Abstract 3459: Patient derived gliomaspheres exhibit HA concentration dependent invasiveness in 3D hydrogels
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Abstract Hyaluronic acid (HA) is a highly abundant glycosaminoglycan within the central nervous system. In glioblastoma (GBM), interactions with HA mediate tumor cell invasion. An improved knowledge of the biological underpinnings of HA-dependent GBM cell migration can facilitate the development of efficacious therapeutics. To better study how HA in the tumor matrix affects invasion, we have developed a tunable, 3D culture system in which to study gliomaspheres (GSs) of patient-derived tumor cells. Photopolymerization (365 nm for 15 seconds) of GSs suspended in a solution 0.025 w/v% lithium phenyl-2,4,6-trimethylbenzoylphosphinate (LAP), thiolated 4-arm poly-ethylene glycol (20 kDa, Laysan Bio), 8-arm poly-ethylene glycol-norbornene (20 kDa, Laysan Bio), thiolated peptides containing an ‘RGD’ amino acid motif, and either 0.10, 0.25, 0.50, or 0.75 w/v% of thiolated HA (700 kDa average molecular weight, Lifecore Biomedical) yielded 3D hydrogels of varying HA concentrations and similar mechanical properties. Relative invasive capacity, quantified by shape factor (deviation from circularity) and migration length (maximum extension length of processes from the GS periphery), differed across patient lines and was independent of their Cancer Genome Atlas (TCGA) classification as either mesenchymal or proneural. Hydrogels with higher amounts of HA (>0.25% w/v) generally enhanced invasion as compared to low HA (0.10 w/v%) hydrogels. In certain cell lines, a biphasic relationship between HA concentration and migration was observed, in line with previous reports of CD44 expression and migration. Moreover, inhibition of the CD44-Ezrin-Actin axis, using NSC668394, reduced migratory activity in hydrogels with higher HA (>0.25% w/v), while slightly increasing invasion in hydrogels with low HA (0.10 w/v%). In sum, results demonstrate the use of a matrix-mimetic, 3D hydrogel system in which to study GBM invasion through the local extracellular matrix. Citation Format: Gevick Safarians, Itay Solomon, Alireza Sohrabi, Stephanie Seidlits. Patient derived gliomaspheres exhibit HA concentration dependent invasiveness in 3D hydrogels [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2022; 2022 Apr 8-13. Philadelphia (PA): AACR; Cancer Res 2022;82(12_Suppl):Abstract nr 3459.The relatively weak mechanical properties of hydrogels remain a major drawback for their application as load-bearing tissue scaffolds. Previously, we developed cell-laden double-network (DN) hydrogels that were composed of photocrosslinkable gellan gum (GG) and gelatin. Further research into the materials as tissue scaffolds determined that the strength of the DN hydrogels decreased when they were prepared at cell-compatible conditions, and the encapsulated cells in the DN hydrogels did not function as well as they did in gelatin hydrogels. In this work, we developed microgel-reinforced (MR) hydrogels from the same two polymers, which have better mechanical strength and biological properties in comparison to the DN hydrogels. The MR hydrogels were prepared by incorporating stiff GG microgels into soft and ductile gelatin hydrogels. The MR hydrogels prepared at cell-compatible conditions exhibited higher strength than the DN hydrogels and the gelatin hydrogels, the highest strength being 2.8 times that of the gelatin hydrogels. MC3T3-E1 preosteoblasts encapsulated in MR hydrogels exhibited as high metabolic activity as in gelatin hydrogels, which is significantly higher than that in the DN hydrogels. The measurement of alkaline phosphatase (ALP) activity and the amount of mineralization showed that osteogenic behavior of MC3T3-E1 cells was as much facilitated in the MR hydrogels as in the gelatin hydrogels, while it was not as much facilitated in the DN hydrogels. These results suggest that the MR hydrogels could be a better alternative to the DN hydrogels and have great potential as load-bearing tissue scaffolds.
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This minireview discusses the advantages and challenges in constructing bioinspired double-network hydrogels mimicking the structure and/or properties of biological tissue.
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Research on hydrogels has been geared toward biomedical applications from the beginning due to their relatively high biocompatibility. Initially only the hydrophilic nature and the large swelling properties of hydrogels was explored. Continued research on hydrogels has resulted in the development of new types of hydrogels, such as environment-sensitive hydrogels, thermoplastic hydrogels, hydrogel foams, and sol-gel phase-reversible hydrogels. Application of hydrogels ranges from biomedical devices to solute separation. Examples of hydrogel applications in pharmaceutics, biomaterials, and biotechnology are briefly described.
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The relatively weak mechanical properties of hydrogels remain a major drawback for their application as load-bearing tissue scaffolds. Previously, we developed cell-laden double-network (DN) hydrogels that were composed of photocrosslinkable gellan gum (GG) and gelatin. Further research into the materials as tissue scaffolds determined that the strength of the DN hydrogels decreased when they were prepared at cell-compatible conditions, and the encapsulated cells in the DN hydrogels did not function as well as they did in gelatin hydrogels. In this work, we developed microgel-reinforced (MR) hydrogels from the same two polymers, which have better mechanical strength and biological properties in comparison to the DN hydrogels. The MR hydrogels were prepared by incorporating stiff GG microgels into soft and ductile gelatin hydrogels. The MR hydrogels prepared at cell-compatible conditions exhibited higher strength than the DN hydrogels and the gelatin hydrogels, the highest strength being 2.8 times that of the gelatin hydrogels. MC3T3-E1 preosteoblasts encapsulated in MR hydrogels exhibited as high metabolic activity as in gelatin hydrogels, which is significantly higher than that in the DN hydrogels. The measurement of alkaline phosphatase (ALP) activity and the amount of mineralization showed that osteogenic behavior of MC3T3-E1 cells was as much facilitated in the MR hydrogels as in the gelatin hydrogels, while it was not as much facilitated in the DN hydrogels. These results suggest that the MR hydrogels could be a better alternative to the DN hydrogels and have great potential as load-bearing tissue scaffolds.
Gelatin
Gellan gum
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Research on hydrogels has been geared toward biomedical applications from the beginning due to their relatively high biocompatibility. Initially only the hydrophilic nature and the large swelling properties of hydrogels was explored. Continued research on hydrogels has resulted in the development of new types of hydrogels, such as environment-sensitive hydrogels, thermoplastic hydrogels, hydrogel foams, and sol-gel phase-reversible hydrogels. Application of hydrogels ranges from biomedical devices to solute separation. Examples of hydrogel applications in pharmaceutics, biomaterials, and biotechnology are briefly described.
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Hydrogels are there-dimensional polymer network in which the voids are filled with water.Hydrogels have been widely used in various fields including biomedical engineering.However,they have very limited applicability due to their poor mechanical strength.Therefore,many efforts have been focused on the enhancement of mechanical properties of hydrogels.This review mainly introduces some novel high strength hydrogels,such as slide-ring hydrogels,double network hydrogels,composite hydrogels and others and analyzes the factors affecting mechanical properties of hydrogels.Biocompatible,degradable,injectable,loading growth factor and high strength hydrogels as major research directions.
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