During intervertebral disc (IVD) maturation, the main cell type shifts from notochordal cells (NCs) to chondrocytelike cells (CLCs). NCs secrete factors with regenerative potential, making them an interesting focus for regenerative treatments. During initial development, these strategies preferably employ non-human donors due to easy availability of their NC-rich nucleus pulposus (NP) tissue. To increase the success of translating these strategies for clinical application, this study aimed to delineate whether NC-secreted factors of different species have a regenerative effect on human CLCs. Human, canine and porcine NC-rich NP tissue and NC-conditioned medium (NCCM) were analysed biochemically and histologically. Human CLC micro-aggregates from degenerated IVDs were cultured in human, canine or porcine NCCM. Collagen, glycosaminoglycan (GAG) and DNA content was determined and histology was performed. Canine and porcine NPs were richer in NCs than human NPs. Human NPs contained the highest collagen content, whereas the DNA and GAG content of canine NPs was significantly higher than that of human or porcine NPs. NCCM from all species significantly increased the DNA and GAG content of the human CLC micro-aggregates. Porcine and canine NCCM were significantly more potent than human NCCM in inducing GAG deposition, whereas only human NCCM induced collagen type II production. Secreted factors from human, canine and porcine NC-rich NPs exerted regenerative effects on human CLCs, indicating a cross-species effect. Bioactive compound(s) are present in NCCM of different species that may reverse human IVD degeneration, supporting further research into strategies based on NC-technology employing canine or porcine models for their translation into humans.
Intervertebral disc (IVD) degeneration is associated with most cases of cervical and lumbar spine pathologies, amongst which chronic low back pain has become the number one cause of loss of quality-adjusted life years. In search of alternatives to the current less than optimal and usually highly invasive treatments, regenerative strategies are being devised, none of which has reached clinical practice as yet. Strategies include the use of stem cells, gene therapy, growth factors and biomaterial carriers. Biomaterial carriers are an important component in musculoskeletal regenerative medicine techniques. Several biomaterials, both from natural and synthetic origin, have been used for regeneration of the IVD in vitro and in vivo. Aspects such as ease of use, mechanical properties, regenerative capacity, and their applicability as carriers for regenerative and anti-degenerative factors determine their suitability for IVD regeneration. The current review provides an overview of the biomaterials used with respect to these properties, including their drawbacks. In addition, as biomaterial application until now appears to have been based on a mix of mere availability and intuition, a more rational design is proposed for future use of biomaterials for IVD regeneration. Ideally, high-throughput screening is used to identify optimally effective materials, or alternatively medium content comparative studies should be carried out to determine an appropriate reference material for future studies on novel materials.
Hydrogels can facilitate nucleus pulposus (NP) regeneration, either for clinical application or research into mechanisms of regeneration. However, many different hydrogels and culture conditions for human degenerated NP have been employed, making literature data difficult to compare. Therefore, we compared six different hydrogels of natural polymers and investigated the role of serum in the medium and of osmolarity during expansion or redifferentiation in an attempt to provide comparators for future studies. Human NP cells of Thompson grade III discs were cultured in alginate, agarose, fibrin, type II collagen, gelatin methacryloyl (gelMA), and hyaluronic acid-poly(ethylene glycol) hydrogels. Medium containing fetal bovine serum and a serum-free (SF) medium were compared in agarose, gelMA, and type II collagen hydrogels. Isolation and expansion of NP cells in low compared to high osmolarity medium were performed before culture in agarose and type II collagen hydrogels in media of varying osmolarity. NP cells in agarose produced the highest amounts of proteoglycans, followed by cells in type II collagen hydrogels. The absence of serum reduced the total amount of proteoglycans produced by the cells, although incorporation efficiency was higher in type II collagen hydrogels in the absence than in the presence of serum. Isolation and expansion of NP cells in high osmolarity medium improved proteoglycan production during culture in hydrogels, but variation in osmolarity during redifferentiation did not have any effect. Agarose hydrogels seem to be the best option for in vitro culture of human NP cells, but for clinical application, type II collagen hydrogels may be better because, as opposed to agarose, it degrades in time. Although culture in SF medium reduces the amount of proteoglycans produced during redifferentiation culture, isolating and expanding the cells in high osmolarity medium can largely compensate for this loss.
Intervertebral disc (IVD) degeneration causes low-back pain through disc compression, prolapse and herniation. Inflammation of the IVD and subsequent degeneration produce altered glycosylation profiles in several animal models of IVD injury and ageing, although the function of this altered glycosylation pattern in a human is unknown. Altered N-glycome, specifically sialylated and fucosylated N-glycosylation motif expression, might play a role in inflammation and disease progression. Healthy (foetal and adolescent idiopathic scoliosis) and degenerated (lumbar degeneration) human IVD glycosylation patterns were studied using lectin histochemistry. Small-molecule fluorinated sugar analogues (3Fax-Peracetyl Neu5Ac; 2F-Peracetyl-Fucose) were used to inhibit sialylation and fucosylation in an in vitro model of inflammation, to investigate their effects on the glycosignature, cell metabolism, extracellular matrix synthesis and cell migration. The effects of interleukin (IL)-1β, tumour necrosis factor (TNF)-α and IL-6 on glycosylation in human nucleus pulposus cells were investigated by lectin histochemistry, PCR and enzyme-linked immunosorbent assay (ELISA). In the in vitro model of IVD degeneration, cytokine-induced inflammation-induced hypersialylation was observed, as indicated by Sambucus nigra I binding. However, this modification was inhibited by the sialyltransferase inhibitor. Inhibition of sialylation and fucosylation modulates cell migration and protein translation of catabolic enzymes in response to inflammation. The altered patterns of glycosylation in human tissue in degeneration was consistent with previous IVD studies in murine, bovine and ovine models. The present study was the first functional investigation of glycosylation in human degenerated IVD, elucidating the role of the glycome in disease progression and identified potential therapeutic targets for future regenerative therapies.
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