Hydrogels for the repair of articular cartilage defects

The repair of articular cartilage defects remains a significant challenge in orthopedic medicine. Hydrogels, three-dimensional polymer networks swollen in water, offer a unique opportunity to generate a functional cartilage substitute. Hydrogels can exhibit similar mechanical, swelling, and lubricating behavior to articular cartilage, and promote the chondrogenic phenotype by encapsulated cells. Hydrogels have been prepared from naturally derived and synthetic polymers, as cell-free implants and as tissue engineering scaffolds, and with controlled degradation profiles and release of stimulatory growth factors. Using hydrogels, cartilage tissue has been engineered in vitro that has similar mechanical properties to native cartilage. This review summarizes the advancements that have been made in determining the potential of hydrogels to replace damaged cartilage or support new tissue formation as a function of specific design parameters, such as the type of polymer, degradation profile, mechanical properties and loading regimen, source of cells, cell-seeding density, controlled release of growth factors, and strategies to cause integration with surrounding tissue. Some key challenges for clinical translation remain, including limited information on the mechanical properties of hydrogel implants or engineered tissue that are necessary to restore joint function, and the lack of emphasis on the ability of an implant to integrate in a stable way with the surrounding tissue. Future studies should address the factors that affect these issues, while using clinically relevant cell sources and rigorous models of repair.     

A biomimetic extracellular matrix for cartilage tissue engineering centered on photocurable gelatin,hyaluronic acid and chondroitin sulfate

The development of hydrogels tailored for cartilage tissue engineering has been a research and clinical goal for over a decade. Directing cells towards a chondrogenic phenotype and promoting new matrix formation are significant challenges that must be overcome for the successful application of hydrogels in cartilage tissue therapies. Gelatin–methacrylamide (Gel-MA) hydrogels have shown promise for the repair of some tissues, but have not been extensively investigated for cartilage tissue engineering. We encapsulated human chondrocytes in Gel-MA-based hydrogels, and show that with the incorporation of small quantities of photocrosslinkable hyaluronic acid methacrylate (HA-MA), and to a lesser extent chondroitin sulfate methacrylate (CS-MA), chondrogenesis and mechanical properties can be enhanced. The addition of HA-MA to Gel-MA constructs resulted in more rounded cell morphologies, enhanced chondrogenesis as assessed by gene expression and immunofluorescence, and increased quantity and distribution of the newly synthesized extracellular matrix (ECM) throughout the construct. Consequently, while the compressive moduli of control Gel-MA constructs increased by 26 kPa after 8 weeks culture, constructs with HA-MA and CS-MA increased by 114 kPa. The enhanced chondrogenic differentiation, distribution of ECM, and improved mechanical properties make these materials potential candidates for cartilage tissue engineering applications.     

Comparative study of the use of poly(glycolic acid), calcium alginate and pluronics in the engineering of autologous porcine cartilage

New cartilage formation has been successfully achieved by a technology referred to as tissue engineering. Polymers and hydrogels such as poly(glycolic acid), calcium alginate, and poly(ethylene) and poly(propylene) hydrogels have been used as cell carriers to regenerate cartilage in the nude mouse model. The next step toward human applications of engineered cartilage is to demonstrate their potential in immunocompetent animal models. This study compared the suitability of three polymers for generating tissue engineered elastic cartilage using autologous cells in an immuno-competent porcine animal model. Auricular cartilage was obtained from pigs. Chondrocytes were isolated and seeded onto fiber based poly(glycolic acid) (PGA) scaffolds or suspended in calcium alginate or pluronic F127 gel at constant concentrations. Chondrocyte-polymer constructs were either implanted (PGA) or injected (calcium alginate and pluronic) as autologous implants subcutaneously into the pigs from which the cells had been isolated. Specimens were harvested and analyzed grossly and histologically after 6 weeks in vivo. All explants demonstrated cartilage formation to a variable degree. When using PGA or calcium alginate, the overall histological appearance of the tissue formed is that of fibrocartilage with thick bundles of collagen dispersed in the tissue. When using pluronics as scaffold, histologic features resemble those of native elastic cartilage, showing a more organized arrangement of the cells, which seems to correlate to functional properties as elastin presence in the tissue engineered cartilage. Elastic cartilage engineered in an immunocompetent animal model varies with the type of polymer used. The behavior of the cell-polymer constructs is not fully understood and outcome seems to be related to several factors, including inflammatory reaction. Further studies with similar models are needed to determine the feasibility of engineering tissue generated from different cell-polymer constructs prior to human application.     

An overview of recent patents on musculoskeletal interface tissue engineering

Interface tissue engineering involves the development of engineered grafts that promote integration between multiple tissue types. Musculoskeletal tissue interfaces are critical to the safe and efficient transmission of mechanical forces between multiple musculoskeletal tissues, e.g., between ligament and bone tissue. However, these interfaces often do not physiologically regenerate upon injury, resulting in impaired tissue function. Therefore, interface tissue engineering approaches are considered to be particularly relevant for the structural restoration of musculoskeletal tissues interfaces. In this article, we provide an overview of the various strategies used for engineering musculoskeletal tissue interfaces with a specific focus on the recent important patents that have been issued for inventions that were specifically designed for engineering musculoskeletal interfaces as well as those that show promise to be adapted for this purpose.     

Maximizing cartilage formation and integration via a trajectory-based tissue engineering approach

Given the limitations of current surgical approaches to treat articular cartilage injuries, tissue engineering (TE) approaches have been aggressively pursued. Despite reproduction of key mechanical attributes of native tissue, the ability of TE cartilage constructs to integrate with native tissue must also be optimized for clinical success. In this paper, we propose a “trajectory-based” tissue engineering (TB-TE) approach, based on the hypothesis that time-dependent increases in construct maturation in-vitro prior to implantation (i.e. positive rates) may provide a reliable predictor of in-vivo success. As an example TE system, we utilized hyaluronic acid hydrogels laden with mesenchymal stem cells. We first modeled the maturation of these constructs in-vitro to capture time-dependent changes. We then performed a sensitivity analysis of the model to optimize the timing and amount of data collection. Finally, we showed that integration to cartilage in-vitro is not correlated to the maturation state of TE constructs, but rather their maturation rate, providing a proof-of-concept for the use of TB-TE to enhance treatment outcomes following cartilage injury. This new approach challenges the traditional TE paradigm of matching only native state parameters of maturity and emphasizes the importance of also establishing an in-vitro trajectory in constructs in order to improve the chance of in-vivo success.     

Review: photopolymerizable and degradable biomaterials for tissue engineering applications

Photopolymerizable and degradable biomaterials are finding widespread application in the field of tissue engineering for the engineering of tissues such as bone, cartilage, and liver. The spatial and temporal control afforded by photoinitiated polymerizations has allowed for the development of injectable materials that can deliver cells and growth factors, as well as for the fabrication of scaffolding with complex structures. The materials developed for these applications range from entirely synthetic polymers (e.g., poly(ethylene glycol)) to purely natural polymers (e.g., hyaluronic acid) that are modified with photoreactive groups, with degradation based on the hydrolytic or enzymatic degradation of bonds in the polymer backbone or crosslinks. The degradation behavior also ranges from purely bulk to entirely surface degrading, based on the nature of the backbone chemistry and type of degradable units. The mechanical properties of these polymers are primarily based on factors such as the network crosslinking density and polymer concentration. As we better understand biological features necessary to control cellular behavior, smarter materials are being developed that can incorporate and mimic many of these factors.     

注射型组织再生支架的研究进展

在组织修复与再生中,可注射型支架具有微创的优点,并能够为细胞的增殖与分化提供更接近于天然细胞外基质的化学与物理环境。因此,相比于传统的硬支架具有更大的优势,是细胞支架的一个重要组成部分与发展方向。目前,可注射型支架材料是以水凝胶为基础,包括温敏型水凝胶、交联型水凝胶和以水凝胶为载体的混合物。这类支架已被广泛地用于骨和软骨的修复。这些支架在体内实验中表现出良好的生物和细胞相容性,能够促进组织的形成。本文综述了可注射型组织再生支架近年来的发展动向,分析了各类可注射支架的优缺点。     

A Paradigm for Functional Tissue Engineering of Articular Cartilage via Applied Physiologic Deformational Loading

Deformational loading represents a primary component of the chondrocyte physical environment in vivo. This review summarizes our experience with physiologic deformational loading of chondrocyte-seeded agarose hydrogels to promote development of cartilage constructs having mechanical properties matching that of the parent calf tissue, which has a Young's modulus E(Y) = 277 kPa and unconfined dynamic modulus at 1 Hz G* = 7 MPa. Over an 8-week culture period, cartilage-like properties have been achieved for 60 x 10(6) cells/ml seeding density agarose constructs, with E(Y) = 186 kPa, G* = 1.64 MPa. For these constructs, the GAG content reached 1.74% ww and collagen content 2.64% ww compared to 2.4% ww and 21.5% ww for the parent tissue, respectively. Issues regarding the deformational loading protocol, cell-seeding density, nutrient supply, growth factor addition, and construct mechanical characterization are discussed. In anticipation of cartilage repair studies, we also describe early efforts to engineer cylindrical and anatomically shaped bilayered constructs of agarose hydrogel and bone (i.e., osteochondral constructs). The presence of a bony substrate may facilitate integration upon implantation. These efforts will provide an underlying framework from which a functional tissue-engineering approach, as described by Butler and coworkers (2000), may be applied to general cell-scaffold systems adopted for cartilage tissue engineering.     

Synthesis and in vitro evaluation of enzymatically cross-linked elastin-like polypeptide gels for cartilaginous tissue repair

Genetically engineered elastin-like polypeptide (ELP) hydrogels offer unique promise as scaffolds for cartilage tissue engineering because of the potential to promote chondrogenesis and to control mechanical properties. In this study, we designed and synthesized ELPs capable of undergoing enzyme-initiated gelation via tissue transglutaminase, with the ultimate goal of creating an injectable, in situ cross-linking scaffold to promote functional cartilage repair. Addition of the enzyme promoted ELP gel formation and chondrocyte encapsulation in a biocompatible process, which resulted in cartilage matrix synthesis in vitro and the potential to contribute to cartilage mechanical function in vivo. A significant increase in the accumulation of sulfated glycosaminoglycans was observed, and histological sections revealed the accumulation of a cartilaginous matrix rich in type II collagen and lacking in type I collagen, indicative of hyaline cartilage formation. These results provide evidence of chondrocytic phenotype maintenance for cells in the ELP hydrogels in vitro. In addition, the dynamic shear moduli of ELP hydrogels seeded with chondrocytes increased from 0.28 to 1.7 kPa during a 4-week culture period. This increase in the mechanical integrity of cross-linked ELP hydrogels suggests restructuring of the ELP matrix by deposition of functional cartilage extracellular matrix components.     

Synthesis,properties, and biomedical applications of gelatin methacryloyl (GelMA) hydrogels

Gelatin methacryloyl (GelMA) hydrogels have been widely used for various biomedical applications due to their suitable biological properties and tunable physical characteristics. GelMA hydrogels closely resemble some essential properties of native extracellular matrix (ECM) due to the presence of cell-attaching and matrix metalloproteinase responsive peptide motifs, which allow cells to proliferate and spread in GelMA-based scaffolds. GelMA is also versatile from a processing perspective. It crosslinks when exposed to light irradiation to form hydrogels with tunable mechanical properties. It can also be microfabricated using different methodologies including micromolding, photomasking, bioprinting, self-assembly, and microfluidic techniques to generate constructs with controlled architectures. Hybrid hydrogel systems can also be formed by mixing GelMA with nanoparticles such as carbon nanotubes and graphene oxide, and other polymers to form networks with desired combined properties and characteristics for specific biological applications. Recent research has demonstrated the proficiency of GelMA-based hydrogels in a wide range of tissue engineering applications including engineering of bone, cartilage, cardiac, and vascular tissues, among others. Other applications of GelMA hydrogels, besides tissue engineering, include fundamental cell research, cell signaling, drug and gene delivery, and bio-sensing.     

Designing zonal organization into tissue-engineered cartilage

Cartilage tissue engineering strategies generally result in homogeneous tissue structures with little resemblance to the native zonal organization of articular cartilage. The objective of this study was to use bilayered photopolymerized hydrogels to organize zone-specific chondrocytes in a stratified framework and study the effects of this three-dimensional coculture system on the properties of the engineered tissue. Superficial and deep zone chondrocytes from bovine articular cartilage were photoencapsulated in separate hydrogels as well as in adjacent layers of a bilayered hydrogel. Histology, mechanical testing, and biochemical analysis was performed after culturing in vitro. To evaluate the influence of coculture on tissue properties, the layers were separated and compared to constructs containing only superficial or deep cells. In the bilayered constructs, deep cells produced more collagen and proteoglycan than superficial cells, resulting in cartilage tissue with stratified, heterogeneous properties. Deep cells cocultured with superficial cells in the bilayered system demonstrated reduced proliferation and increased matrix synthesis compared to deep cells cultured alone. The bilayered constructs demonstrated greater shear and compressive strength than homogenous cell constructs. This study demonstrated that interactions between zone-specific chondrocytes affect the biological and mechanical properties of engineered cartilage. Strategies aimed to structurally organize zone-specific cells and encourage heterotypic cell interactions may contribute to improved functional properties of engineered cartilage.     

The assembly of cell-encapsulating microscale hydrogels using acoustic waves

Microscale hydrogels find widespread applications in medicine and biology, e.g., as building blocks for tissue engineering and regenerative medicine. In these applications, these microgels are assembled to fabricate large complex 3D constructs. The success of this approach requires non-destructive and high throughput assembly of the microgels. Although various assembly methods have been developed based on modifying interfaces, and using microfluidics, so far, none of the available assembly technologies have shown the ability to assemble microgels using non-invasive fields rapidly within seconds in an efficient way. Acoustics has been widely used in biomedical arena to manipulate droplets, cells and biomolecules. In this study, we developed a simple, non-invasive acoustic assembler for cell-encapsulating microgels with maintained cell viability (>93%). We assessed the assembler for both microbeads (with diameter of 50?μm and 100?μm) and microgels of different sizes and shapes (e.g., cubes, lock-and-key shapes, tetris, saw) in microdroplets (with volume of 10?μL, 20?μL, 40?μL, 80?μL). The microgels were assembled in seconds in a non-invasive manner. These results indicate that the developed acoustic approach could become an enabling biotechnology tool for tissue engineering, regenerative medicine, pharmacology studies and high throughput screening applications.     

The Effect of Hybridization of Hydrogels and Poly(L-lactide-co-ε-caprolactone) Scaffolds on Cartilage Tissue Engineering

For repairing cartilage defects by cartilage tissue engineering, it is important that engineered cartilage that is fabricated with scaffolds and cells can maintain the biological and physiological functions of cartilage, and also can induce three-dimensional spatial organization of chondrocytes. In this sense, hydrogels such as fibrin gels (FG) and hyaluronan (HA) are widely used for application in cartilage treatment. However, the use of hydrogels alone as a scaffold has a physical weakness; the mechanical properties of hydrogels are too weak to endure complex loading in the body. In this study, for mimicking a native cartilage microenvironment, we made cell–hybrid scaffold constructs with poly(L-lactide-co-ε-caprolactone) (PLCL) scaffolds and hydrogels to guide three-dimensional spatial organization of cells and extracellular matrix. A highly elastic scaffold was fabricated from PLCL with 85% porosity and 300–500 μm pore size using a gel-pressing method. The mixture of rabbit chondrocytes and hydrogels was seeded on PLCL scaffolds, and was subcutaneously implanted into nude mice for up to eight weeks. The cell seeding efficiency of the hybrid scaffolds with FG or HA was higher than that of the PLCL scaffolds. From in vivo studies, the accumulation of cartilaginous extracellular matrices of constructs, which was increased by hybridization of hydrogels and PLCL scaffolds, showed that the cell–hybrid scaffold constructs formed mature and well-developed cartilaginous tissue. In conclusion, the hybridization of hydrogels and PLCL scaffold for three-dimensional spatial organization of cells would provide a biomimetic environment where cartilage tissue growth is enhanced and facilitated. It can enhance the production of cartilaginous extracellular matrices and, consequently, improve the quality of the cartilaginous tissue formed.     

Engineered osteochondral grafts using biphasic composite solid free-form fabricated scaffolds

Tissue engineering has provided an alternative to traditional strategies to repair cartilage damaged by injury or degenerative disease. A successful strategy to engineer osteochondral tissue will mimic the natural contour of the articulating surface, achieve native mechanical properties and functional load-bearing ability, and lead to integration with host cartilage and underlying subchondral bone. Image-based design (IBD) and solid free-form (SFF) fabrication can be used to generate scaffolds that are load bearing and match articular geometry. The objective of this study was to utilize materials and biological factors in an integrated approach to regenerate a multitissue interface. Biphasic composite scaffolds manufactured by IBD and SFF fabrication were used to simultaneously generate bone and cartilage in discrete regions and provide for the development of a stable interface between cartilage and subchondral bone. Poly-L-lactic acid/hydroxyapatite composite scaffolds were differentially seeded with fibroblasts transduced with an adenovirus expressing bone morphogenetic protein 7 (BMP-7) in the ceramic phase and fully differentiated chondrocytes in the polymeric phase. After subcutaneous implantation into mice, the biphasic scaffolds promoted the simultaneous growth of bone, cartilage, and a mineralized interface tissue. Within the ceramic phase, the pockets of tissue generated included blood vessels, marrow stroma, and adipose tissue. This combination of IBD and SFF-fabricated biphasic scaffolds with gene and cell therapy is a promising approach to regenerate osteochondral defects.     

The mechanical properties and cytotoxicity of cell-laden double-network hydrogels based on photocrosslinkable gelatin and gellan gum biomacromolecules

A major goal in the application of hydrogels for tissue engineering scaffolds, especially for load-bearing tissues such as cartilage, is to develop hydrogels with high mechanical strength. In this study, a double-network (DN) strategy was used to engineer strong hydrogels that can encapsulate cells. We improved upon previously studied double-network (DN) hydrogels by using a processing condition compatible with cell survival. The DN hydrogels were created by a two-step photocrosslinking using gellan gum methacrylate (GGMA) for the rigid and brittle first network, and gelatin methacrylamide (GelMA) for the soft and ductile second network. We controlled the degree of methacrylation of each polymer so that they obtain relevant mechanical properties as each network. The DN was formed by photocrosslinking the GGMA, diffusing GelMA into the first network, and photocrosslinking the GelMA to form the second network. The formation of the DN was examined by diffusion tests of the large GelMA molecules into the GGMA network, the resulting enhancement in the mechanical properties, and the difference in mechanical properties between GGMA/GelMA single networks (SN) and DNs. The resulting DN hydrogels exhibited the compressive failure stress of up to 6.9?MPa, which approaches the strength of cartilage. It was found that there is an optimal range of the crosslink density of the second network for high strength of DN hydrogels. DN hydrogels with a higher mass ratio of GelMA to GGMA exhibited higher strength, which shows promise in developing even stronger DN hydrogels in the future. Three dimensional (3D) encapsulation of NIH-3T3 fibroblasts and the following viability test showed the cell-compatibility of the DN formation process. Given the high strength and the ability to encapsulate cells, the DN hydrogels made from photocrosslinkable macromolecules could be useful for the regeneration of load-bearing tissues.     

Unique biomaterial compositions direct bone marrow stem cells into specific chondrocytic phenotypes corresponding to the various zones of articular cartilage

Numerous studies have reported generation of cartilage-like tissue from chondrocytes and stem cells, using pellet cultures, bioreactors and various biomaterials, especially hydrogels. However, one of the primary unsolved challenges in the field has been the inability to produce tissue that mimics the highly organized zonal architecture of articular cartilage; specifically its spatially varying mechanical properties and extra-cellular matrix (ECM) composition. Here we show that different combinations of synthetic and natural biopolymers create unique niches that can "direct" a single marrow stem cell (MSC) population to differentiate into the superficial, transitional, or deep zones of articular cartilage. Specifically, incorporating chondroitin sulfate (CS) and matrix metalloproteinase-sensitive peptides (MMP-pep) into PEG hydrogels (PEG:CS:MMP-pep) induced high levels of collagen II and low levels of proteoglycan expression resulting in a low compressive modulus, similar to the superficial zone. PEG:CS hydrogels produced intermediate-levels of both collagen II and proteoglycans, like the transitional zone, while PEG:hyaluronic acid (HA) hydrogels induced high proteoglycan and low collagen II levels leading to high compressive modulus, similar to the deep zone. Additionally, the compressive moduli of these zone-specific matrices following cartilage generation showed similar trend as the corresponding zones of articular cartilage, with PEG:CS:MMP-pep having the lowest compressive modulus, followed by PEG:CS while PEG:HA had the highest modulus. These results underscore the potential for composite scaffold structures incorporating these biomaterial compositions such that a single stem-progenitor cell population can give rise to zonally-organized, functional articular cartilage-like tissue.     

Photocrosslinkable polysaccharides based on chondroitin sulfate

Photopolymerizing hydrogels have demonstrated potential for use as a scaffold in numerous tissue-engineering applications. The majority of photopolymerizing hydrogels are made from purely synthetic polymers. The purpose of this study was to synthesize and characterize photopolymerizing hydrogels derived from the biopolymer chondroitin sulfate in order to enhance the bioactivity of the scaffold and potentially improve tissue regeneration. Methacrylate groups were added to chondroitin sulfate, a major component of cartilage, using glycidyl methacrylate. The gels exhibited viscoelastic behavior typical of hydrogels. Cogels based on chondroitin sulfate and poly(ethylene glycol) demonstrated increasing pore size with increasing concentration of chondroitin sulfate as determined by water content, mechanical strength, and morphology using scanning electron microscopy. The chondroitin sulfate hydrogels degraded specifically in the presence of the enzyme chondroitinase. Chondrocytes remained viable after photoencapsulation and incubation in the biogels, suggesting their possible use for cartilage tissue engineering.     

细胞外基质来源支架在软骨组织工程中的应用

BACKGROUND: At present, a variety of extracellular matrix-derived scaffolds have been successfully applied for cartilage tissue engineering in experiment and clinical practice. OBJECTIVE: To summarize the application and research status of extracellular matrix-derived scaffolds in cartilage tissue engineering. METHODS: A computer-based online search in PubMed, CNKI, CqVip and WanFang databases was performed using the keywords of “tissue engineering, cartilage, extracellular matrix, scaffolds” in English and Chinese, respectively. A total of 1 140 literatures were retrieved, and finally 65 eligible literatures were included. RESULTS AND CONCLUSION: In terms of the components, extracellular matrix-derived scaffolds are divided into monomeric natural polymers, mixed natural polymers, natural polymers compositing with synthetic polymers as well as acellular extracellular matrix-derived materials. Extracellular matrix-derived scaffolds hold good biocompatibility and degradability, and can promote proliferation and differentiation of choncrodytes; therefore, they as good bionic scaffolds have been applied for cartilage tissue engineering in clinical practice, However, poor mechanical properties and difficulty to molding should never be ignored. Further research should focus on improving the preparation technology by combining synthetic materials with extracellular matrix-derived scaffolds for cartilage tissue engineering.      

Cartilage-like mechanical properties of poly (ethylene glycol)-diacrylate hydrogels

Hydrogels prepared from poly-(ethylene glycol) (PEG) have been used in a variety of studies of cartilage tissue engineering. Such hydrogels may also be useful as a tunable mechanical material for cartilage repair. Previous studies have characterized the chemical and mechanical properties of PEG-based hydrogels, as modulated by precursor molecular weight and concentration. Cartilage mechanical properties vary substantially, with maturation, with depth from the articular surface, in health and disease, and in compression and tension. We hypothesized that PEG hydrogels could mimic a broad range of the compressive and tensile mechanical properties of articular cartilage. The objective of this study was to characterize the mechanical properties of PEG hydrogels over a broad range and with reference to articular cartilage. In particular, we assessed the effects of PEG precursor molecular weight (508?Da, 3.4?kDa, 6?kDa, and 10?kDa) and concentration (10-40%) on swelling property, equilibrium confined compressive modulus (H(A0)), compressive dynamic stiffness, and hydraulic permeability (k(p0)) of PEG hydrogels in static/dynamic confined compression tests, and equilibrium tensile modulus (E(ten)) in tension tests. As molecular weight of PEG decreased and concentration increased, hydrogels exhibited a decrease in swelling ratio (31.5-2.2), an increase in H(A0) (0.01-2.46?MPa) and E(ten) (0.02-3.5?MPa), an increase in dynamic compressive stiffness (0.055-42.9?MPa), and a decrease in k(p0) (1.2?×?10(-15) to 8.5?×?10(-15)?m(2)/(Pa?s)). The frequency-dependence of dynamic compressive stiffness amplitude and phase, as well as the strain-dependence of permeability, were typical of the time- and strain-dependent mechanical behavior of articular cartilage. H(A0) and E(ten) were positively correlated with the final PEG concentration, accounting for swelling. These results indicate that PEG hydrogels can be prepared to mimic many of the static and dynamic mechanical properties of articular cartilage.     

Photopolymerizable hydrogels for tissue engineering applications

Photopolymerized hydrogels are being investigated for a number of tissue engineering applications because of the ability to form these materials in situ in a minimally invasive manner such as by injection. In addition, hydrogels, three-dimensional networks of hydrophilic polymers that are able to swell large amounts of water, can be made to resemble the physical characteristics of soft tissues. Hydrogel materials also generally exhibit high permeability and good biocompatibility making, these materials attractive for use in cell encapsulation and tissue engineering applications. A number of hydrogel materials can be formed via photopolymerization processes mild enough to be carried out in the presence of living cells. This allows one to homogeneously seed cells throughout the scaffold material and to form hydrogels in situ. This review presents advantages of photopolymerization of hydrogels and describes the photoinitiators and materials in current use. Applications of photopolymerized hydrogels in tissue engineering that have been investigated are summarized.