Modulus Of Hydrogels Research Articles

Influences of Coagulant Polarity on the Modulus of the Chitin Hydrogel.

The chitin hydrogel draws great attention in biomedical fields owing to its high similarity and good affinity for peptides. The conversion of raw chitin to the designed hydrogel through a sol-gel process prevails, while the modulus of the chitin hydrogel is significantly influenced by the factors of gelation technology (i.e., coagulation, involving polymer chain rearrangement and the reconstruction of multiple interactions). Water and several organic solvents such as ethanol, DMAc, and DMSO are effective coagulants for aqueous chitin/KOH/urea solutions. In particular, the concentration of aqueous ethanol solutions displays a high dependency on the modulus of chitin hydrogels. However, recent reports about chitin hydrogel fabrication seldom demonstrate the effect of coagulant factors on hydrogel performance. Our study found that the polarity of the coagulant and its diffusion index for entry into the chitin solution during the coagulation process had a direct influence on the hydrogel modulus. The influence of the two factors was investigated to find out their quantified relationship with the hydrogel modulus, which will inspire a practical method to develop new coagulants to prepare modulus-manipulable chitin hydrogels.

Frontal polymerization of acrylamide/GelMA/gelatin hydrogels with controlled mechanical properties and inherent self-recovery

Low mechanical resistance represents one of the significant problems of hydrogels, limiting their applicability in many fields. One approach to overcome this issue is synthesizing interpenetrating polymeric networks. In this work, the frontal polymerization technique was used to synthesize two series of novel hydrogels: (i) poly(acrylamide) (PAAm)-based hydrogels copolymerized/crosslinked with methacrylate gelatin (GelMA) (AAm-GelMA copolymer networks), and (ii) semi-IPN made of AAm-GelMA copolymer networks and a physically crosslinked gelatin network. With the final objective of improving the rheological, mechanical, morphological, thermal, and swelling properties of PAAm hydrogels, GelMA with two different degrees of methacrylation (30 and 75 mol%) was used. Interactions between GelMA chains, which give rise to physical network formation (i.e., GelMA-GelMA interactions), resulted in very efficient crosslinking for PAAm-based hydrogels, requiring a significantly lower methacrylic group concentration (0.04 mol%) for hydrogel formation compared to N,N′-methylene-bis-acrylamide (1 mol%), which is the agent typically used as a crosslinker for PAAm. Furthermore, the degree of GelMA methacrylation markedly affected the properties of the hydrogels. For example, regarding the swelling degree, hydrogels containing 22 wt% of GELMA30 had an SR% of 2870, while those containing the same amount of GELMA75 swelled much less (870 %). The introduction of gelatin as a secondary network in semi-IPNs influenced the rheological and mechanical properties, resulting in increased hydrogel modulus and stiffness attributed to enhanced physical interactions within the network. Finally, dynamic rheological shear strain and cyclic loading compression tests demonstrated exceptional recovery capabilities in all hydrogel formulations: samples subjected to alternating low (0.1 %) and high (300 % or 10 %) shear strain demonstrated a complete and prompt recovery of G′ and G″ values.

On the Relation between the Viscoelastic Properties of Granular Hydrogels and Their Performance as Support Materials in Embedded Bioprinting.

Granular hydrogels, formed by jamming microgels suspension, are promising materials for three-dimensional bioprinting applications. Despite their extensive use as support materials for embedded bioprinting, the influence of the particle's physical properties on the macroscale viscoelasticity on one hand and on the printing performance on the other hand remains unclear. Herein, we investigate the linear and nonlinear rheology of κ-carrageenan granular hydrogel through small- and large-amplitude oscillatory shear measurements. We tuned the granular hydrogel's properties by changing the stiffness (soft, medium, stiff) and the packing density of the individual microgels. Characterizations in the linear viscoelasticity regime revealed that the storage modulus of granular hydrogels is not a simple function of microgel stiffness and depends on the microgel packing density. At larger strains, increasing the microgel stiffness reduced the energy dissipation of the granular beds and increased the solid-fluid transition point. To understand how the different rheological properties of granular support materials influence embedded bioprinting, we examined the printing fidelity and cellular filament shrinkage within the granular beds. We found that microgels with low packing density diminished the printing quality, while stiff microgels promoted filament roughness. In addition, we found that highly packed stiff microgels significantly reduced the postprinting contraction of cellular filaments. Overall, this work provides a comprehensive knowledge of the rheology of granular hydrogels that can be used to rationally design support beds for bioprinting applications with specific characteristics.

Polyion Hydrogels of Polymeric and Nanofibrous Carboxymethyl Cellulose and Chitosan: Mechanical Characteristics and Potential Use in Environmental Remediation.

Recently, cellulose and other biomass nanofibers (NFs) have been increasingly utilized in the design of sustainable materials for environmental, biomedical, and other applications. However, the past literature lacks a comparison of the macromolecular and nanofibrous states of biopolymers in various materials, and the advantages and limitations of using nanofibers (NF) instead of conventional polymers are poorly understood. To address this question, hydrogels based on interpolyelectrolyte complexes (IPECs) between carboxymethyl cellulose nanofibers (CMCNFs) and chitosan (CS) were prepared by ele+ctrostatic cross-linking and compared with the hydrogels of carboxymethyl cellulose (CMC) and CS biopolymers. The presence of the rigid CMCNF altered the mechanism of the IPEC assembly and drastically affected the structure of IPEC hydrogels. The swelling ratios of CMCNF-CS hydrogels of ca. 40% were notably lower than the ca. 100-300% swelling of CMC-CS hydrogels. The rheological measurements revealed a higher storage modulus (G') of the CMCNF-CS hydrogel, reaching 13.3 kPa compared to only 3.5 kPa measured for the CMC-CS hydrogel. Further comparison of the adsorption characteristics of the CMCNF-CS and CMC-CS hydrogels toward Cu2+, Cd2+, and Hg2+ ions showed the slightly higher adsorption capacity of CMC-CS for Cu2+ but similar adsorption capacities for Cd2+ and Hg2+. The adsorption kinetics obeyed the pseudo-second-order adsorption model in both cases. Overall, while the replacement of CMC with CMCNF in hydrogel does not significantly affect the performance of such systems as adsorbents, CMCNF imparts IPEC hydrogel with higher stiffness and a frequency-independent loss (G″) modulus and suppresses the hydrogel swelling, so can be beneficial in practical applications that require stable performance under various dynamic conditions.

Molecular Chain Rearrangement-Induced In Situ Formation of Nanofibers for Improving the Strength and Toughness of Hydrogels.

Although poly(vinyl alcohol) (PVA) hydrogel has high elasticity and is suitable for cartilage tissue engineering, it is difficult to have both high strength and toughness. In this study, a simple and universal strategy is proposed to prepare strong and tough PVA hydrogels by in situ forming nanofibers on the original network structure induced by a molecular chain rearrangement. Quenching-tempering alteratively in ethanol and water several times is carried out to strengthen PVA hydrogels (PVA-Etn hydrogels) due to the advantages of noncovalent bonds in adjustability and reversibility. The results show that, after three quenching-tempering cycles, PVA-Et3 hydrogel with water content up to 79 wt % shows comprehensive improved mechanical properties. The compression modulus, tensile modulus, fracture strength, tensile strain, and tear energy of the PVA-Et3 hydrogel are 270, 250, 260, 130, and 180% of the initial PVA hydrogel, respectively. The improved mechanical properties of the PVA-Et3 hydrogel are attributed to the strong cross-linked PVA chains and hydrogen bond-reinforced nanofibers. This study not only provides a simple and efficient solution for the preparation of strong and tough polymer scaffolds in tissue engineering but also provides new insights for understanding the mechanism of improving the mechanical properties of polymer hydrogels by adjusting the molecular structure.

The effect of swelling/deswelling cycles on the mechanical behaviors of the polyacrylamide hydrogels

In practical applications, hydrogels experience swelling or deswelling in response to external stimuli, showcasing large deformation, tunable mechanical properties, and excellent biocompatibility. Previous studies focused on the effect of individual swelling or deswelling on the mechanical behaviors of hydrogels, neglecting the combined effects of both processes. The underlying mechanism of how the combined processes of swelling and deswelling affect the mechanical behaviors of hydrogels has not been systematically explored. To address this gap, polyacrylamide hydrogels with diverse initial compositions are prepared and subjected to controlled swelling-deswelling or deswelling-swelling cycles to achieve the same water content state. The mechanical properties of the hydrogel samples exposed to these cycles, including shear modulus, stretchability, Mullins effect, and fracture toughness, are experimentally evaluated and compared with those of as-prepared hydrogel samples without undergoing such cycles. Our findings reveal a significant reduction in stretchability, the Mullins effect, and fracture toughness of hydrogels exposed to either cycle. The extent of these reductions varies depending on the initial compositions of the hydrogels. This reduction in properties is primarily attributed to the rearrangement of hydrogel networks during these cycles, which becomes noticeable in hydrogels with network inhomogeneity. We also found that although the shear modulus of hydrogels varies after swelling-deswelling or deswelling-swelling cycles, it remains at relatively consistent levels compared to the as-prepared hydrogel. These findings suggest that the mechanical properties of hydrogels can be adjusted by optimizing the initial compositions and regulating the swelling-deswelling processing method. By studying the effects of swelling/deswelling cycles on the mechanical properties of hydrogels, we provide valuable insights for the application of hydrogels under dynamic environmental changes.

The effect of hemicelluloses on biosynthesis, structure and mechanical performance of bacterial cellulose-hemicellulose hydrogels

The primary plant cell wall (PCW) is a specialized structure composed predominantly of cellulose, hemicelluloses and pectin. While the role of cellulose and hemicelluloses in the formation of the PCW scaffold is undeniable, the mechanisms of how hemicelluloses determine the mechanical properties of PCW remain debatable. Thus, we produced bacterial cellulose–hemicellulose hydrogels as PCW analogues, incorporated with hemicelluloses. Next, we treated samples with hemicellulose degrading enzymes, and explored its structural and mechanical properties. As suggested, difference of hemicelluloses in structure and chemical composition resulted in a variety of the properties studied. By analyzing all the direct and indirect evidences we have found that glucomannan, xyloglucan and arabinoxylan increased the width of cellulose fibers both by hemicellulose surface deposition and fiber entrapment. Arabinoxylan increased stresses and moduli of the hydrogel by its reinforcing effect, while for xylan, increase in mechanical properties was determined by establishment of stiff cellulose–cellulose junctions. In contrast, increasing content of xyloglucan decreased stresses and moduli of hydrogel by its weak interactions with cellulose, while glucomannan altered cellulose network formation via surface deposition, decreasing its strength. The current results provide evidence for structure–dependent mechanisms of cellulose–hemicellulose interactions, suggesting the specific structural role of the latter.

Investigation of the effect of cefazolin drug on swelling and mechanical and thermal properties of polyacrylamide-hydrogels using molecular dynamics approach

Through molecular dynamics simulations, this study examined the interactions between water and cross-linked hydrogels, with a particular emphasis on the effect of cefazolin drug loading. The swelling percentage, ultimate strength, Young's modulus, heat flux, and thermal conductivity of polyacrylamide-based hydrogels were evaluated in relation to their respective drug concentrations (0 %, 3 %, 5 %, 15 %, and 30 %). The study results show that after 10 ns, the kinetic energy and total energy of atomic specimens stabilized at values of 12,532 and 12,488 kcal/mol, respectively. As the drug ratio increased from 0 to 15 %, the volume of polyacrylamide decreased from 342,722 to 302,583 ų, with further increased from 15 to 30 % reducing the volume to 298,562 ų due to pore and interatomic space closure by the drug. As the drug ratio increased from 0 to 3 %, the ultimate strength of the simulated structure slightly decreased from 0.0333 to 0.0332 MPa, then increased to 0.0333 MPa at a 5 % drug ratio, and remained constant beyond that. The heat flux value decreased from 1583 to 1563 W/m2 with a drug ratio increase from 0 to 3 %, but then increased from 1563 to 1585 W/m2 as the drug ratio further increased to 30 %. Increasing the drug ratio had no effect on the thermal properties of simulated structure, and the thermal conductivity remained constant at 0.57 W/m·K with increasing cefazolin dosage.

Bridge-rich and loop-less hydrogel networks through suppressed micellization of multiblock polyelectrolytes

Most triblock copolymer-based physical hydrogels form three-dimensional networks through micellar packing, and formation of polymer loops represents a topological defect that diminishes hydrogel elasticity. This effect can be mitigated by maximizing the fraction of elastically effective bridges in the hydrogel network. Herein, we report hydrogels constructed by complexing oppositely charged multiblock copolymers designed with a sequence pattern that maximizes the entropic and enthalpic penalty of micellization. These copolymers self-assemble into branched and bridge-rich network units (netmers), instead of forming sparsely interlinked micelles. We find that the storage modulus of the netmer-based hydrogel is 11.5 times higher than that of the micelle-based hydrogel. Complementary coarse grained molecular dynamics simulations reveal that in the netmer-based hydrogels, the numbers of charge-complexed nodes and mechanically reinforcing bridges increase substantially relative to micelle-based hydrogels.

Strong Acid Enabled Comprehensive Training of Poly (Sodium Acrylate) Hydrogel Networks.

The design of admirable hydrogel networks is of both practical and fundamental importance for diverse applications of hydrogels. Herein a general strategy of acid-assisted training is designed to enable multiple improvements of conventional poly (sodium acrylate) networks for hydrogels. Hydrophobic homogeneous crosslinked poly (sodium acrylate) hydrogels are prepared to verify the strategy. The multiple improvements of poly (sodium acrylate) networks are simply achieved by immersing the hydrogel networks into 4 M H2SO4 solutions. The introduced acids would induce transformation of poly (sodium acrylate) into poly (acrylic acid) at hydrogel surface, which constructs dynamic hydrogen bonding interactions to tighten the network. The acid-containing poly (sodium acrylate) hydrogels newly generate anti-swelling and self-healing performance, and show mechanical improvement. The internal poly (sodium acrylate) of the pristine acid-containing hydrogels is further fully transformed via acid-infiltration after following cyclic stretch/release training to significantly improve the mechanical performance. The Young's modulus, stress, and toughness of the fully-trained hydrogels are 187.6 times, 35.6 times, and 5.4 times enhanced, respectively. The polymeric networks retain isotropic in fully-trained hydrogels to ensure superior stretchability of 8.6. The acid-assisted training performance of the hydrogels can be reversibly recovered by NaOH neutralization. The acid-assisted training strategy here is general for poly (sodium acrylate) hydrogels.

Emulsion-Templated Gelatin/Amino Acids/Chitosan Macroporous Hydrogels with Adjustable Internal Dimensions for Three-Dimensional Stem Cell Culture.

The demand for macroporous hydrogel scaffolds with interconnected porous and open-pore structures is crucial for advancing research and development in cell culture and tissue regeneration. Existing techniques for creating 3D porous materials and controlling their porosity are currently constrained. This study introduces a novel approach for producing highly interconnected aspartic acid-gelatin macroporous hydrogels (MHs) with precisely defined open pore structures using a one-step emulsification polymerization method with surface-modified silica nanoparticles as Pickering stabilizers. Macroporous hydrogels offer adjustable pore size and pore throat size within the ranges of 50 to 130 μm and 15 to 27 μm, respectively, achieved through variations in oil-in-water ratio and solid content. The pore wall thickness of the macroporous hydrogel can be as thin as 3.37 μm and as thick as 6.7 μm. In addition, the storage modulus of the macroporous hydrogels can be as high as 7250 Pa, and it maintains an intact rate of more than 92% after being soaked in PBS for 60 days, which is also good performance for use as a biomedical scaffold material. These hydrogels supported the proliferation of human dental pulp stem cells (hDPSCs) over a 30 day incubation period, stretching the cell morphology and demonstrating excellent biocompatibility and cell adhesion. The combination of these desirable attributes makes them highly promising for applications in stem cell culture and tissue regeneration, underscoring their potential significance in advancing these fields.

Colloidal Probe Technique Optimization for Determination of Young's Modulus of Soft Adhesive Hydrogels.

Atomic force microscopy (AFM) is a valuable tool for determining the Young's modulus of a wide range of materials. However, it faces challenges, particularly when assessing adhesive materials like soft poly(N-isopropylacrylamide) (pNIPAM) hydrogels. This study focuses on enhancing the consistency and reliability of AFM measurements by functionally modifying AFM spherical tip cantilevers to address substrate adhesion issues with these hydrogels. Specifically, hydrophobic functionalization with 1H,1H,2H,2H-perfluorooctyltrichlorosilane (PFOCTS) emerged as the most effective approach, yielding consistent and reliable Young's modulus data across various pNIPAM hydrogel samples. This work highlights the importance of optimizing data acquisition in AFM, rather than relying on postprocessing, to reduce inconsistencies in Young's modulus assessment.

Effect of Compressive Modulus of Porous PVA Hydrogel Coating on the Preventing Adhesion of Polypropylene Mesh.

PP mesh is a widely used prosthetic material in hernia repair. However, visceral adhesion is one of the worst complications of this operation. Hence, an anti-adhesive PP mesh is developed by coating porous polyvinyl alcohol (PVA) hydrogel on PP surface via freezing-thawing process method. The compressive modulus of porous PVA hydrogel coating is first regulated by the addition of porogen sodium bicarbonate (NaHCO3) at various quality ratios with PVA. As expected, the porous hydrogel coating displayed modulus more closely resembling that of native abdominal wall tissue. In vitro tests demonstrate the modified PP mesh show superior coating stability, excellent hemocompatibility, and good cytocompatibility. In vivo experiments illustrate that PP mesh coated by the PVA4 hydrogel that mimicked the modulus of native abdominal wall could prevent adhesion effectively. Based on this, the rapamycin (RPM) is loaded into the porous PVA4 hydrogel coating to further improve anti-adhesive property of PP mesh. The Hematoxylin and eosin (H&E) and Masson trichrome (MT) staining results verified that the resulting mesh could alleviate the inflammation response and reduce the deposition of collagen around the implantation zone. The biomimetic mechanical property and anti-adhesive property of modified PP mesh make it a valuable candidate for application in hernioplasty.

Soft Polyethylene Glycol Hydrogels Support Human PSC Pluripotency and Morphogenesis.

Lumenogenesis within the epiblast represents a critical step in early human development, priming the embryo for future specification and patterning events. However, little is known about the specific mechanisms that drive this process due to the inability to study the early embryo in vivo. While human pluripotent stem cell (hPSC)-based models recapitulate many aspects of the human epiblast, most approaches for generating these 3D structures rely on ill-defined, reconstituted basement membrane matrices. Here, we designed synthetic, nonadhesive polyethylene glycol (PEG) hydrogel matrices to better understand the role of matrix mechanical cues in iPSC morphogenesis, specifically elastic modulus. First, we identified a narrow range of hydrogel moduli that were conducive to the hPSC viability, pluripotency, and differentiation. We then used this platform to investigate the effects of the hydrogel modulus on lumenogenesis, finding that matrices of intermediate stiffness yielded the most epiblast-like aggregates. Conversely, stiffer matrices impeded lumen formation and apico-basal polarization, while the softest matrices yielded polarized but aberrant structures. Our approach offers a simple, modular platform for modeling the human epiblast and investigating the role of matrix cues in its morphogenesis.

Fabrication and properties of hydrogel based on itaconic anhydride modified collagen

Based on the bioconjugation engineering, the structures and properties of collagen could be optimized, which is attractive for the development of novel collagen-based biomaterials. Here, itaconic anhydride was used to modify the amino groups in collagen to prepare the itaconic anhydride modified collagen (CITA) with different grafting density. The grafting density of CITAs was detected by TNBS assay. The integrity and thermostability of triple helical structure in CITAs were revealed by CD. Hydrophilicity of CITAs was studied by isoelectric point and water contact angles analysis. The concentration of CITA solution could be improved to 30 mg/mL under physiological environment. The hydrogelation of CITA was realized by photopolymerization, based on the introduction of double bonds. The storage modulus (G′) of CITA hydrogel could be improved to 680 Pa, compared with 67 Pa of Col hydrogel. The improved hemostasis property and antibacterial property of CITAs were confirmed, and CITAs also possessed good biocompatibility. This work provided a novel artificially modified collagen with optimized properties, which could be used for 3D bioprinting and fabrication of the in situ hemostatic hydrogel system.

Luteolin-incorporated fish collagen hydrogel scaffold: An effective drug delivery strategy for wound healing

In clinical practice, wound care has always been challenging. Hydrogels play a key role in facilitating active wound recovery by absorbing exudates, maintaining moisture, and alleviating pain through cooling. In this study, type I collagen was isolated from the skin of crucian carp (Carassius carassius) and verified by amino acid analysis, FTIR, and SDS-PAGE. By adopting a new approach, luteolin was added to collagen hydrogels in situ after being dissolved in an alkaline solution. XRD and SEM confirmed the luteolin was incorporated and entirely distributed throughout the hydrogel. The plastic compression improved the young's modulus of hydrogel to 15.24 ± 0.59 kPa, which is adequate for wound protection. The drug loading efficiency was 98 ± 1.47 % in the selected formulation. The luteolin-incorporated hydrogel enabled regulated drug release. We assessed the cytotoxicity using MTT and live-dead assays, as well as examined the hemocompatibility to determine the biocompatibility of the hydrogel. In vivo experiments showed that the hydrogel with luteolin had the highest wound closure rate (94.01 ± 2.1 %) and improved wound healing with granular tissue formation, collagen deposition, and re-epithelialization. These findings indicate that this efficient drug delivery technology can accelerate the process of wound healing.

Tuning Mechanical Characteristics and Permeability of Alginate Hydrogel by Polyvinyl Alcohol and Deep Eutectic Solvent Addition.

Alginate-based hydrogels are widely utilized for various applications, including enzyme immobilization and the development of drug delivery systems, owing to their advantageous characteristics, such as low toxicity, high availability and cost-effectiveness. However, the broad applicability of alginate hydrogels is hindered by their limited mechanical and chemical stability, as well as their poor permeability to hydrophobic molecules. In this study, we addressed the mechanical properties and chemical resistance of alginate hydrogels in a high-pKa environment by the copolymerization of alginate with polyvinyl alcohol (PVA). The addition of PVA resulted in a threefold improvement in the shear modulus of the copolymeric hydrogel, as well as enhanced chemical resistance to (S)-α-methylbenzylamine, a model molecule with a high pKa value. Furthermore, we addressed the permeability challenge by introducing a betaine-propylene glycol deep eutectic solvent (DES) into the PVA-alginate copolymer. This led to an increased permeability for ethyl 3-oxobutanoate, a model molecule used for bioreduction to chiral alcohols. Moreover, the addition of the DES resulted in a notable improvement of the shear modulus of the resulting hydrogel. This dual effect highlights the role of the DES in achieving the desired improvement of the hydrogel as an immobilization carrier.

Effect of carboxylated cellulose nanocrystals on konjac glucomannan/κ-carrageenan composite hydrogels

Konjac glucomannan/κ-carrageenan (KGM/KC) composite hydrogels often fail to meet industrial requirements due to their weak mechanical properties, while nanofillers are potential materials to address this challenge by taking advantage of their nano-size and filling effects. Herein, carboxylated cellulose nanocrystals (C–CNCs) were chosen as nanofillers to regulate the properties of KGM/KC composite hydrogels, with focus on the effect of C–CNCs concentration on the morphological and physicochemical properties. Meanwhile, an in-depth exploration of the possible mechanisms was also underlying. C–CNCs were well dispersed within the KGM/KC composite matrix, which positively enhanced the mechanical strength, as well as increased the apparent viscosity and modulus of the composite hydrogel greatly when the C–CNCs concentration was 10 % (w/w). This is mainly ascribed to the enhancement of hydrogen bond interaction among the KGM, KC, and C–CNCs, which were verified by Fourier transform infrared spectroscopy. Additionally, the results of low-field nuclear magnetic resonance confirmed the presence of C–CNCs in the hydrogel matrix reduced the water mobility of the hydrogel, which improved the freeze-thaw stability of the composite hydrogel. The fitting of the Power law model (R2 > 0.98) showed that the swelling mechanism of KGM/KC composite hydrogels belonged to Fickian diffusion, and the swelling behavior could be regulated by adjusting the C–CNCs concentration. However, the excessive C–CNCs might weakened the interaction of composite hydrogels, which partially explains the reversal of the reinforcement effects seen at the lower additions of C–CNCs inclusion. These results provide a basis for the development and design of KGM/KC-based products with desirable attributes.

Interaction mechanism and binding mode between different polyphenols and gellan gum

To investigate the impact of different polyphenols on the gel properties of gellan gum (GG) and the interaction mechanism, experiments and virtual molecular simulations were conducted based on nine representative polyphenols. Rheological analysis revealed that all the GG/polyphenol composite hydrogels were pseudoplastic fluids with a low viscosity. The storage modulus (G′) of hydrogel containing only GG was 28.3 Pa at 0.1 Hz. The addition of gallic acid (GA), puerarin (PUE) or cyanidin cation (CC) significantly increased the G′ of the hydrogel by 4.9-fold, 3.3-fold, and 2.6-fold, respectively. The introduction of GA reduced the water holding capacity (WHC) of the hydrogel to 62.0 %, while the other eight polyphenols increased the WHC to nearly 100 %. Regular, intact and dense honeycomb mesh structures were observed in the GG/GA, GG/PUE, GG/CC and GG/catechin microstructures. The molecular docking results indicated that, among the nine polyphenols, PUE had the strongest affinity for GG with an interaction energy of −18.64 kcal/mol. According to the results of molecular dynamics simulation, the total energy of the composite system interacting with water corresponded well with the G′ of the composite hydrogels. The GG/GA system with the highest G′ had the lowest total energy of −15655.82 kJ/mol. Hydrogen bonds were the main driving force for improving the strength and maintaining the structural stability of the composite hydrogels. Therefore, this study confirmed the various effects of nine polyphenols on GG hydrogels and provided a novel basis for investigating the synthesis and gelation mechanism of polysaccharide-polyphenol composite hydrogels.

Abstract 305: Bioinspired synthetic hydrogel in pancreatic cancer organoid matrix modeling

Abstract Background: Pancreatic ductal adenocarcinoma (PDAC) is a leading cause of cancer mortality with a primary hallmark, including dense collagen matrix in the desmoplastic stroma. Organoid technologies often rely on commercially available EHS mouse sarcoma matrix materials, and it remains uncertain how batch-to-batch variability of this matrix impacts the consistency of cancer signaling. Here, we present a novel photo-activated hydrogel tuned to the properties of the desmoplastic stroma in PDAC organoid cultures. Method: We designed multiple synthetic hydrogel materials with tunable mechanical properties, including SP-139 (Stem Pharm, Inc), a polyethylene glycol-based hydrogel functionalized with norbornene and formed with both degradable and non-degradable crosslinking peptides and a cell adhesion peptide (CRGDS). We used rheometry to measure the elastic modulus of the polymerized hydrogel after visible light photoactivation (395 nm) and expanded multiple cancer organoid cultures. RNAseq was performed from patient-derived xenografts to expanded organoids across matrix designs (Cultrex® v. SP-139) and analyzed by GSVA pathway analyses. Result: We optimized the ratio of non-degradable v. degradable crosslinking peptide to support culture expansion and enzymatic digestion with dispase II (125 µg/mL) and collagenase II (1 mg/mL). Using rheometry, SP-139 at 75% v/v had increased elastic modulus versus Cultrex RGF BME matrix Type 2 at 100% v/v (4992±76.3 v. 68.4±5.6 Pa, p<0.0001). Phenotypic growth was confirmed across serial passages (>8) and a diversity of gastrointestinal cancer types (n=5). Baseline growth rates were identical over 48h between SP-139 (75% v/v) and Cultrex (50% v/v) (+13.4% v. +13.0, p=0.75). Growth remained consistent for SP-139 yet increased with Cultrex at interval of 48-96h (+12.9% SP-139 v +22.4% Cultrex, p<0.005) and interval of 96-144h (+13.6% SP-139 v +24.0% Cultrex®, p<0.0001). Therapeutic response was assessed using 3D CellTiter-Glo® using gemcitabine 100 µM (24h) with comparable inhibition of normalized cell viability in SP-139 v. Cultrex® (35.4±1.9% v. 52.3±6.5%, n.s.) and qualitatively with viability staining using calcein AM and Caspase 3/7FITC. RNAseq revealed Cultrex, when compared to SP-139, yielded down regulation of epoxygenase p450 pathways (padj<0.012) and negative regulation of the p38 MAP kinase cascade (padj<0.048). Conclusions: Functionalized PEG-based synthetic hydrogel matrix materials can be tuned for physical properties to mimic cancer tissue microenvironments more accurately. SP-139, designed to mimic the desmoplastic stroma of the pancreatic cancer microenvironment, has favorable properties including controlled growth rates and compatibility with high content imaging by luminescence and fluorescence. RNAseq pathway analysis shows SP-139 maintains pathways of p450 and MAP kinase signaling of importance with therapeutic resistance. Citation Format: Md Shahadat Hossan, Austin Stram, Ethan Samuel Lin, Sean McIlwain, Connie Lebakken, William Richards, Jeremy D. Kratz. Bioinspired synthetic hydrogel in pancreatic cancer organoid matrix modeling [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2024; Part 1 (Regular Abstracts); 2024 Apr 5-10; San Diego, CA. Philadelphia (PA): AACR; Cancer Res 2024;84(6_Suppl):Abstract nr 305.