Gelatin-Based Matrices as a Tunable Platform To Study in Vitro and in Vivo 3D Cell Invasion (original) (raw)
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3D cell entrapment in crosslinked thiolated gelatin-poly(ethylene glycol) diacrylate hydrogels
Biomaterials, 2012
The combined use of natural ECM components and synthetic materials offers an attractive alternative to fabricate hydrogel-based tissue engineering scaffolds to study cell-matrix interactions in three-dimensions (3D). A facile method was developed to modify gelatin with cysteine via a bifunctional PEG linker, thus introducing free thiol groups to gelatin chains. A covalently crosslinked gelatin hydrogel was fabricated using thiolated gelatin and poly(ethylene glycol) diacrylate (PEGdA) via thiol-ene reaction. Unmodified gelatin was physically incorporated in a PEGdA-only matrix for comparison. We sought to understand the effect of crosslinking modality on hydrogel physicochemical properties and the impact on 3D cell entrapment. Compared to physically incorporated gelatin hydrogels, covalently crosslinked gelatin hydrogels displayed higher maximum weight swelling ratio (Q max ), higher water content, significantly lower cumulative gelatin dissolution up to 7 days, and lower gel stiffness. Furthermore, fibroblasts encapsulated within covalently crosslinked gelatin hydrogels showed extensive cytoplasmic spreading and the formation of cellular networks over 28 days. In contrast, fibroblasts encapsulated in the physically incorporated gelatin hydrogels remained spheroidal. Hence, crosslinking ECM protein with synthetic matrix creates a stable scaffold with tunable mechanical properties and with long-term cell anchorage points, thus supporting cell attachment and growth in the 3D environment.
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Acta Biomaterialia, 2014
Modern cancer research requires physiological, three-dimensional (3-D) cell culture platforms, wherein the physical and chemical characteristics of the extracellular matrix (ECM) can be modified. In this study, gelatine methacrylamide (GelMA)-based hydrogels were characterized and established as in vitro and in vivo spheroid-based models for ovarian cancer, reflecting the advanced disease stage of patients, with accumulation of multicellular spheroids in the tumour fluid (ascites). Polymer concentration (2.5-7% w/ v) strongly influenced hydrogel stiffness (0.5 ± 0.2 kPa to 9.0 ± 1.8 kPa) but had little effect on solute diffusion. The diffusion coefficient of 70 kDa fluorescein isothiocyanate (FITC)-labelled dextran in 7% GelMA-based hydrogels was only 2.3 times slower compared to water. Hydrogels of medium concentration (5% w/v GelMA) and stiffness (3.4 kPa) allowed spheroid formation and high proliferation and metabolic rates. The inhibition of matrix metalloproteinases and consequently ECM degradability reduced spheroid formation and proliferation rates. The incorporation of the ECM components laminin-411 and hyaluronic acid further stimulated spheroid growth within GelMA-based hydrogels. The feasibility of pre-cultured GelMA-based hydrogels as spheroid carriers within an ovarian cancer animal model was proven and led to tumour development and metastasis. These tumours were sensitive to treatment with the anti-cancer drug paclitaxel, but not the integrin antagonist ATN-161. While paclitaxel and its combination with ATN-161 resulted in a treatment response of 33-37.8%, ATN-161 alone had no effect on tumour growth and peritoneal spread. The semi-synthetic biomaterial GelMA combines relevant natural cues with tunable properties, providing an alternative, bioengineered 3-D cancer cell culture in in vitro and in vivo model systems.
Scientific reports, 2018
Purpose of this study was the development of a 3D material to be used as substrate for breast cancer cell culture. We developed composite gels constituted by different concentrations of Alginate (A) and Matrigel (M) to obtain a structurally stable-in-time and biologically active substrate. Human aggressive breast cancer cells (i.e. MDA-MB-231) were cultured within the gels. Known the link between cell morphology and malignancy, cells were morphologically characterized and their invasiveness correlated through an innovative bioreactor-based invasion assay. A particular type of gel (i.e. 50% Alginate, 50% Matrigel) emerged thanks to a series of significant results: 1. cells exhibited peculiar cytoskeleton shapes and nuclear fragmentation characteristic of their malignancy; 2. cells expressed the formation of the so-called invadopodia, actin-based protrusion of the plasma membrane through which cells anchor to the extracellular matrix; 3. cells were able to migrate through the gels and...
The Use of Hydrogels as Biomimetic Materials for 3D Cell Cultures
Australian Journal of Chemistry, 2017
With the recent developments in cell cultures and biomimetic materials, there is growing evidence indicating that long-established two-dimensional (2D) cell culture techniques are slowly being phased out and replaced with three-dimensional (3D) cell cultures. This is due to the 3D cell cultures better mimicking the natural extracellular matrix (ECM) where cells are found. The emergence of self-assembled hydrogels as an ECM mimic has revolutionised the field owing to their ability to closely simulate the fibrous nature of the ECM. Here, we review recent progress in using hydrogels as biomimetic materials in 3D cell cultures, particularly supramolecular peptide hydrogels. With greater comprehension of the behaviour of cells in these hydrogels, a cell culture system that can be used in a wide array of 3D culture-based applications can be developed.
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Three-dimensional (3D) cell culture systems mimic the structural complexity of the tissue microenvironment that includes the extracellular matrix (ECM) in addition to the cellular components Thus, 3D culture systems are increasingly important as they resemble the ECM-cell and cell-cell physical interactions occurring in vivo. So far, several scaffold-based culture systems and techniques have been proposed as valuable approaches for large-scale production of spheroids, but often suffering of poor reproducible conditions or high costs of production. In this work we present a reliable 3D culture system based on collagen I-blended agarose hydrogels and show how the variation of the agarose weight percentage affects the physical and mechanical properties of the resulting hydrogel, being that with a lower amount of agarose more permeable, softer and more prone to degradation compared to hydrogels with higher agarose concentrations. We have also evaluated the effect of the different physic...
Hydrogels as extracellular matrix mimics for 3D cell culture
Biotechnology and Bioengineering, 2009
Methods for culturing mammalian cells ex vivo are increasingly needed to study cell and tissue physiology and to grow replacement tissue for regenerative medicine. Two-dimensional culture has been the paradigm for typical in vitro cell culture; however, it has been demonstrated that cells behave more natively when cultured in three-dimensional environments. Permissive, synthetic hydrogels and promoting, natural hydrogels have become popular as three-dimensional cell culture platforms; yet, both of these systems possess limitations. In this perspective, we discuss the use of both synthetic and natural hydrogels as scaffolds for three-dimensional cell culture as well as synthetic hydrogels that incorporate sophisticated biochemical and mechanical cues as mimics of the native extracellular matrix. Ultimately, advances in synthetic-biologic hydrogel hybrids are needed to provide robust platforms for investigating cell physiology and fabricating tissue outside of the organism.
bioRxiv (Cold Spring Harbor Laboratory), 2023
The study of in vitro models of breast cancer is crucial for understanding and treating the malignancy in patients, with 3D in vitro models providing researchers with more biomimetic systems to overcome limitations of current to 2D cultures and in vivo animal models. Ex vivo patient tissues have shown that malignant breast tissues are stiffer than healthy or benign tissues, and that the stiffness corresponds with increasing tumour grade. Stiffening of the breast tumour environment alters tumour cell phenotype and facilitates tumour progression, invasion and metastasis. Better understanding of the relationship between extracellular matrix stiffness and breast cancer cell phenotype, and how that is important in the initiation of metastasis, should lead to designing 3D models that mimic the breast tumour microenvironment at different stages of breast cancer progression. This study investigated phenotypic response of two breast cancer cell lines that are representative of clinical breast cancer subtypes (MCF7, Luminal A; MDA-MB-231, Triple Negative Breast Cancer) in gelatin-methacryloyl (GelMA) hydrogels of varying stiffness. A visible light photoinitiation system was adopted to provide a tuneable photocrosslinking platform to systematically control hydrogel stiffness and tumour microenvironment. This allowed rapid fabrication of biocompatible hydrogels supporting high cell viability over longterm culture. The impact of a clinically relevant range of microenvironmental stiffness on breast cancer cell behaviour and phenotype was examined over a 21-day culture period using GelMA hydrogels. Results showed that MCF7 cells cultured for 21 days in high stiffness hydrogels (10 wt%; 28 kPa) responded by downregulating the epithelial marker E-cadherin and upregulating mesenchymal markers N-cadherin and Vimentin, whereas MDA-MB-231 cells showed no changes in EMT-markers when cultured in hydrogels of corresponding stiffness (10 wt%; 33 kPa). Culturing both cell lines in soft hydrogels (5 wt%; 11 kPa) maintained their phenotype over 21 days, highlighting the importance of controlling hydrogel mechanical properties when studying breast cancer cell phenotype.
Macromolecular Research
An emerging trend in cancer research is to develop engineered tumor models using bio-inspired biomaterials that can mimic the native tumor microenvironment. Although various bio-inspired hydrogels have been utilized, it is still challenging to develop advanced polymeric hydrogel materials that can more accurately reconstruct critical aspects of the native tumor microenvironment. Herein, we present interpenetrating polymer network (IPN) hydrogels composed of thiolated gelatin and tyramine-conjugated poly(ethylene glycol), which form IPN hydrogels via horseradish peroxidase-mediated dual cross-linking reactions. We demonstrate that the IPN hydrogels exhibit independently controllable physicochemical properties. Also, the IPN hydrogels show resistance to the proteolytic enzymes and cytocompatibility for long-term culture of human fibrosarcoma (HT1080) cells. Moreover, we utilize the engineered tumor construct as a platform to evaluate the effect of matrix stiffness on cancer cell proliferation and drug resistance against the anticancer drug 5-fluorouracil as a model drug. In conclusion, we suggest that our IPN hydrogel is a promising material to study cancer biology and to screen innovative therapeutic agents for better clinical outcomes.
Microstructures in 3D Biological Gels Affect Cell Proliferation
Tissue Engineering, 2007
Controlling the microscale environment in 3D matrices for tissue engineering applications is a challenging but necessary goal. In this work, the effect of discrete microscale structures (microrods) on cell proliferation was assessed in three dimensional gels. Microrods were fabricated out of SU-8 with dimensions of 100 by 15 by 15 microns (LxHxW) and incorporated into matrigel seeded with fibroblasts. The 3D microrod-Matrigel composite system inhibited proliferation of both primary and cell-line fibroblasts compared to cells seeded in matrigel alone.
Langmuir : the ACS journal of surfaces and colloids, 2015
The design of scaffolds which mimic the stiffness, nanofiber structure, and biochemistry of the native extracellular matrix (ECM) has been a major objective for the tissue engineering field. Furthermore, mimicking the innate three-dimensional (3D) environment of the ECM has been shown to significantly altered cellular response compared to that of traditional two-dimensional (2D) culture. We report the development of a self-assembling, fibronectin-mimetic, peptide-amphiphile nanofiber scaffold for 3D cell culture. To form such a scaffold, 5 mol % of a bioactive PR_g fibronectin-mimetic peptide-amphiphile was mixed with 95 mol % of a diluent peptide-amphiphile (E2) whose purpose was to neutralize electrostatic interactions, increase the gelation kinetics, and promote cell survival. Atomic force microscopy verified the fibrilar structure of the gels, and the mechanical properties were characterized for various weight percent (wt %) formulations of the 5 mol % PR_g-95 mol % E2 peptide-a...