgel (about 50 micrometers) using a microfluidic device. The stiff magnetic microrobot was seeded inside a cell colony and acted as a stiffness probe by rigidly rotating in response to an oscillatory magnetic field. Then, brief episodes of ultraviolet light exposure were applied to dynamically photodegrade and soften the fluorescent nanoparticle–embedded PEG microgel, whose deformation and 3D traction forces were quantified. Using the microrobot probe, we show that malignant tumor–repopulating cell colonies altered their modulus but not traction forces in response to different 3D substrate elasticities. Stiffness and 3D traction forces were measured, and both normal and shear traction force oscillations were observed in zebrafish embryos from blastula to gastrula. Mouse embryos generated larger tensile and compressive traction force oscillations than shear traction force oscillations during blastocyst. The microrobot probe with controllable functionality via magnetic fields could potentially be useful for studying the mechanoregulation of cells, tissues, and embryos. 

Spatiotemporally coordinated transformations in epithelial curvature are necessary to generate crypt-villus structures during intestinal development. However, the temporal regulation of mechanotransduction pathways that drive crypt morphogenesis remains understudied. Intestinal organoids have proven useful to study crypt morphogenesis in vitro, yet the reliance on static culture scaffolds limits the ability to assess the temporal effects of changing curvature. Here, a photoinduced hydrogel cross-link exchange reaction is used to spatiotemporally alter epithelial curvature and study how dynamic changes in curvature influence mechanotransduction pathways to instruct crypt morphogenesis. Photopatterned curvature increased membrane tension and depolarization, which was required for subsequent nuclear localization of yes-associated protein 1 (YAP) observed 24 hours following curvature change. Curvature-directed crypt morphogenesis only occurred following a delay in the induction of differentiation that coincided with the delay in spatially restricted YAP localization, indicating that dynamic changes in curvature initiate epithelial curvature–dependent mechanotransduction pathways that temporally regulate crypt morphogenesis. 

The ability to engineer complex multicellular systems has enormous potential to inform our understanding of biological processes and disease and alter the drug development process. Engineering living systems to emulate natural processes or to incorporate new functions relies on a detailed understanding of the biochemical, mechanical, and other cues between cells and between cells and their environment that result in the coordinated action of multicellular systems. On April 3–6, 2022, experts in the field met at the Keystone symposium “Engineering Multicellular Living Systems” to discuss recent advances in understanding how cells cooperate within a multicellular system, as well as recent efforts to engineer systems like organ-on-a-chip models, biological robots, and organoids. Given the similarities and common themes, this meeting was held in conjunction with the symposium “Organoids as Tools for Fundamental Discovery and Translation”.