Low back pain (LBP) is a worldwide leading cause of disability. This preclinical study evaluated the safety of a combined advanced therapy medicinal product developed during the European iPSpine project (#825925) consisting of mesendoderm progenitor cells (MEPC), derived from human induced pluripotent stem cells, in combination with a synthetic poly(N-isopropylacrylamide) hydrogel (NPgel) in an ovine intervertebral disc degeneration (IDD) model. IDD was induced through nucleotomy in 4 adult sheep, 5 lumbar discs each (n=20). After 5 weeks, 3 alternating discs were treated with NPgel (n=6) or NPgel+MEPC (n=6). Before sacrifice, animals were subjected to: MRI of lumbar spines (disc height and Pfirmann grading); blood sampling (hematological, biochemical, metabolic and lymphocyte/monocytes immunological). After 3 months the sheep were sacrificed. The spines were processed for: macroscopic morphology (Thompson grading), microscopic morphology (Histological grading), and glycosaminoglycan content (GAG, DMMB Assay). Furthermore, at sacrifice biodistribution of human MEPC was assessed by Alu-sequences quantification (qPCR) from three tissue samples of heart, liver, spleen, brain, lungs, and kidneys, and PBMCs collected to assess activation of systemic immune cells. To each evaluation, appropriate statistical analysis was applied.Introduction
Method
Tryfonidou leads the Horizon 2020 consortium (iPSpine; 2019–2023) bringing a transdisciplinary team of 21 partners together to address the challenges and bottlenecks of iPS-based advanced therapies towards their transition to the clinic. Here, chronic back pain due to intervertebral disc degeneration is employed as a show case. The project develops the iPS-technology and designed smart biomaterials to carry, protect and instruct the iPS cells within the degenerate disc environment. This work will be presented including ongoing activities focus on translating the developed methodology and tools towards clinically relevant animal models. The consortium optimized the protocol for the differentiated iPS-notochordal-like cells (iPS-NLCs) and shortlisted two biomaterials shortlisted based on their physicochemical, cytotoxicity, biomechanical and biocompatibility testing. Both were shown to be safe and have been tested with the progenitors of iPS-NLCs. An advanced platform (e.g., the dynamic loading bioreactor for disc tissue) was used to evaluate their performance: the biomaterials supported the iPS-NLC progenitors after injection into the degenerate disc and seem to also support their maturation towards NLCs. Furthermore, we confirmed the capacity of these cells to survive inside degenerated discs at 30 days upon injection in sheep, whereafter we continued with their evaluation at 3 months post-injection. We achieved full evaluation of the sheep spines, including biomechanical analysis using the portable spine biomechanics tester prior analysis at the macro- and microscopic, and biochemical level.
Within the field of disc degeneration-related low back pain, the spine community has been increasingly acknowledging the regenerative potential of extracellular vesicles (EVs). EVs are small lipid bilayer-delimited particles naturally released by cells, involved in intercellular signaling. They do so by interacting with recipient cells and releasing their biological cargo (e.g., mRNA, miRNA, DNA, protein, lipid) EVs derived from mesenchymal stromal cells and, more recently, also EVs from notochordal cells, the cells residing within the core of the juvenile human disc, are being actively studied. In general, they have been proposed to mitigate inflammation/catabolic processes, reduce apoptosis, stimulate proliferation and even improve the matrix producing capacity of the treated cells. Within this context, appropriate characterization of EVs is essential to increase the level of evidence that the reported effects are indeed EV-associated. To analyze the purity and biochemical composition of EV preparations the International Society for Extracellular Vesicles (ISEV) has prepared guidelines recommending the analysis of multiple (EV) markers, as well as proteins co-isolated/recovered with EVs. Alongside, to prove that the effects are EV-associated and not due to co-isolated factors from the tissue or cells used to derive the EVs, appropriate technical controls need to be taken along (during cell/tissue culture). As such the question arises: “what is the evidence so far?” While from a fundamental perspective EVs are very appealing, the use of natural EVs in clinical applications is challenging. It comes with drawbacks, including biologic variability, yield, cumbersome isolation, and challenging upscaling and storage to achieve industrial levels. To date there is no FDA-approved EV-based therapy for disc-related lower back pain. Nonetheless, EV-based therapeutic approaches have unique advantages over the use of (pluripotent) stem cell-based therapies, such as a high biologic, but low immunogenic and tumorigenic potential.
Low back pain resulting from Interertebral disc (IVD) degeneration is a serious worldwide problem, with poor treatment options available. Notochordal (NC) cells, are a promising therapeutic cell source with anti-catabolic and regenerative effect. However, their behaviour in the harsh degenerate environment is unknown. Porcine NC cells (pNCs), and Human NP cells from degenerate IVDs were cultured in alginate beads to maintain phenotype. Cells were cultured alone or in combination, or co-stimulated with notochordal cell condition media (NCCM), in media to mimic the healthy and degenerate disc environment, together with controls for up to 1 week. Following culture viability, qPCR and proteomic analysis using Digiwest was performed. A small increase in pNC cell death was observed in degenerated media compared to standard and healthy media, with a further decrease seen when cultured with IL-1β. Whilst no significant differences were seen in phenotypic marker expression in pNCs cultured in any media at gene level (ACAN, KRT8, KRT18, FOXA2, COL1A1 and Brachyury). Preliminary Digiwest analysis showed increased protein production for Cytokeratin 18, src and phosphorylated PKC but a decrease in fibronectin in degenerated media compared to standard media. Human NP cells cultured with NCCM, showed a decrease in IL-8 production compared to human NP cells alone when cultured in healthy media. However, gene expression analysis (ACAN, VEGF, MMP3 and IL-1β) demonstrated no significant difference between NP only and NP+NCCM groups. Studying the behaviour of the NCs in in vitro conditions that mimic the in vivo healthy or degenerate niche will help us to better understand their potential for therapeutic approaches. The potential use of NC cell sources for regenerative therapies can then be translated to investigate the potential use of iPSCs differentiated into NC cells as a regenerative cell source.
Low back pain is strongly associated with degeneration of the intervertebral disc (IVD). During degeneration, altered matrix synthesis and increased matrix degradation, together with accompanied cell loss is seen particularly in the nucleus pulposus (NP). It has been proposed that notochordal (NC) cells, embryonic precursors for the cells within the NP, could be utilized for mediating IVD regeneration. However, injectable biomaterials are likely to be required to support their phenotype and viability within the degenerate IVD. Therefore, viability and phenotype of NC cells were analysed and compared within biomaterial carriers subjected to physiological oxygen conditions over a four-week period were investigated. Porcine NC cells were incorporated into three injectable hydrogels: NPgel (a L-pNIPAM-co-DMAc hydrogel), NPgel with decellularized NC-matrix powder (dNCM) and Albugel (an albumin/ hyaluronan hydrogel). The NCs and biomaterials constructs were cultured for up to four weeks under 5% oxygen (n=3 biological repeats). Histological, immunohistochemical and glycosaminoglycans (GAG) analysis were performed to investigate NC viability, phenotype and extracellular matrix synthesis and deposition. Histological analysis revealed that NCs survive in the biomaterials after four weeks and maintained cell clustering in NPgel, Albugel and dNCM/NPgel with maintenance of morphology and low caspase 3 staining. NPgel and Albugel maintained NC cell markers (brachyury and cytokeratin 8/18/19) and extracellular matrix (collagen type II and aggrecan). Whilst Brachyury and Cytokeratin were decreased in dNCM/NPgel biomaterials, Aggrecan and Collagen type II was seen in acellular and NC containing dNCM/NPgel materials. NC containing constructs excreted more GAGs over the four weeks than the acellular controls. NC cells maintain their phenotype and characteristic features in vitro when encapsulated into biomaterials. NC cells and biomaterial construct could potentially become a therapy to treat and regenerate the IVD.
Intervertebral disc (IVD) degeneration accompanying with low back pain is a serious worldwide problem. Even though, surgical treatments are available for pain relief, there is an urgent need to establish enduring cell-based remedies. Notochordal (NC) cells as the ancestor of nucleus pulposus (NP) cells in human IVD are a promising therapeutic target. It has been reported that the loss of NC cells after childhood could promote the onset of disc degeneration. Thus, we firstly, aimed to optimise the culture of NC cells in vitro without using the FCS in alginate (3D) culture systems, secondly, investigate their behaviour in healthy and degenerate niche and lastly, co-culture these cells with degenerated NP cells to assess their regeneration potentials. Porcine NC cells were extracted using pronase treatment followed by overnight digestion in 0.01% collagenase II. After extraction, cells were culture in 1.2% alginate beads (gold standard 3D culture) in either low glucose DMEM or αMEM medium. Cells were harvested after 24 hours, 1 week and 2 weeks for gene expression analysis and formalin fixed paraffin embedding. Quantitative Real-Time PCR and Immuno-staining were performed for analysis of NC markers (KRT18, FOXA2 and T) and COL I as a negative marker. Next, NC cells were cultured in healthy and degenerate medium to assess their viability and behaviour.Introduction and Objective
Materials and Methods