Thermally Triggered Hydrogel Injection Into Bovine Intervertebral Disc Tissue Explants Induces Differentiation Of Mesenchymal Stem Cells And Restores Mechanical Function.

We previously reported a synthetic Laponite® crosslinked pNIPAM-co-DMAc (L-pNIPAM-co-DMAc) hydrogel which promotes differentiation of mesenchymal stem cells (MSCs) to nucleus pulposus (NP) cells without additional growth factors. The clinical success of this hydrogel is dependent on: integration with surrounding tissue; the capacity to restore mechanical function; as well as supporting the viability and differentiation of delivered MSCs. Bovine NP tissue explants were injected with media (control), human MSCs (hMSCs) alone, acellular L-pNIPAM-co-DMAc hydrogel or hMSCs incorporated within the L-pNIPAM-co-DMAc hydrogel and maintained at 5% O2 for 6 weeks. Viability of native NP cells and delivered MSCs was maintained. Furthermore hMSCs delivered via the L-pNIPAM-co-DMAc hydrogel differentiated and produced NP matrix components: aggrecan, collagen type II and chondroitin sulphate, with integration of the hydrogel with native NP tissue. In addition L-pNIPAM-co-DMAc hydrogel injected into collagenase digested bovine discs filled micro and macro fissures, were maintained within the disc during loading and restored IVD stiffness. The mechanical support of the L-pNIPAM-co-DMAc hydrogel, to restore disc height, could provide immediate symptomatic pain relief, whilst the delivery of MSCs over time regenerates the NP extracellular matrix; thus the L-pNIPAM-co-DMAc hydrogel could provide a combined cellular and mechanical repair approach

Current strategies for treatment of intervertebral disc degeneration: substitution and regeneration possibilities

Background: Intervertebral disc degeneration has an annual worldwide socioeconomic impact masked as low back pain of over 70 billion euros. This disease has a high prevalence over the working age class, which raises the socioeconomic impact over the years. Acute physical trauma or prolonged intervertebral disc mistreatment triggers a biochemical negative tendency of catabolic-anabolic balance that progress to a chronic degeneration disease. Current biomedical treatments are not only ineffective in the long-run, but can also cause degeneration to spread to adjacent intervertebral discs. Regenerative strategies are desperately needed in the clinics, such as: minimal invasive nucleus pulposus or annulus fibrosus treatments, total disc replacement, and cartilaginous endplates decalcification. Main Body: Herein, it is reviewed the state-of-the-art of intervertebral disc regeneration strategies from the perspective of cells, scaffolds, or constructs, including both popular and unique tissue engineering approaches. The premises for cell type and origin selection or even absence of cells is being explored. Choice of several raw materials and scaffold fabrication methods are evaluated. Extensive studies have been developed for fully regeneration of the annulus fibrosus and nucleus pulposus, together or separately, with a long set of different rationales already reported. Recent works show promising biomaterials and processing methods applied to intervertebral disc substitutive or regenerative strategies. Facing the abundance of studies presented in the literature aiming intervertebral disc regeneration it is interesting to observe how cartilaginous endplates have been extensively neglected, being this a major source of nutrients and water supply for the whole disc. Conclusion: Severalinnovative avenues for tackling intervertebral disc degeneration are being reported â from acellular to cellular approaches, but the cartilaginous endplates regeneration strategies remain unaddressed. Interestingly, patient-specific approaches show great promise in respecting patient anatomy and thus allow quicker translation to the clinics in the near future.The authors would like to acknowledge the support provided by the Portuguese Foundation for Science and Technology (FCT) through the project EPIDisc (UTAP-EXPL/BBBECT/0050/2014), funded in the Framework of the “International Collaboratory for Emerging Technologies, CoLab”, UT Austin|Portugal Program. The FCT distinctions attributed to J. Miguel Oliveira (IF/00423/2012 and IF/01285/ 2015) and J. Silva-Correia (IF/00115/2015) under the Investigator FCT program are also greatly acknowledged.info:eu-repo/semantics/publishedVersio

Structured Coculture of Mesenchymal Stem Cells and Disc Cells Enhances Differentiation and Proliferation

PURPOSE: During in vivo stem cell differentiation, mature cells often induce the differentiation of nearby stem cells. Accordingly, prior studies indicate that a randomly mixed coculture can help transform mesenchymal stem cells (MSC) into Nucleus Pulposus cells (NPC). However, because in vivo signaling typically occurs heterotopically between adjacent cell layers, we hypothesized that a structurally organized coculture between MSC and NPC will result in greater cell differentiation and proliferation over single cell type controls and cocultures with random organization. METHODS: We developed a novel bilaminar cell pellet (BCP) system where a sphere of MSC is enclosed in a shell of NPC by successive centrifugation. Controls were made using single-cell type pellets and coculture pellets with random organization. The pellets were evaluated for DNA content, gene expression, and histology. RESULTS: A bilaminar 3D organization enhanced cell proliferation and differentiation. BCP showed significantly more cell proliferation than pellets with one cell type and those with random organization. Enhanced differentiation of MSC within the BCP pellet relative to single cell type pellets was demonstrated by quantitative RT-PCR, histology, and in situ hybridization. CONCLUSIONS: The BCP culture system increases MSC proliferation and differentiation as compared to single-cell type or randomly mixed co-culture controls

Three-dimensional morphology of the pericellular matrix of intervertebral disc cells in the rat

Intervertebral disc cells are surrounded by a pericellular matrix that is biochemically and morphologically distinct from other extracellular matrix regions. Although the function of the pericellular matrix is not fully understood, prior studies of pericellular matrix-chondrocyte regions in articular cartilage (termed ‘chondrons’) suggest that the size, shape, and mechanical properties of the pericellular matrix significantly influence the micromechanical environment of the contained cells. A first step in understanding the role of the pericellular matrix in the intervertebral disc is to quantify the three-dimensional morphology and zonal variations of these regions across the disc. In this study, three-dimensional reconstructions and morphometric measurements of pericellular matrix-cell regions were obtained in situ using fluorescence confocal microscopy of en bloc sections of nucleus pulposus and anulus fibrosus of the rat disc immunolabeled for type VI collagen. The morphology of the pericellular matrix and cells varied significantly across regions, with distinct pericellular matrix aspect ratios (largest/smallest diameter) showing shapes that were generally large and rounded in the nucleus pulposus (average of 1.9), and ellipsoidal and discoidal in the inner (2.4) and outer anulus fibrosus (2.8). The average pericellular matrix volume per cell was found to be significantly larger in the nucleus (6424 µm3) than that of inner (1903 µm3) and outer (1433 µm3) anulus. Pericellular matrix regions containing 1 or 2 cells were the dominant subgroup in the rat intervertebral disc at both 1 and 12 months of age. Multicellular pericellular matrix regions were present more often in the younger nucleus pulposus and outer anulus fibrosus. The orientation of the pericellular matrix regions further varied significantly across the disc, reflecting local collagen matrix architecture. These studies provide new information on the organization and shape of intervertebral disc cells and their surrounding pericellular matrix, which may provide new insights into the mechanisms that regulate cell-matrix interactions

Future perspectives of cell-based therapy for intervertebral disc disease

Intervertebral disc degeneration is a primary cause of low back pain and has a high societal cost. Research on cell-based therapies for intervertebral disc disease is emerging, along with the interest in biological therapy to treat disc disease without reducing the mobility of the spinal motion segment. Results from animal models have shown promising results under limited conditions; however, future studies are needed to optimise efficacy, methodology, and safety. To advance research on cell-based therapy for intervertebral disc disease, a better understanding of the phenotype and differentiation of disc cells and of their microenvironment is essential. This article reviews current concepts in cell-based therapy for intervertebral disc disease, with updates on potential cell sources tested primarily using animal models, and discusses the hurdles to clinical application. Future perspectives for cell-based therapies for intervertebral disc disease are also discussed