In Situ Generation of Cell-Laden Porous MMP-Sensitive PEGDA Hydrogels by Gelatin Leaching (original) (raw)

Controlled Proteolytic Cleavage Site Presentation in Biomimetic PEGDA Hydrogels Enhances Neovascularization In Vitro

Tissue Engineering Part A, 2012

The volume of tissue that can be engineered is limited by the extent to which vascularization can be stimulated within the scaffold. The ability of a scaffold to induce vascularization is highly dependent on its rate of degradation. We present a novel approach for engineering poly (ethylene glycol) diacrylate (PEGDA) hydrogels with controlled protease-mediated degradation independent of alterations in hydrogel mechanical and physical properties. Matrix metalloproteinase (MMP)-sensitive peptides containing one (SSite) or three (TriSite) proteolytic cleavage sites were engineered and conjugated to PEGDA macromers followed by photopolymerization to form PEGDA hydrogels with tethered cell adhesion ligands of YRGDS and with either single or multiple MMPsensitive peptide domains between cross links. These hydrogels were investigated as provisional matrices for inducing neovascularization, while maintaining the structural integrity of the hydrogel network. We show that hydrogels made from SSite and TriSite peptide-containing PEGDA macromers polymerized under the same conditions do not result in alterations in hydrogel swelling, mesh size, or compressive modulus, but result in statistically different hydrogel degradation times with TriSite gels degrading in 1-3 h compared to 2-4 days in SSite gels. In both polymer types, increases in the PEGDA concentration result in decreases in hydrogel swelling and mesh size, and increases in the compressive modulus and degradation time. Furthermore, TriSite gels support vessel invasion over a 0.3-3.6 kPa range of compressive modulus, while SSite gels do not support invasion in hydrogels above compressive modulus values of 0.4 kPa. In vitro data demonstrate that TriSite gels result in enhanced vessel invasion areas by sevenfold and depth of invasion by twofold compared to SSite gels by 3 weeks. This approach allows for controlled, localized, and cell-mediated matrix remodeling and can be tailored to tissues that may require more rapid regeneration and neovascularization.

Controlled Proteolytic Cleavage Site Presentation in Biomimetic PEGDA Hydrogels Enhances Neovascularization In Vitro

Tissue Engineering Part A, 2012

Enhanced proteolytic degradation of molecularly engineered PEG hydrogels in response to MMP-1 and MMP-2

Biomaterials, 2010

Bioactive hydrogels formed by Michael-type addition reactions of end-functionalized poly(ethylene glycol) macromers with cysteine-containing peptides have been described as extracellular matrix mimetics and tissue engineering scaffolds. Although these materials have shown favorable behavior in vivo in tissue repair, we sought to develop materials formulations that would be more rapidly responsive to cell-induced enzymatic remodeling. In this study, protease-sensitive peptides that have increased k cat values were characterized and evaluated for their effects on gel degradability. Biochemical properties for soluble peptides and hydrogels were examined for matrix metalloproteinase (MMP)-1 and MMP-2. The most efficient peptide substrates in some cases overlap and in other cases differ between the two enzymes tested, and a range of k cat values was obtained. For each enzyme, hydrogels formed using the peptides with higher k cat values degraded faster than a reference with lower k cat . Fibroblasts showed increased cell spreading and proliferation when cultured in 3D hydrogels with faster degrading peptides, and more cell invasion from aortic ring segments embedded in the hydrogels was observed. These faster degrading gels should provide matrices that are easier for cells to remodel and lead to increased cellular infiltration and potentially more robust healing in vivo.

The role of pore size on vascularization and tissue remodeling in PEG hydrogels

Biomaterials, 2011

Vascularization is influenced by the physical architecture of a biomaterial. The relationship between pore size and vascularization has been examined for hydrophobic polymer foams, but there has been little research on tissue response in porous hydrogels. The goal of this study was to examine the role of pore size on vessel invasion in porous poly(ethylene glycol) (PEG) hydrogels. Vascularized tissue ingrowth was examined using three-dimensional cell culture and rodent models. In culture, all porous gels supported vascular invasion with the rate increasing with pore size. Following subfascia implantation, porous gels rapidly absorbed wound fluid, which promoted tissue ingrowth even in the absence of exogenous growth factors. Pore size influenced neovascularization, within the scaffolds and also the overall tissue response. Cell and vessel invasion into gels with pores 25e50 mm in size was limited to the external surface, while gels with pores larger pores (50e100 and 100e150 mm) permitted mature vascularized tissue formation throughout the entire material volume. A thin layer of inflammatory tissue was present at all PEG-tissue interfaces, effectively reducing the area available for tissue growth. These results show that porous PEG hydrogels can support extensive vascularized tissue formation, but the nature of the response depends on the pore size. Published by Elsevier Ltd.

Development of porous PEG hydrogels that enable efficient,

Acta Biomaterialia, 2009

Three-dimensional polymer scaffolds are useful culture systems for neural cell growth and can provide permissive substrates that support neural processes as they extend across lesions in the brain and spinal cord. Degradable poly(ethylene) glycol (PEG) gels have been identified as a particularly promising scaffold material for this purpose; however, process extension within PEG gels is limited to late stages of hydrogel degradation. Here we demonstrate that earlier process extension can be achieved from primary neural cells encapsulated within PEG gels by creating a network of interconnected pores thoughout the gel. Our method of incorporating these pores involves co-encapsulating a cell solution and a fibrin network within a PEG gel. The fibrin is subsequently enzymatically degraded under cytocompatible conditions, leaving behind a network of interconnected pores within the PEG gel. The primary neural cell population encapsulated in the gel is of mixed composition, containing differentiated neurons, and multipotent neuronal and glial precursor cells. We demonstrate that the initial presence of fibrin does not influence the cell-fate decisions of the encapsulated precursor cells. We also demonstrate that this fabrication approach enables simple, efficient and uniform seeding of viable cells throughout the entire porous scaffold. 2009 Acta Materialia Inc. Published by Elsevier Ltd. All rights reserved.

An in situ forming collagen–PEG hydrogel for tissue regeneration

Acta Biomaterialia, 2012

There are limited options for surgeons to repair simple or complex tissue defects due to injury, illness or disease. Consequently, there are few treatments for many serious ailments, including neural-related injuries, myocardial infarction and focal hyaline cartilage defects. Tissue-engineered scaffolds offer great promise for addressing these wide-ranging indications; however, there are many considerations that need to be made when conceptualizing a product. For many applications, an in situ forming scaffold that could completely fill defects with complex geometries, adhere to adjacent tissues and foster cell proliferation would be ideal. Additionally, the scaffold would preferably have tailored mechanical properties similar to native tissues and highly controllable gelation kinetics, and would not require an external trigger, such as ultraviolet light, for gelation. We have developed a unique injectable hydrogel system composed of collagen and multi-armed poly(ethylene glycol) (PEG) that meets all of these criteria. The collagen component enables cellular adhesion and permits enzymatic degradation, while the multiarmed PEG component has amine-reactive chemistry that also binds proteins/tissue and is hydrolytically degradable. We have characterized the mechanical properties, swelling, degradation rates and cytocompatibility of these novel hydrogels. The hydrogels demonstrated tunable mechanics, variable swelling and suitable degradation profiles. Cells adhered and proliferated to near confluence on the hydrogels over 7 days. These data suggest that these collagen and PEG hydrogels exhibit the mechanical, physical and biological properties suitable for use as an injectable tissue scaffold for the treatment of a variety of simple and complex tissue defects.

Molecularly Engineered PEG Hydrogels: A Novel Model System for Proteolytically Mediated Cell Migration

Biophysical Journal, 2005

Model systems mimicking the extracellular matrix (ECM) have greatly helped in quantifying cell migration in three dimensions and elucidated the molecular determinants of cellular motility in morphogenesis, regeneration, and disease progression. Here we tested the suitability of proteolytically degradable synthetic poly(ethylene glycol) (PEG)-based hydrogels as an ECM model system for cell migration research and compared this designer matrix with the two well-established ECM mimetics fibrin and collagen. Three-dimensional migration of dermal fibroblasts was quantified by time-lapse microscopy and automated single-cell tracking. A broadband matrix metalloproteinase (MMP) inhibitor and tumor necrosis factor-alpha, a potent MMP-inducer in fibroblasts, were used to alter MMP regulation. We demonstrate a high sensitivity of migration in synthetic networks to both MMP modulators: inhibition led to an almost complete suppression of migration in PEG hydrogels, whereas MMP upregulation increased the fraction of migrating cells significantly. Conversely, migration in collagen and fibrin proved to be less sensitive to the above MMP modulators, as their fibrillar architecture allowed for MMP-independent migration through preexisting pores. The possibility of molecularly recapitulating key functions of the natural extracellular microenvironment and the improved protease sensitivity makes PEG hydrogels an interesting model system that allows correlation between protease activity and cell migration.

Interpenetrating networks based on gelatin methacrylamide and PEG formed using concurrent thiol click chemistries for hydrogel tissue engineering scaffolds

Biomaterials, 2014

The integration of biological extracellular matrix (ECM) components and synthetic materials is a promising pathway to fabricate the next generation of hydrogel-based tissue scaffolds that more accurately emulate the microscale heterogeneity of natural ECM. We report the development of a bio/synthetic interpenetrating network (BioSIN x ), containing gelatin methacrylamide (GelMA) polymerized within a poly(ethylene glycol) (PEG) framework to form a mechanically robust network capable of supporting both internal cell encapsulation and surface cell adherence. The covalently crosslinked PEG network was formed by thiol-yne coupling, while the bioactive GelMA was integrated using a concurrent thiol-ene coupling reaction. The physical properties (i.e. swelling, modulus) of BioSIN x were compared to both PEG networks with physically-incorporated gelatin (BioSIN P ) and homogenous hydrogels. BioSIN x displayed superior physical properties and significantly lower gelatin dissolution. These benefits led to enhanced cytocompatibility for both cell adhesion and encapsulation; furthermore, the increased physical strength provided for the generation of a micro-engineered tissue scaffold. Endothelial cells showed extensive cytoplasmic spreading and the formation of cellular adhesion sites when cultured onto BioSIN x ; moreover, both encapsulated and adherent cells showed sustained viability and proliferation.

Recombinant Protein-co-PEG Networks as Cell-Adhesive and Proteolytically Degradable Hydrogel Matrixes. Part I: Development and Physicochemical Characteristics

Biomacromolecules, 2005

Toward the development of synthetic bioactive materials to support tissue repair, we present here the design, production, and characterization of genetically engineered protein polymers carrying specific key features of the natural extracellular matrix, as well as cross-linking with functionalized poly(ethylene glycol) (PEG) to form hybrid hydrogel networks. The repeating units of target recombinant protein polymers contain a cell-binding site for ligation of cell-surface integrin receptors and substrates for plasmin and matrix metalloproteinases (MMPs), proteases implicated in wound healing and tissue regeneration. Hydrogels were formed under physiological conditions via Michael-type conjugate addition of vinyl sulfone groups of endfunctionalized PEG with thiols of cysteine residues, representing designed chemical cross-linking sites within recombinant proteins. Cross-linking kinetics was shown to increase with the pH of precursor solutions. The elastic moduli (G′) and swelling ratios (Q m) of the resulting hydrogels could be varied as a function of the stoichiometry of the reacting groups and precursor concentration. Optima of G′ and Q m , maximum and minimum, respectively, were obtained at stoichiometry ratios r slightly in excess of 1 (r) cysteine/vinyl sulfone). The pool of technologies utilized here represents a promising approach for the development of artificial matrixes tailored for specific medical applications.

In Situ Generation of Cell-Laden Porous MMP-Sensitive PEGDA Hydrogels by Gelatin Leaching (original) (raw)

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