Multi-scale modeling to predict ligand presentation within RGD nanopatterned hydrogels

The adhesion ligand RGD has been coupled to various materials to be used as tissue culture matrices or cell transplantation vehicles, and recent studies indicate that nanopatterning RGD into high-density islands alters cell adhesion, proliferation, and differentiation. However, elucidating the impact of nanopattern parameters on cellular responses has been stymied by a lack of understanding of the actual ligand presentation within these systems. We have developed a multi-scale predictive modeling approach to characterize the adhesion ligand nanopatterns within an alginate hydrogel matrix. The models predict the distribution of ligand islands, the spacing between ligands within an island and the fraction of ligands accessible for cell binding. These model predictions can be used to select pattern parameter ranges for experiments on the effects of individual parameters on cellular responses. Additionally, our technique could also be applied to other polymer systems presenting peptides or other signaling molecules.     

Engineering RGD nanopatterned hydrogels to control preosteoblast behavior: a combined computational and experimental approach

The adhesion ligand arginine-glycine-aspartic acid (RGD) has been coupled to various materials to be used as tissue culture matrices or cell transplantation vehicles, and recent studies indicate that nanopatterning RGD into high-density islands alters key cell behaviors. Previous studies have failed, however, to conclusively decouple the effects of RGD bulk density and individual pattern parameters (i.e. RGDs/island and island distribution) on these altered cell responses. Using a nanopatterned RGD-coupled alginate hydrogel matrix, this work combines computational, statistical and experimental approaches to elucidate the effects of RGD patterns on four key cell responses. This study shows that in MC3T3 preosteoblasts focal adhesion kinase (FAK) Y397 phosphorylation, cell spreading, and osteogenic differentiation can be controlled by RGD nanopatterning, with the distribution of islands throughout the hydrogel (i.e. how closely spaced the islands are) being the most significant pattern parameter. More closely spaced islands favor FAK Y397 phosphorylation and cell spreading, while more widely spaced islands favor differentiation. Proliferation, in contrast, is primarily a function of RGD bulk density. Nanopatterning of cell adhesion ligands has tremendous potential as a simple tool to gain significant control over multiple cell behaviors in engineered extracellular matrix (ECM).     

Differentiation stage alters matrix control of stem cells

Cues from the material to which a cell is adherent (e.g., adhesion ligand presentation, substrate elastic modulus) clearly influence the phenotype of differentiated cells. However, it is currently unclear if stem cells respond similarly to these cues. This study examined how the overall density and nanoscale organization of a model cell adhesion ligand (arginine-glycine-aspartic acid [RGD] containing peptide) presented from hydrogels of varying stiffness regulated the proliferation of a clonally derived stem cell line (D1 cells) and preosteoblasts (MC3T3-E1). While the growth rate of MC3T3-E1 preosteoblasts was responsive to nanoscale RGD ligand organization and substrate stiffness, the D1 stem cells were less sensitive to these cues in their uncommitted state. However, once the D1 cells were differentiated towards the osteoblast lineage, they became more responsive to these signals. These results demonstrate that the cell response to material cues is dependent on the stage of cell commitment or differentiation, and these findings will likely impact the design of biomaterials for tissue regeneration.     

Dynamic cell-adhesive microenvironments and their effect on myogenic differentiation

Integrin-mediated cell adhesion plays a central role in cell behavior on biomaterial surfaces and influences various cell functions. Photoactivatable RGD adhesive peptides were used to investigate the effect of the density and time point of bioadhesive ligand presentation on cell adhesion, proliferation and differentiation. PEGylated self-assembled monolayers were functionalized with RGD and caged RGD ligands and seeded with C2C12 myoblasts. The cultures were irradiated at various time points between 1 and 48 h after cell seeding in order to increase RGD surface concentration at defined time points. Attachment, spreading and myogenic differentiation of C2C12 myoblasts strongly varied with the density of RGD at the surface. Proliferation and myogenesis were further regulated by the time point at which RGD was presented to the cell, reaching highest levels when RGD exposure occurred ≤6 h after cell seeding. These results provide fundamental insights in cell–biomaterial interactions of C2C12 myoblasts in terms of temporal integrin-mediated cell responses.     

Influence of mechanical properties of alginate-based substrates on the performance of Schwann cells in culture

In tissue engineering, artificial tissue scaffolds containing living cells have been studied for tissue repair and regeneration. Notably, the performance of these encapsulated-in-scaffolds cells in terms of cell viability, proliferation, and expression of function during and after the scaffold fabrication process, has not been well documented because of the influence of mechanical, chemical, and physical properties of the scaffold substrate materials. This paper presents our study on the influence of mechanical properties of alginate-based substrates on the performance of Schwann cells, which are the major glial cells of peripheral nervous system. Given the fact that alginate polysaccharide hydrogel has poor cell adhesion properties, in this study, we examined several types of cell-adhesion supplements and found that alginate covalently modified with RGD peptide provided improved cell proliferation and adhesion. We prepared alginate-based substrates for cell culture using varying alginate concentrations for altering their mechanical properties, which were confirmed by compression testing. Then, we examined the viability, proliferation, morphology, and expression of the extracellular matrix protein laminin of Schwann cells that were seeded on the surface of alginate-based substrates (or 2D culture) or encapsulated within alginate-based substrates (3D cultures), and correlated the examined cell performance to the alginate concentration (or mechanical properties) of hydrogel substrates. Our findings suggest that covalent attachment of RGD peptide can improve the success of Schwann cell encapsulation within alginate-based scaffolds, and provide guidance for regulating the mechanical properties of alginate-based scaffolds containing Schwann cells for applications in peripheral nervous system regeneration and repair.     

The effect of injected RGD modified alginate on angiogenesis and left ventricular function in a chronic rat infarct model

Congestive heart failure (CHF) is a chronic disease with a high mortality rate. Managing CHF patients has been one of the most severe health care problems for years. Scaffold materials have been predominantly investigated in acute myocardial infarction (MI) studies and have shown promising improvement in LV function. In this study we examined whether surface modification of a biomaterial can influence the myocardial microenvironment and improve myocardial function in a rodent model of ischemic cardiomyopathy. In vitro cell culture and in vivo rat studies were performed. RGD peptides conjugated to alginate improved human umbilical vein endothelial cell (HUVEC) proliferation and adhesion when compared to a non-modified alginate group. Injection of the alginate hydrogel into the infarct area of rats 5 weeks post-MI demonstrated that both modified and non-modified alginate improve heart function, while LV function in the control group deteriorated. Both the RGD modified alginate and non-modified alginate increased the arteriole density compared to control, with the RGD modified alginate having the greatest angiogenic response. These results suggest that in situ use of modified polymers may influence the tissue microenvironment and serve as a potential therapeutic agent for patients with chronic heart failure.     

Protein and surface effects on monocyte and macrophage adhesion, maturation, and survival

Cell adhesion and maturation can be affected by the protein adsorption profile on the surface of an implanted biomaterial. In this study we have investigated how surface chemistry and adsorbed proteins can modulate monocyte and macrophage adhesion, IL-13-induced foreign-body giant cell formation, and apoptosis in vitro. Compared to a dimethylsilane-modified surface (DM), a surface modified with RGD peptides had no effect on adhesion density, foreign-body giant cell (FBGC) formation, or apoptosis in nondepleted serum conditions. The depletion of specific adhesive proteins affected adhesion, FBGC formation, and apo- ptosis. While the depletion of fibronectin and vitronectin had no overall effect compared to nondepleted serum conditions, the depletion of IgG from serum caused a significant decrease in initial adherent cell density [1000 +/- 200 compared to 2460 +/- 590 (p = 0.02)], a significant decrease in FBGC formation [2% compared to 17% (p = 0.02)], and a significant increase in the level of apoptosis [57% compared to 32% (p = 0.01)] on DM. The lowered initial adherent cell density on DM was not observed on the RGD surface, indicating that the RGD surface promotes increased initial adhesion. However, the RGD surface does not affect FBGC formation (i.e., macrophage fusion) or levels of apoptosis, which remained comparable to those on the DM surfaces at days 7 and 10.     

Characterization of leukemic cell behaviors in a soft marrow mimetic alginate hydrogel

Alginate hydrogels possess tunable mechanical properties that can mimic soft marrow tissue and present three-dimensional (3D) cues. This study evaluates its utility for supporting leukemic cell growth in vitro and its impact on cell survival, growth, and differentiation. Our results showed that the standard viscosity alginates had compromised leukemia cell viability but lower viscosity alginates recovered cell viability and improved 3D cell proliferation (27 fold) compared to 2D cultures (18 fold). Conjugation with RGD peptides promoted further cell growth (43 folds). In general, 3D hydrogels supported high-density cultures better than 2D cultures. Leukemic cells formed densely packed cell clusters in alginate hydrogels and spontaneously differentiated into a more diverse myeloid population. The cell cycle data suggested that more cells go into active cycling with a G2/M arrest in alginate hydrogels and the presence of multiploidy confirmed maturation toward megakaryocytes. In summary, superior culture of leukemia cells in 3D hydrogels is demonstrated in this study accompanied by a potential role of physical cues influencing cell fate decision. Manipulation of biophysical and biochemical properties of alginate hydrogels permits the study of specific interactions and serves to provide a robust 3D platform for studying extrinsic contributions inside the bone marrow. ? 2012 Wiley Periodicals, Inc. J Biomed Mater Res Part B: Appl Biomater, 2012.     

Human microvascular endothelial cell growth and migration on biomimetic surfactant polymers

Successful engineering of a tissue-incorporated vascular prosthesis requires cells to proliferate and migrate on the scaffold. Here, we report on a series of "ECM-like" biomimetic surfactant polymers that exhibit quantitative control over the proliferation and migrational properties of human microvascular endothelial cells (HMVEC). The biomimetic polymers consist of a poly(vinyl amine) (PVAm) backbone with hexanal branches and varying ratios of cell binding peptide (RGD) to carbohydrate (maltose). Proliferation and migration behavior of HMVEC was investigated using polymers containing RGD: maltose ratios of 100:0, 75:25 and 50:50, and compared with fibronectin (FN) coated glass (1 microg/cm2). A radial Teflon fence migration assay was used to examine HMVEC migration at 12 h intervals over a 48 h period. Migration was quantified using an inverted optical microscope, and HMVEC were examined by confocal microscopy for actin and focal adhesion organization/ arrangement. Over the range of RGD ligand density studied (approximately 0.19-0.6 peptides/nm2), our results show HMVEC migration decreases with increasing RGD density in the polymer. HMVEC were least motile on the 100% RGD polymer (approximately 0.38-0.6 peptides/nm2) with an average migration of 0.20 mm2/h in area covered, whereas HMVEC showed the fastest migration of 0.48+/-0.06 mm2/h on the 50% RGD surface ( approximately 0.19-0.30 peptides/nm2). In contrast, cell proliferation increased with increasing surface peptide density; proliferation on the 50% RGD surface was 1.5%+/-0.06/h compared with 2.2%+/-0.07/h on the 100% RGD surface. Our results show that surface peptide density affects cellular functions such as growth and migration, with the highest peptide density supporting the most proliferation but the slowest migration.     

Adhesion and Proliferation of Human Adipo-Stromal Cells for Two- or Three-Dimensional Poly(ethylene terephthalate) Substrates with or without RGD Immobilization

The adhesion and proliferation of human adipo-stromal cells was investigated for poly(ethylene terephthalete) (PET) films of two-dimensional (2D) substrate and non-woven fabrics of three-dimensional (3D) substrate after seeding at the same cell density and culturing at the same medium volume to surface area of the substrates ratio. When seeded by a static seeding method, more cells adhered on the film than on the non-woven fabric. However, the number ratio of cells proliferated to those initially adhered was similar. For the non-woven fabric, cell proliferation was enhanced by an agitated culture method. NaOH treatment introduced carboxyl groups into the surface of substrates, irrespective of the substrate type. Cell adhesion of a peptide (Arg-Gly-Asp, RGD) was chemically immobilized through the carboxyl groups on the non-woven fabric surface at a density of 10 pmol/cm². RGD immobilization significantly increased the number of cells adhered after the agitated seeding method, but did not affect the cell proliferation. Phosphorylation of focal adhesion kinase (FAK) was also enhanced by the RGD immobilization on the PET non-woven fabrics.     

Enhanced proliferation and differentiation of neural stem cells grown on PHA films coated with recombinant fusion proteins

Polyhydroxyalkanoates (PHAs) belong to a family of copolyesters with demonstrated biocompatibility. We hypothesize that genetically fusing evolutionarily preserved cell binding motifs, such as RGD or IKVAV, to the PHA-binding protein phasin (PhaP) for surface functionalization of PHA materials could better support the growth and differentiation of neural stem cells (NSCs). This hypothesis is tested on three polyester materials of the same aliphatic family: poly(L-lactic acid) (PLA) and two PHB copolymers, poly(3-hydroxybutyrate-co-3-hydroxyhexanoate) and poly(3-hydroxybutyrate-co-3-hydroxyvalerate-co-3-hydroxyhexanoate) (PHBVHHx). Experimental results indicate that surface coating of the two fusion proteins, PhaP–RGD and PhaP–IKVAV, provides short-term advantages in promoting the adhesion, proliferation and neural differentiation of rat NSCs compared to the PhaP-coated or uncoated material. Among the tested samples, the combination of coating PhaP–IKVAV on an PHBVHHx surface yields the highest levels in cell adhesion and proliferation, while the PLA film coated with PhaP–IKVAV promotes better neural differentiation and neurite outgrowth in the early stage. Because both PhaP–RGD and PhaP–IKVAV could be produced in an inexpensive manner, our data suggest that PhaP–IKVAV is an ideal nonspecific coating agent to functionalize hydrophobic biomaterials in the application of neural tissue engineering.     

The interplay between cell adhesion cues and curvature of cell adherent alginate microgels in multipotent stem cell culture

Cell-adherent microcarriers are increasingly used to expand multipotent stem cells on a large scale for therapeutic applications. However, the role of the microcarrier properties and geometry on the phenotypic activities of multipotent cells has not been well studied. This study presents a significant interplay of the number of cell adhesion sites and the curvature of the microcarrier in regulating cell growth and differentiation by culturing mesenchymal stem cells on alginate microgels chemically linked with oligopeptides containing the Arg-Gly-Asp (RGD) sequence. Interestingly, the cell growth rate and osteogenic differentiation level were increased with the RGD peptide density. At a given RGD peptide density, the cell growth rate was inversely related to the microgel diameter, whereas the osteogenic differentiation level was minimally influenced. The dependency of the cell growth rate on the microgel diameter was related to changes in shear stresses acting on cells according to simulation. Overall, this study identifies material variables key to regulating cellular activities on microcarriers, and these findings will be useful to designing a broad array of bioactive microcarriers.     

Study on the potential of RGD- and PHSRN-modified alginates as artificial extracellular matrices for engineering bone

Alginate is a polysaccharide that can be crosslinked by divalent cations, such as calcium ions, to form a gel. Chemical modification is typically used to improve its cell adhesive properties for tissue engineering applications. In this study, alginates were modified with peptides containing RGD (arginine–glycine–aspartic acid) or PHSRN (proline–histidine–serine–arginine–asparagine) sequences from fibronectin to study possible additive and synergistic effects on adherent cells. Alginates modified with each peptide were mixed at different ratios to form gels containing various concentrations and spacing between the RGD and PHSRN sequences. When normal human osteoblasts (NHOsts) were cultured on or in the gels, the ratio of RGD to PHSRN was found to influence cell behaviors, especially differentiation. NHOsts cultured on gels composed of RGD- and PHSRN-modified alginates showed enhanced differentiation when the gels contained >33 % RGD-alginate, suggesting the relative distribution of the peptides and the presentation to cells are important parameters in this regulation. NHOsts cultured in gels containing both RGD- and PHSRN-alginates also demonstrated a similar enhancement tendency of calcium deposition that was dependent on the peptide ratio in the gel. However, calcium deposition was greater when cells were cultured in the gels, as compared to on the gels. These results suggest that modifying this biomaterial to more closely mimic the chemistry of natural cell adhesive proteins, (e.g., fibronectin) may be useful in developing scaffolds for bone tissue engineering and provide three-dimensional cell culture systems which more closely mimic the environment of the human body.     

RGD多肽修饰的改性PLGA仿生支架材料对骨髓间充质干细胞粘附、增殖及分化影响的研究

目的：探索RGD多肽修饰的改性PLGA支架材料上骨髓基质细胞的增殖、粘附及分化情况。方法用异型双功能交联剂Sulfo-LC-SPDP将GRGDSPC多肽共价结合到改性PLGA支架材料上，以未接多肽的改性PLGA材料做对照，取第三代MSC接种到材料上，培养1d、2d、3d、4d后比较材料上的细胞密度来反映细胞的增殖程度；取第三代MSC接种到材料上，培养4h、12h后沉淀法定量检测粘附的细胞数，培养24h后摄光镜图像比较粘附细胞的数量和形态，并用FITC连接的鬼笔环肽对细胞骨架染色，在荧光显微镜下观察细胞骨架的组织情况；取第三代MSC接种到材料上，用成骨性培养基培养7d、14d、21d，检测细胞中ALP活性来了解MSC分化情况。结果：培养1d、2d、3d、4d后细胞的增殖程度无显著性差异；培养4h、12h后实验组细胞粘附率均显著高于对照组，且24h后细胞的粘附质量、细胞骨架的组织情况也较对照组为好；培养14d后实验组细胞表达显著高的ALP活性。结论：RGD多肽修饰对细胞增殖无明显促进作用，但能提高改性PLGA支架材料对骨髓基质细胞的粘附性，对MSC向成骨细胞分化有显著促进作用。     

The effect of adhesive ligands on bacterial and fibroblast adhesions to surfaces

The modification of medical device surface with adhesive ligands has been recently shown to be an effective means for making a bioselective surface which can inhibit bacterial adhesion while promoting host cell adhesion on device materials. Currently, the lack of quantitative correlation between the adhesion strength of bacteria, nature of adhesive ligand and adhesion kinetics of mammalian cells hinders the development of such device surface. In this study, the biophysical responses of bacteria and mammalian cells towards adhesive ligand on model device surfaces formed by the chemisorption of dopamine (a moderate antibiotic) on glass are elucidated. The effects of RGD, collagen and dopamine modification on the adhesion strength of two clinically significant bacteria including Escherichia coli (E. coli) and Staphylococcus aureus (S. aureus) were investigated by the determination of minimum lateral forces for bacterial detachment and the density of adhering bacteria. The result indicates that RGD has no apparent effect on E. coli and S. aureus adhesion, while collagen reduces E. coli but enhances S. aureus. In order to assess the degree of host cell integration, the adhesion kinetics of 3T3 fibroblasts on the four surfaces was examined by confocal reflectance interference contrast microscopy (C-RICM). In contrast to the difference found in bacterial adhesion, the result indicates that both collagen and RGD significantly enhance the initial rate of deformation and adhesion energy for fibroblasts compared to those on glass and dopamine-glass. Overall, it is demonstrated that the choice of adhesive ligand is critical for designing a device surface which simultaneously minimizes bacterial adhesion and enhances host cell integrations.     

A hydrogel material for plastic and reconstructive applications injected into the subcutaneous space of a sheep

Soft tissue reconstruction using tissue-engineered constructs requires the development of materials that are biocompatible and support cell adhesion and growth. The objective of this study was to evaluate the use of macroporous hydrogel fragments that were formed using either unmodified alginate or alginate covalently linked with the fibronectin cell adhesion peptide RGD (alginate-RGD). These materials were injected into the subcutaneous space of adult, domesticated female sheep and harvested for histological comparisons at 1 and 3 months. In addition, the alginate-RGD porous fragments were seeded with autologous sheep preadipocytes isolated from the omentum, and these cell-based constructs were also implanted. The results from this study indicate that both the alginate and alginate-RGD subcutaneous implants supported tissue and vascular ingrowth. Furthermore, at all time points of the experiment, a minimal inflammatory response and capsule formation surrounding the implant were observed. The implanted materials also maintained their sizes over the 3-month study period. In addition, the alginate-RGD fragments supported the adhesion and proliferation of sheep preadipocytes, and adipose tissue was present within the transplant site of these cellular constructs, which was not present within the biomaterial control sites.     

In vitro and in vivo characterization of nonbiomedical- and biomedical-grade alginates for articular chondrocyte transplantation

Alginate is a key hydrogel for cartilage tissue engineering. Here, we systematically evaluated four biomedical- and two nonbiomedical-grade alginates for their capacity to support the in vitro culture and in vivo transplantation of articular chondrocytes. Chondrocytes in all ultrapure alginates maintained high cell viability. Spheres composed of biomedical-grade, low-viscosity, high-mannuronic acid content alginate showed the lowest decrease in size over time. Biomedical-grade, low-viscosity, high-guluronic acid content alginate allowed for optimal cell proliferation. Biomedical-grade, medium-viscosity, high-mannuronic acid content alginate promoted the highest production of proteoglycans. When transplanted into osteochondral defects in the knee joint of sheep in vivo, empty spheres were progressively surrounded by a granulation tissue. In marked contrast with these observations, all alginate spheres carrying allogeneic chondrocytes were gradually invaded by a granulation tissue containing multinucleated giant cells, lymphocytes, and fibroblasts, regardless whether they were based on biomedical- or nonbiomedical-grade alginates. After 21 days in vivo, transplanted chondrocytes were either viable or underwent necrosis, and apoptosis played a minor role in their early fate. The individual characteristics of these alginates may be valuable to tailor specific experimental and clinical strategies for cartilage tissue engineering.     

Surface functionalization of titanium with hyaluronic acid/chitosan polyelectrolyte multilayers and RGD for promoting osteoblast functions and inhibiting bacterial adhesion

Titanium (Ti) and its alloys are used extensively in orthopedic implants due to their excellent biocompatibility and mechanical properties. However, titanium-based implant materials have specific complications associated with their applications, such as the loosening of implant-host interface owing to unsatisfactory cell adhesion and the susceptibility of the implants to bacterial infections. Hence, a surface which displays selective biointeractivity, i.e. enhancing beneficial host cell responses but inhibiting pathogenic microbial adhesion, would be highly desirable. This present study aims to improve biocompatibility and confer long-lasting antibacterial properties on Ti via polyelectrolyte multilayers (PEMs) of hyaluronic acid (HA) and chitosan (CH), coupled with surface-immobilized cell-adhesive arginine-glycine-aspartic acid (RGD) peptide. The HA/CH PEM-functionalized Ti is highly effective as an antibacterial surface but the adhesion of bone cells (osteoblasts) is poorer than on pristine Ti. With additional immobilized RGD moieties, the osteoblast adhesion can be significantly improved. The density of the surface-immobilized RGD peptide has a significant effect on osteoblast proliferation and alkaline phosphatase (ALP) activity, and both functions can be increased by 100-200% over that of pristine Ti substrates while retaining high antibacterial efficacy. Such substrates can be expected to have good potential in orthopedic applications.     

Photocrosslinked alginate hydrogels with tunable biodegradation rates and mechanical properties

Photocrosslinked and biodegradable alginate hydrogels were engineered for biomedical applications. Photocrosslinkable alginate macromers were prepared by reacting sodium alginate and 2-aminoethyl methacrylate in the presence of 1-ethyl-3-(3-dimethylaminopropyl)-carbodiimide hydrochloride and N-hydroxysuccinimide. Methacrylated alginates were photocrosslinked using ultraviolet light with 0.05% photoinitiator. The swelling behavior, elastic moduli, and degradation rates of photocrosslinked alginate hydrogels were quantified and could be controlled by varying the degree of alginate methacrylation. The methacrylated alginate macromer and photocrosslinked alginate hydrogels exhibited low cytotoxicity when cultured with primary bovine chondrocytes. In addition, chondrocytes encapsulated in these hydrogels remained viable and metabolically active as demonstrated by Live/Dead cell staining and MTS assay. These photocrosslinked alginate hydrogels, with tailorable mechanical properties and degradation rates, may find great utility as therapeutic materials in regenerative medicine and bioactive factor delivery.     

Evaluation of sodium alginate for bone marrow cell tissue engineering

Sodium alginate has applications as a material for the encapsulation and immobilisation of a variety of cell types for immunoisolatory and biochemical processing applications. It forms a biodegradable gel when crosslinked with calcium ions and it has been exploited in cartilage tissue engineering since chondrocytes do not dedifferentiate when immobilised in it. Despite its attractive properties of degradability, ease of processing and cell immobilisation, there is little work demonstrating the efficacy of alginate gel as a substrate for cell proliferation, except when RGD is modified. In this study we investigated the ability of rat bone marrow cells to proliferate and differentiate on alginates of differing composition and purity. The mechanical properties of the gels were investigated. It was found that high purity and high G-type alginate retained 27% of its initial strength after 12 days in culture and that comparable levels of proliferation were observed on this material and tissue culture plastic. Depending on composition, calcium crosslinked alginate can act as a substrate for rat marrow cell proliferation and has potential for use as 3D degradable scaffold.