Thermoresponsive, redox-polymerized cellulosic hydrogels undergo in situ gelation and restore intervertebral disc biomechanics post discectomy.

Back and neck pain are commonly associated with intervertebral disc (IVD) degeneration. Structural augmentation of diseased nucleus pulposus (NP) tissue with biomaterials could restore degeneration-related IVD height loss and degraded biomechanical behaviors; however, effective NP replacement biomaterials are not commercially available. This study developed a novel, crosslinked, dual-polymer network (DPN) hydrogel comprised of methacrylated carboxymethylcellulose (CMC) and methylcellulose (MC), and used in vitro, in situ and in vivo testing to assess its efficacy as an injectable, in situ gelling, biocompatible material that matches native NP properties and restores IVD biomechanical behaviors. Thermogelling MC was required to enable consistent and timely gelation of CMC in situ within whole IVDs. The CMC-MC hydrogel was tuned to match compressive and swelling NP tissue properties. When injected into whole IVDs after discectomy injury, CMC-MC restored IVD height and compressive biomechanical behaviors, including range of motion and neutral zone stiffness, to intact levels. Subcutaneous implantation of the hydrogels in rats further demonstrated good biocompatibility of CMC-MC with a relatively thin fibrous capsule, similar to comparable biomaterials. In conclusion, CMC-MC is an injectable, tunable and biocompatible hydrogel with strong potential to be used as an NP replacement biomaterial since it can gel in situ, match NP properties, and restore IVD height and biomechanical function. Future investigations will evaluate herniation risk under severe loading conditions and assess long-term in vivo performance.

Dynamic hydrostatic pressure promotes differentiation of human dental pulp stem cells.

The masticatory apparatus absorbs high occlusal forces, but uncontrolled parafunctional or orthodontic forces damage periodontal ligament (PDL), cause pulpal calcification, pulp necrosis and tooth loss. Morphology and functional differentiation of connective tissue cells can be controlled by mechanical stimuli but effects of uncontrolled forces on intra-pulpal homeostasis and ability of dental pulp stem cells (DPSCs) to withstand direct external forces are unclear. Using dynamic hydrostatic pressure (HSP), we tested the hypothesis that direct HSP disrupts DPSC survival and odontogenic differentiation. DPSCs from four teenage patients were subjected to HSP followed by assessment of cell adhesion, survival and recovery capacity based on odontogenic differentiation, mineralization and responsiveness to bone morphogenetic protein-2 (BMP-2). HSP down-regulated DPSC adhesion and survival but promoted differentiation by increasing mineralization, in vivo hard tissue regeneration and BMP-2 responsiveness despite reduced cell numbers. HSP-treated DPSCs displayed enhanced odontogenic differentiation, an indication of favorable recovery from HSP-induced cellular stress.

Photo-crosslinked alginate hydrogels support enhanced matrix accumulation by nucleus pulposus cells in vivo.

OBJECTIVE: Intervertebral disc (IVD) degeneration is a major health concern in the United States. Replacement of the nucleus pulposus (NP) with injectable biomaterials represents a potential treatment strategy for IVD degeneration. The objective of this study was to characterize the extracellular matrix (ECM) assembly and functional properties of NP cell-encapsulated, photo-crosslinked alginate hydrogels in comparison to ionically crosslinked alginate constructs. METHODS: Methacrylated alginate was synthesized by esterification of hydroxyl groups with methacrylic anhydride. Bovine NP cells were encapsulated in alginate hydrogels by ionic crosslinking using CaCl(2) or through photo-crosslinking upon exposure to long-wave UV light in the presence of a photoinitiator. The hydrogels were evaluated in vitro by gross and histological analysis and in vivo using a murine subcutaneous pouch model. In vivo samples were analyzed for gene expression, ECM localization and accumulation, and equilibrium mechanical properties. RESULTS: Ionically crosslinked hydrogels exhibited inferior proteoglycan accumulation in vitro and were unable to maintain structural integrity in vivo. In further studies, photo-crosslinked alginate hydrogels were implanted for up to 8 weeks to examine NP tissue formation. Photo-crosslinked hydrogels displayed temporal increases in gene expression and assembly of type II collagen and proteoglycans. Additionally, hydrogels remained intact over the duration of the study and the equilibrium Young's modulus increased from 1.24+/-0.09 kPa to 4.31+/-1.39 kPa, indicating the formation of functional matrix with properties comparable to those of the native NP. CONCLUSIONS: These findings support the use of photo-crosslinked alginate hydrogels as biomaterial scaffolds for NP replacement.

The effect of nucleus pulposus crosslinking and glycosaminoglycan degradation on disc mechanical function.

Altered mechanical loading, secondary to biochemical changes in the nucleus pulposus, is a potential mechanism in disc degeneration. An understanding of the role of this altered mechanical loading is only possible by separating the mechanical and biological effects of early nucleus pulposus changes. The objective of this study was to quantify the mechanical effect of decreased glycosaminoglycans (GAG) and increased crosslinking in the nucleus pulposus using in vitro rat lumbar discs. Following initial mechanical testing the discs were injected according to the four treatment groups: PBS control, chondroitinase-ABC (ChABC) for GAG degradation, genipin (Gen) for crosslinking, or a combination of chondroitinase and genipin (ChABC+Gen). After treatment the discs were again mechanically tested, followed by histology or biochemistry. Neutral zone mechanical properties were changed by approximately 20% for PBS, ChABC, and ChABC+Gen treatments (significant only for PBS in a paired comparison). These trends were reversed with genipin crosslinking alone. With ChABC treatment the effective compressive modulus increased and the GAG content decreased; with the combination of ChABC+Gen the mechanics and GAG content were unchanged. Degradation of nucleus pulposus GAG alters disc axial mechanics, potentially contributing to the degenerative cascade. Crosslinking is unlikely to contribute to degeneration, but may be a potential avenue of treatment.

Modulation of proteoglycan and collagen profiles in human dermal fibroblasts by high density micromass culture and treatment with lactic acid suggests change to a chondrogenic phenotype.

Cartilage formation during embryonic development and in fracture healing in adult animals involves chondrogenic differentiation of mesenchymal precursors. Here we describe an in vitro model whereby human dermal fibroblasts, considered to be restricted to a fibroblast lineage, are apparently redirected toward a chondrogenic phenotype by high density micromass culture in the presence of lactic acid. Micromass cultures treated with 40 mM lactate exhibited increased levels of Alcian blue staining and sulfate incorporation, indicative of elevated sulfated glycosaminoglycan synthesis. Northern analysis revealed an up-regulation of chondroitin sulfate proteoglycan 1 (aggrecan) and transforming growth factor-beta 1 mRNA and a decrease in type I collagen expression. Type II collagen was detected by reverse transcription-PCR only in experimental cultures. Although the observed changes in biosynthesis and gene expression were consistent with differentiating chondrocytes, the cells displayed an elongated, fibroblast-like morphology. These findings suggest that dermal fibroblasts may be committed to differentiate along a chondrogenic pathway by in vitro culture under specific forcing conditions.

Chondrogenic differentiation of murine C3H10T1/2 multipotential mesenchymal cells: I. Stimulation by bone morphogenetic protein-2 in high-density micromass cultures.

Chondrogenic differentiation of mesenchymal cells is generally thought to be initiated by the inductive action of specific growth factors and depends on intimate cell-cell interactions. In this study, we have used multipotential murine C3H10T1/2 cells to analyze the effect and mechanism of action of bone morphogenetic protein 2 (BMP-2) on chondrogenesis. C3H10T1/2 cells have been previously shown to undergo multiple differentiation pathways. While chondrogenesis, osteogenesis, myogenesis and adipogenesis have been observed, chondrocytes appear significantly less frequently than the other cell types, and the appearance of chondrocytes exclusive of the other cell types has not been observed. We report here that the appearance of chondrocytes in C3H10T1/2 cells is markedly enhanced as a result of culture under conditions favorable for chondrogenesis, i.e. plating as high-density micromass and treatment with BMP-2. Such cultures contain chondrocyte-like cells, elaborate an Alcian blue stained cartilage-like matrix, express link protein and type II collagen, both cartilage matrix markers, and show increased [35S]sulfate incorporation. The appearance of Alcian blue positive material and increased sulfate incorporation are dependent on the dose of BMP-2, culture time, and cell plating density of the micromass cultures. Differentiation of cells within the micromass was specific to the chondrogenic lineage, as alkaline phosphatase staining revealed only faint staining in the micromass at the highest BMP-2 concentration. The importance of enhanced cell-cell interaction in the chondroinductive effects of BMP-2 on high-density C3H10T1/2 cultures was further implicated by the additional promotion of chondrogenesis in the presence of the polycationic compound, poly-L-lysine, which has been previously reported to enhance cellular interactions and chondrogenesis in embryonic limb mesenchymal cells. Taken together, these findings suggest that chondrogenesis in C3H10T1/2 cells is inducible by BMP-2 and requires cell-cell interaction.

In vitro release kinetics of biologically active transforming growth factor-beta 1 from a novel porous glass carrier.

Sol-gel silica-based porous glass (xerogel) was used as a novel carrier material for recombinant human transforming growth factor-beta 1 (TGF-beta 1). Room temperature synthesis procedures included sol preparation, the addition of TGF-beta 1 solution to the sol, subsequent gelation and drying. After determination of optimal synthesis parameters, the material was assayed in vitro for its ability to release biologically active TGF-beta 1 in a controlled manner. Sustained release of TGF-beta 1 over a 7-day period was demonstrated. On the basis of published TGF-beta 1 potency, the amount released is capable of eliciting bone tissue reactivity. These findings suggest that this novel glass-growth factor composite may serve as an effective bone graft material for the repair of osseous defects.

Formation of cartilage-like spheroids by micromass cultures of murine C3H10T1/2 cells upon treatment with transforming growth factor-beta 1.

Formation of cartilage during both embryonic development and repair processes involves the differentiation of multipotential mesenchymal cells. The mouse cell line, C3H10T1/2, has been shown to be multipotential and capable of differentiating into various phenotypes normally derived from embryonic mesoderm, including myocytes, adipocytes and chondrocytes. In this study, we have analyzed the induction of chrondrogenesis in C3H10T1/2 cells by transforming growth factor-beta (TGF-beta 1, human recombinant form). Treatment of high-density micromass cultures of C3H10T1/2 cells with TGF-beta 1 resulted in the formation of a three dimensional spheroid structure, which exhibited cartilage-like histology. Extracellular matrix components characteristic of cartilage, type II collagen and cartilage link protein, were demonstrated by immunohistochemistry. TGF-beta 1 treatment increased collagen synthesis, and immunoblot analysis showed the presence of type II collagen in TGF-beta 1-treated micromass cultures, but not in TGF-beta 1-treated monolayer cultures nor in untreated cultures. An increase in radioactive sulfate uptake relative to DNA synthesis was also seen in TGF-beta 1-treated micromass cultures forming spheroids, indicating the increased synthesis of sulfated proteoglycans. These observations indicated that the spheroids formed are of a cartilaginous nature, and that multipotential C3H10T1/2 cells, which do not spontaneously enter the chondrogenic pathway, can be induced to undergo cellular differentiation towards chondrogenesis in vitro through culture in a favorable environment.