Neural tissue engineering and biohybridized microsystems for neurobiological investigation in vitro (Part 1)

Advances in neural tissue engineering have resulted in the development and implementation of three-dimensional (3-D) neural cellular constructs, which may serve as neurofidelic in vitro investigational platforms. In addition, interfacing these 3-D cellular constructs with micro-fluidic and/or micro-electrical systems has created biohybridized platforms, providing unprecedented 3-D microenvironmental control and allowing noninvasive probing and manipulation of cultured neural cells. Cells in the brain interact within a complex, multicellular environment with tightly coupled 3-D cell-cell/cell-extracellular matrix (ECM) interactions; yet most in vitro models utilize planar systems lacking in vivo-like ECM. As such, neural cultures with cells distributed throughout a thick (> 500 microm), bioactive extracellular matrix may provide a more physiologically relevant setting to study neurobiological phenomena than traditional planar cultures. This review presents an overview of 2-D versus 3-D culture models and the state of the art in 3-D neural cell-culture systems. We then detail our efforts to engineer a range of 3-D neural cellular constructs by systematically varying parameters such as cell composition, cell density, matrix constituents, and mass transport. The ramifications on neural cell survival, function, and network formation based on these parameters are specifically addressed. These 3-D neural cellular constructs may serve as powerful investigational platforms for the study of basic neurobiology, network neurophysiology, injury/disease mechanisms, pharmacological screening, or test-beds for cell replacement therapies. Furthermore, while survival and growth of neural cells within 3-D constructs poses many challenges, optimizing in vitro constructs prior to in vivo implementation offers a sound bioengineering design approach.     

The use of poly(ethylene glycol) hydrogels to investigate the impact of ECM chemistry and mechanics on smooth muscle cells

Hydrogels based on poly(ethylene glycol) (PEG) are of increasing interest for regenerative medicine applications and are ideal materials to direct cell function due to the ability to confer key functionalities of native extracellular matrix (ECM) on PEG's otherwise inert backbone. Given extensive recent evidence that ECM compliance influences a variety of cell functions, PEG-based hydrogels are also attractive due to the ease with which their mechanical properties can be controlled. In these studies, we exploited the chemical and mechanical tunability of PEG-based gels to study the impact of ECM chemistry and mechanics on smooth muscle cells (SMCs) in both 2-D and 3-D model systems. First, by controlling the extent of crosslinking and therefore the mechanical properties of PEG-based hydrogels (tensile moduli from 13.7 to 423.9kPa), we report here that the assembly of F-actin stress fibers and focal adhesions, indicative of the state of actin contractility, were influenced by the compliance of 2-D PEG gels functionalized with either short adhesive peptides or full-length ECM proteins. Varying ECM ligand density and identity independent of gel compliance affected the physical properties of the focal adhesions, and also influenced SMC spreading in 2-D. Furthermore, SMCs proliferated to a greater extent as gel stiffness was increased. In contrast, the degree of SMC differentiation, which was qualitatively assessed by the extent of smooth muscle alpha-actin bundling and the association of calponin and caldesmon with the alpha-actin fibrils, was found to decrease with substrate stiffness in 2-D cultures. In 3-D, despite the fact that their viability and degree of spreading were greatly reduced, SMCs did express some contractile markers indicative of their differentiated phenotype when cultured within PEG-RGDS constructs. Combined, these data suggest that the mechanical and chemical properties of PEG hydrogels can be tuned to influence SMC phenotype in both 2-D and 3-D.     

Hydrogel optimization for cultured elastic chondrocytes seeded onto a polyglycolic acid scaffold

The purpose of this study was to compare the effect of different hydrogels on the production of tissue-engineered cartilage based on polyglycolic acid (PGA). Chondrocytes were isolated from adult sheep auricles. Alginate, Type I collagen, methylcellulose, and pluronic F127 hydrogels were evaluated, as were controls prepared without hydrogels. Proliferated chondrocytes were mixed with each hydrogel at 20 x 10(6) cells/mL and seeded onto PGA (1 x 1 x 0.2 cm, n = 60). The constructs were cultured with serum-free medium containing 5 ng/mL TGF-beta(2) and 5 ng/mL des(1-3)IGF-I in rotational bioreactors for up to 6 weeks. The cellular morphology, histology, and biochemistry were analyzed. Type I collagen, methylcellulose, and pluronic F127 displayed improved cartilage matrix deposition in terms of histology and biochemistry compared to alginate. It was not concluded that the combined seeding of chondrocytes and hydrogels on a PGA scaffold had significantly better effects than cell seeding without hydrogels. However, the histology and other useful findings in this ECM analyses suggested that Type I collagen and MC hydrogels were the best candidates for cartilage regeneration, because of their stimulation for chondrocyte proliferation in a three-dimensional culture as well as cartilage regeneration.     

Three dimensional culture upregulates extracellular matrix protein expression in human liver cell lines--a step towards mimicking the liver in vivo?

Extracellular matrix (ECM) in the liver affects the phenotype of both hepatocytes and non-parenchymal cells. To be able to mimic in vivo liver function for extracorporeal hepatic support using human cell lines, a necessary step is to upregulate the function normally seen in monolayer culture. 3-D spheroid colonies were formed by culturing single HepG2 cells encapsulated in alginate beads. ECM expression in these cultures was compared to monolayer Hep G2 cultures. The following ECM proteins were detected immunohistochemically:- collagens 1, III, V and VI, the glycoproteins fibronectin, tenascin and vitronectin, and the basement membrane protein laminin. In 3-D cultures, all proteins except tenascin were strongly expressed, as compared with weak or undetectable expression in monolayer cultures, even with 10-fold increases in the antibody concentration used. In conclusion, we have demonstrated that the 3-D environment created by alginate encapsulation of cell lines leads to cell behaviour mimicking that in vivo.     

Long-term three-dimensional neural tissue cultures in functionalized self-assembling peptide hydrogels,Matrigel and Collagen I

Designer peptides with self-assembling properties form nanofibers which are further organized to form a hydrogel consisting of up to 99.5% water. We present here the encapsulation of neural stem cells into peptide nanofiber hydrogel scaffolds. This results in three-dimensional (3-D) neural tissue cultures in which neural stem cells differentiate into progenitor neural cells, neurons, astrocytes and oligodendrocytes when cultured in serum-free medium. Cell survival studies showed that neural cells in peptide hydrogels thrive for at least 5 months. In contrast, neural stem cells encapsulated in Collagen I were poorly differentiated and did not migrate significantly, thus forming clusters. We show that for culture periods of 1–2 weeks, neural stem cells proliferate and differentiate better in Matrigel. However, in long-term studies, the population of cells in Matrigel decreases whereas better cell survival rates are observed in neural tissue cultures in peptide hydrogels. Peptide functionalization with cell adhesion and cell differentiation motifs show superior cell survival and differentiation properties compared to those observed upon culturing neural cells in non-modified peptide hydrogels. These designed 3-D engineered tissue culturing systems have a potential use as tissue surrogates for tissue regeneration. The well-defined chemical and physical properties of the peptide nanofiber hydrogels and the use of serum-free medium allow for more realistic biological studies of neural cells in a biomimetic 3-D environment.     

Cryopreservation effects on recombinant myoblasts encapsulated in adhesive alginate hydrogels

Cell encapsulation in hydrogels is widely used in tissue engineering applications, including encapsulation of islets or other insulin-secreting cells in pancreatic substitutes. Use of adhesive, biofunctionalized hydrogels is receiving increasing attention as cell–matrix interactions in three-dimensional (3-D) environments can be important for various cell processes. With pancreatic substitutes, studies have indicated benefits of 3-D adhesion on the viability and/or function of insulin-secreting cells. As long-term storage of microencapsulated cells is critical for their clinical translation, cryopreservation of cells in hydrogels is being actively investigated. Previous studies have examined the cryopreservation response of cells encapsulated in non-adhesive hydrogels using conventional freezing and/or vitrification (ice-free cryopreservation); however, none have systematically compared the two cryopreservation methods with cells encapsulated within an adhesive 3-D environment. The latter would be significant, as evidence suggests adhesion influences the cellular response to cryopreservation. Thus, the objective of this study was to determine the response to conventional freezing and vitrification of insulin-secreting cells encapsulated in an adhesive biomimetic hydrogel. Recombinant insulin-secreting C2C12 myoblasts were encapsulated in oxidized RGD–alginate and cultured for 1 or 4 days post-encapsulation, cryopreserved, and assessed up to 3 days post-warming for metabolic activity and insulin secretion, and 1 day post-warming for cell morphology. Besides certain transient differences in the vitrified group relative to the fresh control, both conventional freezing and vitrification maintained the metabolism, secretory activity, and morphology of the recombinant C2C12 cells. Thus, due to a simpler procedure and slightly superior results, conventional freezing is recommended over vitrification for the cryopreservation of C2C12 cells encapsulated in oxidized, RGD-modified alginate.     

Corneal epithelial cell growth over tethered-protein/peptide surface-modified hydrogels

In this study, we investigated the corneal epithelial cell growth rate and adhesion to novel hydrogels with (1) extracellular matrix proteins [fibronectin, laminin, substance P, and insulin-like growth factor-1 (IGF-1)] and (2) peptide sequences [RGD and fibronectin adhesion-promoting peptide (FAP)] tethered to their surface on poly(ethylene glycol) (PEG) chains. The growth rate to confluence of primary rabbit cornea epithelial cells was compared for plain polymethacrylic acid-co-hydroxyethyl methacrylate (PHEMA/MAA) hydrogels, PHEMA/MAA hydrogels coated with extracellular matrix proteins or peptides, and PHEMA/MAA hydrogels with tethered extracellular matrix proteins or peptides on the surface. The development of focal adhesions by the epithelial cells grown on the surfaces was determined by F-actin staining. Little to no epithelial cell growth occurred on the plain hydrogel surfaces throughout the 15-day culture period. Of the coated hydrogels, only the fibronectin-coated surfaces showed a significant increase in cell growth compared to plain hydrogels (p < 0.009). However, even these surfaces reached a maximum of only 20% confluence. Laminin, fibronectin adhesion-promoting peptide (FAP), and fibronectin/laminin (1:1) tether-modified hydrogels all achieved 100% confluence by the end of the culture period, although the rates at which confluence was reached differed. F-actin staining showed that focal adhesions were formed for the laminin, FAP, and fibronectin/laminin tether-modified surfaces. The results support the hypothesis that tethering certain extracellular matrix proteins and/or peptides to the hydrogel surface enhances epithelial cell growth and adhesion, compared with that seen for protein-coated or plain hydrogel surfaces.     

Fabrication methods of an engineered microenvironment for analysis of cell-biomaterial interactions

Success in tissue engineering requires an understanding of how cells integrate the signals presented from the microenvironment created by biomaterial scaffolds to alter their responses. Besides the presence of chemical stimuli, there is growing evidence that the spatial organization of cells and tissue within a 3-dimensional (3-D) extracellular matrix (ECM) context is a critical element in controlling cellular function. Therefore, in order to direct cells toward a desirable tissue structure, it is necessary to engineer biomaterials to have spatiotemporal control of the presentation of regulatory signals. Given that, micro-patterning techniques have profited by combining micro-fabrication technology with the chemical conjugation of biologically active molecules to provide new culture systems where cells can be cultured within a specific geometry. The micro-engineered environments have been developed as 2- and 3-D structures, which have proven greatly useful as versatile platforms to study cell, biomaterial, and ECM interactions on both macroscopic and microscopic levels. The main focus of this review is a brief summary of the use of micro-engineered substrates in the analysis of cell-biomaterial interactions with the aim to provide an introductory overview of practical applications available in the literature. In particular, topics regarding (1) the soft-lithography technique to prepare micro-patterned substrates for the spatial control of cell adhesion, (2) biomaterials stiffness-dependent cellular responses, and (3) the microarray techniques for analysis of cell/biomaterials interactions are discussed.     

Functionalized self-assembling peptide nanofiber hydrogels mimic stem cell niche to control human adipose stem cell behavior in vitro

A class of designer functionalized self-assembling peptide nanofiber scaffolds developed from self-assembling peptide RADA16-I (AcN-RADARADARADARADA-CONH₂) has become increasingly attractive not only for studying spatial behaviors of cells, but also for developing approaches for a wide range of medical applications including regenerative medicine, rapid hemostasis and cell therapy. In this study, we report three functionalized self-assembling peptide hydrogels that serve as a three-dimensional (3-D) artificial microenvironment to control human adipose stem cell (hASC) behavior in vitro. Short peptide motifs SKPPGTSS (bone marrow homing motif), FHRRIKA (heparin-binding motif) and PRGDSGYRGDS (two-unit RGD cell adhesion motif) were used to extend the C-terminus of RADA16-I to obtain functionalized peptides. Atomic force microscopy confirmed the formation of self-assembling nanofibers in the mixture of RADA16-I peptide and functionalized peptides. The behaviors of hASCs cultured in 3-D peptide hydrogels, including migration, proliferation and growth factor-secretion ability, were studied. Our results showed that the functionalized peptide hydrogels were suitable 3-D scaffolds for hASC growth with higher cell proliferation, migration and the secretion of angiogenic growth factors compared with tissue culture plates and pure RADA16-I scaffolds. The present study suggests that these functionalized designer peptide hydrogels not only have promising applications for diverse tissue engineering and regenerative medicine applications as stem cell delivery vehicles, but also could be a biomimetic 3-D system to study nanobiomaterial–stem cell interactions and to direct stem cell behaviors.     

Generation of cell-derived three dimensional extracellular matrix substrates from two dimensional endothelial cell cultures

Within the cellular microenvironment, extracellular matrix (ECM) proteins are critical nonsoluble signaling factors that modulate cell attachment, migration, proliferation, and differentiation. We have developed a simple method to isolate and process ECM from endothelial cell cultures to create a three-dimensional (3D) ECM substrate. Endothelial cell monolayers were chemically lysed and enzymatically digested to isolate a thin, two-dimensional (2D) ECM substrate. This thin 1.8 μm 2D ECM was collected and applied to a solid support to produce 12-16-fold thicker 3D ECM substrates with average thicknesses ranging from 21 to 29 μm. The biological activity of isolated ECM was assessed by cell culture. Neural progenitor cells were cultured on endothelial-produced ECM, and unlike the thin 2D ECM, which was quickly remodeled by cells, 3D ECM substrates remained in culture for an extended period (>7 days), suggesting that a continuous signaling cue for in vitro experiments may be provided. This simple method for creating 3D ECM substrates can be applied to a variety of cell culture models for studies aimed at identifying the signaling effects of the ECM within cellular microenvironments.     

Injectable in situ crosslinkable RGD-modified alginate matrix for endothelial cells delivery

Cell-based therapies offer an attractive approach for revascularization and regeneration of tissues. However, and despite the pressing clinical needs for effective revascularization strategies, the successful immobilization of viable vascular cells within 3D matrices has been difficult to achieve. In this paper the in?vitro potential of a natural, injectable RGD-alginate hydrogel as an in situ forming matrix to deliver endothelial cells was evaluated. Several techniques were employed to investigate how these microenvironments could influence the behavior of vascular cells, namely their ability to promote the outward migration of viable, proliferative cells, retaining the ability to form a 3D arrangement. Cells within RGD-grafted alginate hydrogel were able to proliferate and maintained 80% of viability for at least 48?h post-immobilization. Additionally, entrapped cells created a 3D organization into cellular networks and, when put in contact with matrigel, cells migrated out of the RGD-matrix. Overall, the obtained results support the idea that the RGD peptides conjugated to alginate provide a 3D environment for endothelial cells adhesion, survival, migration and organization.     

Exploiting bacterial peptide display technology to engineer biomaterials for neural stem cell culture

Stem cells are often cultured on substrates that present extracellular matrix (ECM) proteins; however, the heterogeneous and poorly defined nature of ECM proteins presents challenges both for basic biological investigation of cell-matrix investigations and translational applications of stem cells. Therefore, fully synthetic, defined materials conjugated with bioactive ligands, such as adhesive peptides, are preferable for stem cell biology and engineering. However, identifying novel ligands that engage cellular receptors can be challenging, and we have thus developed a high throughput approach to identify new adhesive ligands. We selected an unbiased bacterial peptide display library for the ability to bind adult neural stem cells (NSCs), and 44 bacterial clones expressing peptides were identified and found to bind to NSCs with high avidity. Of these clones, four contained RGD motifs commonly found in integrin binding domains, and three exhibited homology to ECM proteins. Three peptide clones were chosen for further analysis, and their synthetic analogs were adsorbed on tissue culture polystyrene (TCPS) or grafted onto an interpenetrating polymer network (IPN) for cell culture. These three peptides were found to support neural stem cell self-renewal in defined medium as well as multi-lineage differentiation. Therefore, bacterial peptide display offers unique advantages to isolate bioactive peptides from large, unbiased libraries for applications in biomaterials engineering.     

Scaffolds based on degradable alginate hydrogels and poly(lactide-co-glycolide) microspheres for stem cell culture

We describe a method for creating alginate hydrogels with adjustable degradation rates that can be used as scaffolds for stem cells. Alginate hydrogels have been widely tested as three-dimensional constructs for cell culture, cell carriers for implantation, and in tissue regeneration applications; however, alginate hydrogel implants can take months to disappear from implantation sites because mammals do not produce endogenous alginases. By incorporating poly(lactide-co-glycolide) (PLGA) microspheres loaded with alginate lyase into alginate hydrogels, we demonstrate that alginate hydrogels can be enzymatically degraded in a controlled and tunable fashion. We demonstrate that neural progenitor cells (NPCs) can be cultured and expanded in vitro in this degradable alginate hydrogel system. Moreover, we observe a significant increase in the expansion rate of NPCs cultured in degrading alginate hydrogels versus NPCs cultured in standard, i.e. non-degrading, alginate hydrogels. Degradable alginate hydrogels encapsulating stem cells may be widely applied to develop novel therapies for tissue regeneration.     

Three-dimensional culture of hepatocytes on porcine liver tissue-derived extracellular matrix

There is currently no optimal system to expand and maintain the function of human adult hepatocytes in culture. Recent studies have demonstrated that specific tissue-derived extracellular matrix (ECM) can serve as a culture substrate and that cells tend to proliferate and differentiate best on ECM derived from their tissue of origin. The goal of this study was to investigate whether three-dimensional (3D) ECM derived from porcine liver can facilitate the growth and maintenance of physiological functions of liver cells. Optimized decellularization/oxidation procedures removed up to 93% of the cellular components from porcine liver tissue and preserved key molecular components in the ECM, including collagen-I, -III, and -IV, proteoglycans, glycosaminoglycans, fibronectin, elastin, and laminin. When HepG2 cells or human hepatocytes were seeded onto ECM discs, uniform multi-layer constructs of both cell types were formed. Dynamic culture conditions yielded better cellular infiltration into the ECM discs. Human hepatocytes cultured on ECM discs expressed significantly higher levels of albumin over a 21-day culture period compared to cells cultured in traditional polystyrene cultureware or in a collagen gel "sandwich". The culture of hepatocytes on 3D liver-specific ECM resulted in considerably improved cell growth and maintained cell function; therefore, this system could potentially be used in liver tissue regeneration, drug discovery or toxicology studies.     

Time-dependent cellular morphogenesis and matrix stiffening in proteolytically responsive hydrogels

Mesenchymal stromal cells residing in proteolytically responsive hydrogel scaffolds were subjected to changes in mechanical properties associated with their own three-dimensional (3-D) morphogenesis. In order to investigate this relationship the current study documents the transient degradation and restructuring of fibroblasts seeded in hydrogel scaffolds undergoing active cell-mediated reorganization over 7 days in culture. A semi-synthetic proteolytically degradable polyethylene glycol–fibrinogen (PF) hydrogel matrix and neonatal human dermal fibroblasts (NHDF) were used. Rheology (in situ and ex situ) measured stiffening of the gels and confocal laser scanning microscopy (CLSM) measured cell morphogenesis within the gels. The assumption that the matrix modulus systematically decreases as cells locally begin to enzymatically disassemble the PF hydrogel to become spindled in the material was not supported by the bulk mechanical property measurements. Instead, the PF hydrogels exhibited cell-mediated stiffening concurrent with their dynamic morphogenesis, as indicated by a four-fold increase in storage modulus after 1 week in culture. Fibrin hydrogels, which were used as the control biomaterial, proved similarly adaptive to cell-mediated remodeling only in the presence of the exogenous serine protease inhibitor aprotinin. Acellular and non-viable hydrogels also served as control groups to verify that transient matrix remodeling was entirely associated with cell-mediated events, including collagen deposition, cell-mediated proteolysis, and the formation of multicellular networks within the hydrogel constructs. The fact that cell network formation and collagen deposition both paralleled transient stiffening of the PF hydrogels, further reinforces the notion that cells actively balance between proteolysis and ECM synthesis when remodeling proteolytically responsive hydrogel scaffolds.     

甲基丙烯酸钠修饰光交联海藻酸盐水凝胶支架的制备和表征

文题释义：甲基丙烯酸钠：是一种具有双功能的化学基团的有机小分子,一端含有2-甲基丙烯酰基,该基团具有良好的化学活性,可与化合物中的多种基团反应而修饰化合物;另一个功能集团就是拥有负电荷基团,能给修饰过的化合物材料表面带来稳定的负电荷。 光引发剂：又称光敏剂,是一类能在紫外光区(250-420 nm)或可见光区(400-800 nm)吸收一定波长的能量,产生自由基、阳离子等,从而引发单体聚合交联固化的化合物。引发剂分子在紫外光区(250-400 nm)或可见光区(400-800 nm)有一定吸光能力,在直接或间接吸收光能后,引发剂分子从基态跃迁到激发单线态,经系间窜跃至激发三线态;在激发单线态或三线态经历单分子或双分子化学作用后,产生能够引发单体聚合的活性碎片,这些活性碎片可以是自由基、阳离子、阴离子等。按照引发机制不同,光引发剂可分为自由基聚合光引发剂与阳离子光引发剂,其中以自由基聚合光引发剂应用最为广泛。 背景：光交联海藻酸盐水凝胶因具有良好的生物相容性、可微创注射等优势已为热门的组织工程研究材料,但是仍然存在强度不足、细胞黏附能力不足等问题。 目的：构建载负电荷的光交联海藻酸盐水凝胶材料,探索其物理性能和细胞黏附性能变化。 方法：利用海藻酸钠和2-氨乙基甲基丙烯酸酯盐酸盐制备甲基丙烯酸酯化海藻酸盐后,再与光引发剂和不同浓度甲基丙烯酸钠(0,20,40,60 mmol/L)混合制备载负电荷光交联海藻酸盐水凝胶,利用傅里叶红外光谱仪分析水凝胶的功能基团变化情况,扫面电镜观察水凝胶的表面形态,并测量其溶胀率。将MC3T3-E1细胞与各组水凝胶共培养48 h,采用活死染色与CCK-8法分析水凝胶的细胞毒性;接种MC3T3-E1细胞于4组水凝胶表面,在第4小时活死染色观察细胞早期黏附情况,第3天活死染色观察细胞伸展情况。 结果与结论：①傅里叶红外光谱分析显示,甲基丙烯酸钠的引入可在水凝胶红外波普波数1 600 cm^-1左右处出现来自甲基丙烯酸钠的新波峰;②扫描电镜显示随着甲基丙烯酸钠浓度的增加,光交联海藻酸盐水凝胶的致密度增加,孔径减小;③溶胀率测试显示随着甲基丙烯酸钠浓度的升高,光交联海藻酸盐水凝胶的溶胀率逐渐降低;④活死染色显示4种水凝胶表面的细胞生长状态良好,细胞活性均在95%以上;CCK-8检测显示,载负电荷的光交联海藻酸盐水凝胶材料无细胞毒性;⑤随着甲基丙烯酸钠引入量的增加,载负电荷光交联海藻酸盐水凝胶表面的早期细胞黏附率逐渐增加,细胞伸展状态明显改善;⑥结果表明,甲基丙烯酸钠修饰的引入调节了光交联海藻酸盐水凝胶物理性能,并明显提高了其细胞黏附性能。 ORCID: 0000-0002-1054-6002(赵德路) 中国组织工程研究杂志出版内容重点：生物材料;骨生物材料; 口腔生物材料; 纳米材料; 缓释材料; 材料相容性;组织工程     

Bovine primary chondrocyte culture in synthetic matrix metalloproteinase-sensitive poly(ethylene glycol)-based hydrogels as a scaffold for cartilage repair

A poly(ethylene glycol) (PEG)-based hydrogel was used as a scaffold for chondrocyte culture. Branched PEG-vinylsulfone macromers were end-linked with thiol-bearing matrix metalloproteinase (MMP)-sensitive peptides (GCRDGPQGIWGQDRCG) to form a three-dimensional network in situ under physiologic conditions. Both four- and eight-armed PEG macromer building blocks were examined. Increasing the number of PEG arms increased the elastic modulus of the hydrogels from 4.5 to 13.5 kPa. PEG-dithiol was used to prepare hydrogels that were not sensitive to degradation by cell-derived MMPs. Primary bovine calf chondrocytes were cultured in both MMP-sensitive and MMP-insensitive hydrogels, formed from either four- or eight-armed PEG. Most (>90%) of the cells inside the gels were viable after 1 month of culture and formed cell clusters. Gel matrices with lower elastic modulus and sensitivity to MMP-based matrix remodeling demonstrated larger clusters and more diffuse, less cell surface-constrained cell-derived matrix in the chondron, as determined by light and electron microscopy. Gene expression experiments by real-time RT-PCR showed that the expression of type II collagen and aggrecan was increased in the MMP-sensitive hydrogels, whereas the expression level of MMP-13 was increased in the MMP-insensitive hydrogels. These results indicate that cellular activity can be modulated by the composition of the hydrogel. This study represents one of the first examples of chondrocyte culture in a bioactive synthetic material that can be remodeled by cellular protease activity.     

The effects of matrix stiffness and RhoA on the phenotypic plasticity of smooth muscle cells in a 3-D biosynthetic hydrogel system

Studies using 2-D cultures have shown that the mechanical properties of the extracellular matrix (ECM) influence cell migration, spreading, proliferation, and differentiation; however, cellular mechanosensing in 3-D remains under-explored. To investigate this topic, a unique biomaterial system based on poly(ethylene glycol)-conjugated fibrinogen was adapted to study phenotypic plasticity in smooth muscle cells (SMCs) as a function of ECM mechanics in 3-D. Tuning the compressive modulus between 448 and 5804 Pa modestly regulated SMC cytoskeletal assembly in 3-D, with spread cells in stiff matrices having a slightly higher degree of F-actin bundling after prolonged culture. However, vinculin expression in all 3-D conditions was qualitatively low and was not assembled into the classic focal adhesions typically seen in 2-D cultures. Given the evidence that RhoA-mediated cytoskeletal contractility represents a critical node in mechanosensing, we molecularly upregulated contractility by inducing SMCs to express constitutively active RhoA. In these cells, F-actin bundling and total vinculin expression increased, and focal adhesion-like structures began to emerge, consistent with RhoA's mechanism of action in cells cultured on 2-D substrates. Furthermore, SMC proliferation in 3-D did not depend significantly on matrix stiffness, and was reduced by constitutive activation of RhoA irrespective of ECM mechanical properties. Conversely, the expression of contractile markers globally increased with constitutive RhoA activation and depended on 3-D matrix stiffness only in cells with heightened RhoA activity. Combined, these data suggest that the synergistic effects of ECM mechanics and RhoA activity on SMC phenotype in 3-D are distinct from those in 2-D, and highlight the importance of studying the mechanical role of cell-matrix interactions in tunable 3-D environments.     

Three-dimensional culture of human disc cells within agarose or a collagen sponge: assessment of proteoglycan production

The objective of the present study was to assess proteoglycan production by human intervertebral disc cells cultured in vitro in selected cell carriers. Based on previous studies which evaluated disc cells seeded into collagen sponge, collagen gel, agarose, alginate or fibrin gel three-dimensional (3D) cell carriers, collagen sponge and agarose were found to provide superior microenvironments for formation of extracellular matrix (ECM). A standardized test design was used to evaluate ECM formed after 14 days of culture using the 1,9-dimethylmethylene blue (DMB) assay to assess sulfated glycosaminoglycan (S-GAG) production. Although agarose culture showed higher S-GAG levels compared to collagen sponge (2.94+/-2.20 (19) microg/ml S-GAG (mean+/-S.D. (n)) vs. 0.94+/-0.77 (22), respectively, p=0.0003), this is off-set by the significantly lower proliferation rate associated with culture of disc cells in agarose.