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1. Development and characterization of Factor Xa ‐responsive materials for applications in cell culture and biologics delivery

   https://doi.org/10.1002/jbm.a.37513  

   Doron, Gilad; Pearson, Joseph J; Guldberg, Robert E; Temenoff, Johnna S (May 2023, Journal of Biomedical Materials Research Part A)

   Abstract Stimuli–responsive biomaterials may be used to better control the release of bioactive molecules or cells for applications involving drug delivery and controlled cell release. In this study, we developed a Factor Xa (FXa)‐responsive biomaterial capable of controlled release of pharmaceutical agents and cells from in vitro culture. FXa‐cleavable substrates were formed as hydrogels that degraded in response to FXa enzyme over several hours. Hydrogels were shown to release both heparin and a model protein in response to FXa. Additionally, RGD‐functionalized FXa‐degradable hydrogels were used to culture mesenchymal stromal cells (MSCs), enabling FXa‐mediated cell dissociation from hydrogels in a manner that preserved multicellular structures. Harvesting MSCs using FXa‐mediated dissociation did not influence their differentiation capacity or indoleamine 2,3‐dioxygenase (IDO) activity (a measure of immunomodulatory capacity). In all, this FXa‐degradable hydrogel is a novel responsive biomaterial system that may be used for on‐demand drug delivery, as well as for improving processes for in vitro culture of therapeutic cells. 

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2. Bioactive Polyurethane–Poly(ethylene Glycol) Diacrylate Hydrogels for Applications in Tissue Engineering

   https://doi.org/10.3390/gels10020108  

   Yuan, Yixuan; Tyson, Caleb; Szyniec, Annika; Agro, Samuel; Tavakol, Tara N.; Harmon, Alexander; Lampkins, DessaRae; Pearson, Lauran; Dumas, Jerald E.; Taite, Lakeshia J. (February 2024, Gels)

   Polyurethanes (PUs) are a highly adaptable class of biomaterials that are among some of the most researched materials for various biomedical applications. However, engineered tissue scaffolds composed of PU have not found their way into clinical application, mainly due to the difficulty of balancing the control of material properties with the desired cellular response. A simple method for the synthesis of tunable bioactive poly(ethylene glycol) diacrylate (PEGDA) hydrogels containing photocurable PU is described. These hydrogels may be modified with PEGylated peptides or proteins to impart variable biological functions, and the mechanical properties of the hydrogels can be tuned based on the ratios of PU and PEGDA. Studies with human cells revealed that PU–PEG blended hydrogels support cell adhesion and viability when cell adhesion peptides are crosslinked within the hydrogel matrix. These hydrogels represent a unique and highly tailorable system for synthesizing PU-based synthetic extracellular matrices for tissue engineering applications. 

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3. Biocompatible Polyglycidol-based hydrogels for load-bearing tissue engineering

   Beezer, Dain; Harth, Eva (March 2024, SciMeetings, A product from ACS Publications)

   The post-polymerization modification of polyglycidol is of great interest for the synthesis of functional polyether-based polymeric biomaterials. We present a degradable polyglycidol-based hydrogel system using oxime click chemistry by employing a ketone-functionalized and an amino-oxy functionalized branched polyglycidol. Ratio-controlled amino-oxy functionalized species were obtained by controlling the ratio of N-hydroxy phthalimide to the hydroxyl groups attached to the polyether backbone. A similar strategy was utilized to obtain ratio-controlled keto functionalized branched polyglycidols. This unique feature will allow for the tailoring of this branched PEG-like structural motif for the synthesis of novel biomaterials with tailored biochemical and biomechanical properties. The bio-orthogonal nature of this crosslinking reaction makes these hydrogels an attractive option for load-bearing tissue engineering. Our hydrogel synthesis methodology allows for control over the properties of the resulting polymeric network, based upon the ratio between the keto and the amino-oxy functionalities. The potential of these polyether-based networks to serve as a successful delivery platform was assessed by studying their swelling and degradation profiles. Biocompatibility and cytotoxicity of the gels were studied using NIH 3T3 cells. Our preliminary results highlighting the potential of our hydrogels platform will be discussed. 

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4. Finding the sweet spot: a library of hydrogels with tunable degradation for tissue model development

   https://doi.org/10.1039/d1tb02436a  

   Pandala, Narendra; LaScola, Michael A.; Hinton, Zachary; Korley, La Shanda; Lavik, Erin (March 2022, Journal of Materials Chemistry B)

   In vitro models are valuable tools for applications including understanding cellular mechanisms and drug screening. Hydrogel biomaterials facilitate in vitro models by mimicking the extracellular matrix and in vivo microenvironment. However, it can be challenging for cells to form tissues in hydrogels that do not degrade. In contrast, if hydrogels degrade too much or too quickly, tissue models may be difficult to assess in a high throughput manner. In this paper, we present a poly(allylamine) (PAA) based synthetic hydrogel system which can be tuned to control the mechanical and chemical cues provided by the hydrogel scaffold. PAA is a polycation with several biomedical applications, including the delivery of small molecules, nucleic acids, and proteins. Based on PAA and poly(ethylene glycol) (PEG), we developed a synthetic non-degradable system with potential applications for long-term cultures. We then created a second set of gels that combined PAA with poly- l -lysine (PLL) to generate a library of semi-degradable gels with unique degradation kinetics. In this work, we present the hydrogel systems’ synthesis, characterization, and degradation profiles along with cellular data demonstrating that a subset of gels supports the formation of endothelial cell cord-like structures. 

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5. Bacteria encapsulation into polyethylene glycol hydrogels using Michael-type addition reactions

   https://doi.org/10.1557/s43580-024-00940-y  

   Gutierrez, Moises M; Reed, Jeffrey A; McElroy, Robby A; Hansen, Ryan R (October 2024, MRS Advances)

   Abstract Hydrogel materials can be used to integrate bacteria cells into biohybrid systems. Here, we investigate the use of polyethylene glycol-based hydrogels that employ different Michael-type addition crosslinking chemistries, including thiol-acrylate, thiol-vinyl sulfone, and thiol-maleimide click reactions, for covalent hydrogel network formation and bacteria encapsulation. All crosslinking chemistries generated hydrogels that provided stable encapsulation and culture ofBacillus subtilis; however, significant differences in cell viability and cell morphology after encapsulation were identified. Thiol-acrylate hydrogels provided the highest cell viability and favored encapsulation of single cells, while thiol-maleimide hydrogels had the lowest cell viability and favored encapsulation of larger aggregates. These findings demonstrate the impact of crosslinking strategies for encapsulation of microorganisms into hydrogel networks and suggest that thiol-acrylate chemistries are favorable for many applications. Graphical abstract 

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