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1. Cell Microencapsulation Within Engineered Hyaluronan Elastin‐Like Protein (HELP) Hydrogels

   https://doi.org/10.1002/cpz1.917  

   Hefferon, Meghan E.; Huang, Michelle S.; Liu, Yueming; Navarro, Renato S.; de Paiva Narciso, Narelli; Zhang, Daiyao; Aviles‐Rodriguez, Giselle; Heilshorn, Sarah C. (November 2023, Current Protocols)

   Abstract Three‐dimensional cell encapsulation has rendered itself a staple in the tissue engineering field. Using recombinantly engineered, biopolymer‐based hydrogels to encapsulate cells is especially promising due to the enhanced control and tunability it affords. Here, we describe in detail the synthesis of our hyaluronan (i.e., hyaluronic acid) and elastin‐like protein (HELP) hydrogel system. In addition to validating the efficacy of our synthetic process, we also demonstrate the modularity of the HELP system. Finally, we show that cells can be encapsulated within HELP gels over a range of stiffnesses, exhibit strong viability, and respond to stiffness cues. © 2023 Wiley Periodicals LLC. Basic Protocol 1: Elastin‐like protein modification with hydrazine Basic Protocol 2: Nuclear magnetic resonance quantification of elastin‐like protein modification with hydrazine Basic Protocol 3: Hyaluronic acid–benzaldehyde synthesis Basic Protocol 4: Nuclear magnetic resonance quantification of hyaluronic acid–benzaldehyde Basic Protocol 5: 3D cell encapsulation in hyaluronan elastin‐like protein gels 

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2. Conformal single cell hydrogel coating with electrically induced tip streaming of an AC cone

   https://doi.org/10.1039/D0BM02100H  

   Pan, Zehao; Bui, Loan; Yadav, Vivek; Fan, Fei; Chang, Hsueh-Chia; Hanjaya-Putra, Donny (May 2021, Biomaterials Science)

   Encapsulation of single cells in a thin hydrogel provides a more precise control of stem cell niches and better molecular transport. Despite the recent advances in microfluidic technologies to allow encapsulation of single cells, existing methods rely on special crosslinking agents that are pre-coated on the cell surface and subject to the variation of the cell membrane, which limits their widespread adoption. This work reports a high-throughput single-cell encapsulation method based on the “tip streaming” mode of alternating current (AC) electrospray, with encapsulation efficiencies over 80% after tuned centrifugation. Dripping with multiple cells is curtailed due to gating by the sharp conic meniscus of the tip streaming mode that only allows one cell to be ejected at a time. Moreover, the method can be universally applied to both natural and synthetic hydrogels, as well as various cell types, including human multipotent mesenchymal stromal cells (hMSCs). Encapsulated hMSCs maintain good cell viability over an extended culture period and exhibit robust differentiation potential into osteoblasts and adipocytes. Collectively, electrically induced tip streaming enables high-throughput encapsulation of single cells with high efficiency and universality, which is applicable for various applications in cell therapy, pharmacokinetic studies, and regenerative medicine. 

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3. Sliding on Slide-Ring Gels

   https://doi.org/10.1007/s11249-024-01920-x  

   Rhode, Andrew R; Montes_de_Oca, Iván; Chabinyc, Michael L; Bates, Christopher M; Pitenis, Angela A (December 2024, Tribology Letters)

   Abstract Recent investigations have pointed to physical entanglements that greatly outnumber chemical crosslinks as key sources of energy dissipation and low friction in hydrogel networks. Slide-ring gels are an emerging class of hydrogels described by their mobile crosslinks, which are formed by rings topologically constrained to slide along linear polymer chains within the network. These materials have enjoyed decades of study by polymer chemists but have been underexplored by the tribology community. In this work, we synthesized a pseudo-rotaxane crosslinker from poly(ethylene glycol) diacrylate (PEG-diacrylate) andα-cyclodextrin-acrylate followed by hydrogel networks by connecting the sliding crosslinks with polyacrylamide chains. The mechanical and tribological properties of slide-ring hydrogels were investigated using a custom-built microtribometer. Slide-ring hydrogels exhibit unique behavior compared to conventional covalently crosslinked polyacrylamide hydrogels and offer a vast design space for future investigations. Graphical Abstract 

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4. Orthogonal click reactions enable the synthesis of ECM-mimetic PEG hydrogels without multi-arm precursors

   https://doi.org/10.1039/C8TB01399C  

   Jivan, Faraz; Fabela, Natalia; Davis, Zachary; Alge, Daniel L. (January 2018, Journal of Materials Chemistry B)

   Click chemistry reactions have become an important tool for synthesizing user-defined hydrogels consisting of poly(ethylene glycol) (PEG) and bioactive peptides for tissue engineering. However, because click crosslinking proceeds via a step-growth mechanism, multi-arm telechelic precursors are required, which has some disadvantages. Here, we report for the first time that this requirement can be circumvented to create PEG–peptide hydrogels solely from linear precursors through the use of two orthogonal click reactions, the thiol–maleimide Michael addition and thiol–norbornene click reaction. The rapid kinetics of both click reactions allowed for quick formation of norbornene-functionalized PEG–peptide block copolymers via Michael addition, which were subsequently photocrosslinked into hydrogels with a dithiol linker. Characterization and in vitro testing demonstrated that the hydrogels have highly tunable physicochemical properties and excellent cytocompatibility. In addition, stoichiometric control over the crosslinking reaction can be leveraged to leave unreacted norbornene groups in the hydrogel for subsequent hydrogel functionalization via bioorthogonal inverse-electron demand Diels–Alder click reactions with s -tetrazines. After selectively capping norbornene groups in a user-defined region with cysteine, this feature was leveraged for protein patterning. Collectively, these results demonstrate that our novel chemical strategy is a simple and versatile approach to the development of hydrogels for tissue engineering that could be useful for a variety of applications. 

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5. Serial Passaging Affects Stromal Cell Mechanosensitivity on Hyaluronic Acid Hydrogels

   https://doi.org/10.1002/mabi.202300110  

   Sumey, Jenna L.; Harrell, Abigail M.; Johnston, Peyton C.; Caliari, Steven R. (January 2024, Macromolecular Bioscience)

   Abstract There is a tremendous interest in developing hydrogels as tunable in vitro cell culture platforms to study cell response to mechanical cues in a controlled manner. However, little is known about how common cell culture techniques, such as serial expansion on tissue culture plastic, affect subsequent cell behavior when cultured on hydrogels. In this work, a methacrylated hyaluronic acid hydrogel platform is leveraged to study stromal cell mechanotransduction. Hydrogels are first formed through thiol‐Michael addition to model normal soft tissue (e.g., lung) stiffness (E ≈ 1 kPa). Secondary cross‐linking via radical photopolymerization of unconsumed methacrylates allows matching of early‐ (E ≈ 6 kPa) and late‐stage fibrotic tissue (E ≈ 50 kPa). Early passage (P1) human bone marrow mesenchymal stromal cells (hMSCs) display increased spreading, myocardin‐related transcription factor‐A (MRTF‐A) nuclear localization, and focal adhesion size with increasing hydrogel stiffness. However, late passage (P5) hMSCs show reduced sensitivity to substrate mechanics with lower MRTF‐A nuclear translocation and smaller focal adhesions on stiffer hydrogels compared to early passage hMSCs. Similar trends are observed in an immortalized human lung fibroblast line. Overall, this work highlights the implications of standard cell culture practices on investigating cell response to mechanical signals using in vitro hydrogel models. 

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