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1. Bioorthogonal Strategies for Engineering Extracellular Matrices

   https://doi.org/10.1002/adfm.201706046  

   Madl, Christopher M. ; Heilshorn, Sarah C. ( January 2018 , Advanced Functional Materials)

   Hydrogels are commonly used as engineered extracellular matrix (ECM) mimics in applications ranging from tissue engineering to in vitro disease models. Ideal mechanisms used to crosslink ECM‐mimicking hydrogels do not interfere with the biology of the system. However, most common hydrogel crosslinking chemistries exhibit some form of crossreactivity. The field of bioorthogonal chemistry has arisen to address the need for highly specific and robust reactions in biological contexts. Accordingly, bioorthogonal crosslinking strategies are incorporated into hydrogel design, allowing for gentle and efficient encapsulation of cells in various hydrogel materials. Furthermore, the selective nature of bioorthogonal chemistries can permit dynamic modification of hydrogel materials in the presence of live cells and other biomolecules to alter matrix mechanical properties and biochemistry on demand. This review provides an overview of bioorthogonal strategies used to prepare cell‐encapsulating hydrogels and highlights the potential applications of bioorthogonal chemistries in the design of dynamic engineered ECMs.

    

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2. 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)

   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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3. 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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4. Hybrid Synthetic‐Biological Hydrogel System for Adipose Tissue Regeneration

   https://doi.org/10.1002/mabi.201800122  

   Li, Shue ; Poche, John Nicholas ; Liu, Yiming ; Scherr, Thomas ; McCann, Jacob ; Forghani, Anoosha ; Smoak, Mollie ; Muir, Mitchell ; Berntsen, Lisa ; Chen, Cong ; et al ( September 2018 , Macromolecular Bioscience)

   Hydrogels are promising scaffolds for adipose tissue regeneration. Currently, the incorporation of bioactive molecules in hydrogel system is used, which can increase the cell proliferation rate or improve adipogenic differentiation performance of stromal stem cells but often suffers from high expense or cytotoxicity because of light/thermal curing used for polymerization. In this study, decellularized adipose tissue is incorporated, at varying concentrations, with a thiol‐acrylate fraction that is then polymerized to produce hydrogels via a Michael addition reaction. The results reveal that the major component of isolated adipose‐derived extracellular matrix (ECM) is Collagen I. Mechanical properties of ECM polyethylene glycol (PEG) are not negatively affected by the incorporation of ECM. Additionally, human adipose‐derived stem cells (hASCs) are encapsulated in ECM PEG hydrogel with ECM concentrations varying from 0% to 1%. The results indicate that hASCs maintained the highest viability and proliferation rate in 1% ECM PEG hydrogel with most lipids formation when cultured in adipogenic conditions. Furthermore, more adipose regeneration is observed in 1% ECM group with in vivo study by Day 14 compared to other ECM PEG hydrogels with lower ECM content. Taken together, these findings suggest the ECM PEG hydrogel is a promising substitute for adipose tissue regeneration applications.

    

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5. Dynamic Click Hydrogels for Xeno‐Free Culture of Induced Pluripotent Stem Cells

   https://doi.org/10.1002/adbi.202000129  

   Arkenberg, Matthew R. ; Dimmitt, Nathan H. ; Johnson, Hunter C. ; Koehler, Karl R. ; Lin, Chien‐Chi ( September 2020 , Advanced Biosystems)

   Xeno‐free, chemically defined poly(ethylene glycol) (PEG)‐based hydrogels are being increasingly used for in vitro culture and differentiation of human induced pluripotent stem cells (hiPSCs). These synthetic matrices provide tunable gelation and adaptable material properties crucial for guiding stem cell fate. Here, sequential norbornene‐click chemistries are integrated to form synthetic, dynamically tunable PEG–peptide hydrogels for hiPSCs culture and differentiation. Specifically, hiPSCs are photoencapsulated in thiol–norbornene hydrogels crosslinked by multiarm PEG–norbornene (PEG–NB) and proteaselabile crosslinkers. These matrices are used to evaluate hiPSC growth under the influence of extracellular matrix properties. Tetrazine–norbornene (Tz–NB) click reaction is then employed to dynamically stiffen the cell‐laden hydrogels. Fast reactive Tz and its stable derivative methyltetrazine (mTz) are tethered to multiarm PEG, yielding mono‐functionalized PEG‐Tz, PEG‐mTz, and dualfunctionalized PEG‐Tz/mTz that react with PEG–NB to form additional crosslinks in the cell‐laden hydrogels. The versatility of Tz‐NB stiffening is demonstrated with different Tz‐modified macromers or by intermittent incubation of PEG‐Tz for temporal stiffening. Finally, the Tz–NB‐mediated dynamic stiffening is explored for 4D culture and definitive endoderm differentiation of hiPSCs. Overall, this dynamic hydrogel platform affords exquisite controls of hydrogel crosslinking for serving as a xeno‐free and dynamic stem cell niche.

    

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