Project description:Intervertebral disc herniation (IVDH) is an important pathology in humans and also in dogs. While the molecular disease mechanisms are well investigated in humans, little is known about the inflammatory mediators in naturally occurring canine IVDH. The objective of this study was to investigate whether the involved proinflammatory cytokines in human IVDH are also key cytokines in canine IVDH and thus to elucidate the suitability of the dog as a model for human trials. 59 samples from 25 dogs with surgically confirmed thoracolumbar IVDH were collected and classified in three subgroups: herniated (H), affected non-herniated (NH) disc, and adjacent non-affected (NA) disc. Discs from 11 healthy dogs acted as controls (C). Samples were analyzed for IL-1, IL-6, IL-8, and TNF-? expression (qPCR/ELISA) as well as cell infiltration and activation of the MAP kinase pathways (immunohistochemistry). Gene and protein expression of all key cytokines could be detected in IVDH affected dogs. Canine IVDH was significantly associated with a higher gene expression of IL-6 (H?>?C, NH?>?C) and TNF-? (H?>?C, NH?>?C, NA?>?C) and a significant down-regulation of IL-1? (H?<?C). Dogs with spontaneous pain had significantly higher IL-6 mRNA compared to those with pain arising only upon palpation. An inter-donor comparison (H and HN relative to NA) revealed a significant increase of IL-6 gene expression (H?>?NA, NH?>?NA). IL-8 (H?>?C, NA?>?C) and TNF-? (NH?>?C) protein levels were significantly increased in diseased dogs while inversely, IL-6 protein levels were significantly higher in patients with better clinical outcome. Aside from resident IVD cells, mostly monocytes and macrophages were found in extruded material, with concomitant activation of extracellular signal-regulated kinase p38 in the majority of samples. Dogs with spontaneous IVDH might provide a useful model for human disc diseases. Although the expression of key cytokines found in human IVDH was also demonstrated in canine tissue, the inflammatory mechanisms accompanying canine IVDH diverges partially from humans, which will require further investigations in the future. In dogs, IL-6 seems to play an important pathological role and may represent a new potential therapeutic target for canine patients.

Project description:Knowledge of the prognosis of acute spinal cord injury is critical to provide appropriate information for clients and make the best treatment choices. Acute intervertebral disc extrusions (IVDE) are a common cause of pain and paralysis in dogs with several types of IVDE occurring. Important prognostic considerations are recovery of ambulation, return of urinary and fecal continence, resolution of pain and, on the negative side, development of progressive myelomalacia. Initial injury severity affects prognosis as does type of IVDE, particularly when considering recovery of continence. Overall, loss of deep pain perception signals a worse outcome. When considering Hansen type 1 IVDE, the prognosis is altered by the choice of surgical vs. medical therapy. Concentration of structural proteins in the plasma, as well as inflammatory mediators, creatine kinase, and myelin basic protein in the cerebrospinal fluid (CSF) can provide additional prognostic information. Finally, cross-sectional area and length of T2 hyperintensity and loss of HASTE signal on MRI have been associated with outcome. Future developments in plasma and imaging biomarkers will assist in accurate prognostication and optimization of patient management.

Project description:Background: Canine intervertebral disc disease (IVDD) represents a significant clinical problem in veterinary medicine, with similarities to the human pathology. Host-derived damage-associated molecular patterns like fibronectin fragments (FnF) that develop during tissue dysfunction may be of specific relevance to IVD pathologies by inducing an inflammatory response in resident cells. Aim: This project aimed to determine the presence and pathobiological role of FnF during IVD herniation in dogs, with a focus on inflammation. Methods: Herniated nucleus pulposus (NP) material from five dogs as well as non-herniated adjacent NP material from three dogs was collected during spinal surgery required due to acute IVD herniation. The presence of different types of FnF were determined by Western blot analysis. NP cells isolated from six herniated canine IVDs were then exposed to 30 kDa FnF. NP cell inflammation and catabolism was examined by investigating the expression of IL-1β, IL-6, IL-8, and COX-2, as well as MMP-1 and MMP-3 by qPCR (all targets) and ELISA (IL-6, PGE2). Results: Amongst multiple sized FnF (30, 35, 45, and >170kDa), N-terminal fragments at a size of ~30 kDa were most consistently expressed in all five herniated IVDs. Importantly, these fragments were exclusively present in herniated, but not in non-herniated IVDs. Exposure of canine NP cells to 500 nM 30 kDa FnF caused a significant upregulation of IL-6 (62.5 ± 79.9, p = 0.032) and IL-8 (53.0 ± 75.7, p = 0.031) on the gene level, whereas IL-6 protein analysis was inconclusive. Donor-donor variation was observed in response to FnF treatment, whereby this phenomenon was most evident for COX-2, with three donors demonstrating a significant downregulation (0.67 ± 0.03, p = 0.003) and three donors showing upregulation (6.9 ± 5.5, p = 0.21). Co-treatment with Sparstolonin B, a TRL-2/TRL-4 antagonist, showed no statistical difference to FnF treatment alone in all tested target genes. Conclusion: Given the presence of the 30 kDa FnF in canine herniated IVDs and the proinflammatory effect of 30 kDa FnF on NP cells, we concluded that the accumulation of FnF may be involved in the pathogenesis of canine IVDD. These results correspond to the findings in humans with IVDD.

Project description:IntroductionInduced pluripotent stem cells (iPSCs) have emerged as a promising cell source for immune-compatible cell therapy. Although a variety of somatic cells have been tried for iPSC generation, it is still of great interest to test new cell types, especially those which are hardly obtainable in a normal situation.MethodsIn this study, we generated iPSCs by using the cells originated from intervertebral disc which were removed during a spinal operation after spinal cord injury. We investigated the pluripotency of disc cell-derived iPSCs (diPSCs) and neural differentiation capability as well as therapeutic effect in spinal cord injury.ResultsThe diPSCs displayed similar characteristics to human embryonic stem cells and were efficiently differentiated into neural precursor cells (NPCs) with the capability of differentiation into mature neurons in vitro. When the diPSC-derived NPCs were transplanted into mice 9 days after spinal cord injury, we detected a significant amelioration of hindlimb dysfunction during follow-up recovery periods. Histological analysis at 5 weeks after transplantation identified undifferentiated human NPCs (Nestin(+)) as well as early (Tuj1(+)) and mature (MAP2(+)) neurons derived from the transplanted NPCs. Furthermore, NPC transplantation demonstrated a preventive effect on spinal cord degeneration resulting from the secondary injury.ConclusionThis study revealed that intervertebral discs removed during surgery for spinal stabilization after spinal cord injury, previously considered a "waste" tissue, may provide a unique opportunity to study iPSCs derived from difficult-to-access somatic cells and a useful therapeutic resource for autologous cell replacement therapy in spinal cord injury.

Project description:We generated iPSCs from human intervertebral disc cells which were obtained during spine fusion surgery of patients with spinal cord injury. The disc cell-derived iPSCs (diPSCs) showed similar characteristics to human embryonic stem cells (hESCs) and were efficiently differentiated into neural progenitor cells (NPCs) with the capability of differentiation into mature neurons in vitro. To examine whether the transplantation of NPCs derived from the diPSCs showed therapeutic effects, the NPCs were transplanted into mice at 9 days post-spinal cord injury. We detected a significant amelioration of hind limb dysfunction during the follow up recovery periods. Histological analysis at 5 weeks post-transplantation, we could identify undifferentiated human NPCs (Nestin+) as well as early (TUJ1+) and mature neurons (MAP2+) derived from the NPCs. Furthermore, the NPC transplantation demonstrated a preventive effect on the spinal cord degeneration resulting from the secondary injury. This study revealed that the intervertebral disc, a M-bM-^@M-^\to-be-wasteM-bM-^@M-^] tissue, removed from the surgical procedure, could provide a unique opportunity to study iPSCs derived from hardly accessible somatic cells in normal situation and also be a useful therapeutic resource to generate autologous neural cells to treat patients suffering from spinal cord injury. Total RNA was isolated using the NucleoSpin RNA II Kit (Macherey-Nagel, Duren, Germany, www.mn-net.com) according to the manufacturerM-bM-^@M-^Ys suggestions and was utilized for a genome-wide gene expression profiling experiment using the Illumina array (Illumina, San Diego, CA, USA, www.illumina.com) at Macrogen (Macrogen, Seoul, Korea, www.macrogen.com).

Project description:Background contextEndplate (EP) injury plays critical roles in painful IVD degeneration since Modic changes (MCs) are highly associated with pain. Models of EP microfracture that progress to painful conditions are needed to better understand pathophysiological mechanisms and screen therapeutics.PurposeEstablish in vivo rat lumbar EP microfracture model and assess crosstalk between IVD, vertebra and spinal cord.Study design/settingIn vivo rat EP microfracture injury model with characterization of IVD degeneration, vertebral remodeling, spinal cord substance P (SubP), and pain-related behaviors.MethodsEP-injury was induced in 5 month-old male Sprague-Dawley rats L4-5 and L5-6 IVDs by puncturing through the cephalad vertebral body and EP into the NP of the IVDs followed by intradiscal injections of TNFα (n=7) or PBS (n=6), compared with Sham (surgery without EP-injury, n=6). The EP-injury model was assessed for IVD height, histological degeneration, pain-like behaviors (hindpaw von Frey and forepaw grip test), lumbar spine MRI and μCT, and spinal cord SubP.ResultsSurgically-induced EP microfracture with PBS and TNFα injection induced IVD degeneration with decreased IVD height and MRI T2 signal, vertebral remodeling, and secondary damage to cartilage EP adjacent to the injury. Both EP injury groups showed MC-like changes around defects with hypointensity on T1-weighted and hyperintensity on T2-weighted MRI, suggestive of MC type 1. EP injuries caused significantly decreased paw withdrawal threshold, reduced axial grip, and increased spinal cord SubP, suggesting axial spinal discomfort and mechanical hypersensitivity and with spinal cord sensitization.ConclusionsSurgically-induced EP microfracture can cause crosstalk between IVD, vertebra, and spinal cord with chronic pain-like conditions.Clinical significanceThis rat EP microfracture model was validated to induce broad spinal degenerative changes that may be useful to improve understanding of MC-like changes and for therapeutic screening.

Project description:Introduction: Canine interverterbral disc (IVD), although physiologically acellular, displays an inflammatory cell population consisting almost exclusively of macrophages (M?) when acutely herniated. M? encompass a heterogenous cell population, roughly divided into classically (M1) or alternatively activated (M2)M?. Polarization into M1 M? leads to strong antimicrobial activity and pro-inflammatory response. In contrast, M2M? exibit anti-inflammatory function and regulate wound healing. The purpose of this study was to characterize the phenotype of the M? population present in naturally occurring IVD herniation. Materials and Methods: IVD material of dogs with IVD disease was collected during standard decompressive surgery. A negative control consisting of IVD material of dogs without IVD degeneration and a positive control consisting of canine liver and lymph node samples were also included. All samples were embedded in OCT and shock frozen. Eight micrometer cryostat sections were prepared, air dried and immunostained without prefixation or permeabilization. CD14 was used as marker M?, MHCII for M1M? and CD206 for M2M?. Results: Fifteen samples of dogs with IVD herniation, 10 negative, and 5 positive control samples were obtained. No positive cell was found in the negative control group. The positive control group displayed several MHCII and CD206 positive cells, all of them being simultaneously positive to CD14. All herniated samples displayed a mixed population of M1M? and M2M?, and some sparse M? displaying markers for both M1 and M2M? simultaneously. Conclusion: The mixed phenotype encountered shows the plasticity and dynamism of M? and evidences the chronic component of IVD disease despite its acute clinical presentation.

Project description:We generated iPSCs from human intervertebral disc cells which were obtained during spine fusion surgery of patients with spinal cord injury. The disc cell-derived iPSCs (diPSCs) showed similar characteristics to human embryonic stem cells (hESCs) and were efficiently differentiated into neural progenitor cells (NPCs) with the capability of differentiation into mature neurons in vitro. To examine whether the transplantation of NPCs derived from the diPSCs showed therapeutic effects, the NPCs were transplanted into mice at 9 days post-spinal cord injury. We detected a significant amelioration of hind limb dysfunction during the follow up recovery periods. Histological analysis at 5 weeks post-transplantation, we could identify undifferentiated human NPCs (Nestin+) as well as early (TUJ1+) and mature neurons (MAP2+) derived from the NPCs. Furthermore, the NPC transplantation demonstrated a preventive effect on the spinal cord degeneration resulting from the secondary injury. This study revealed that the intervertebral disc, a “to-be-waste” tissue, removed from the surgical procedure, could provide a unique opportunity to study iPSCs derived from hardly accessible somatic cells in normal situation and also be a useful therapeutic resource to generate autologous neural cells to treat patients suffering from spinal cord injury.

Project description:BackgroundSpinal growth modulation has been proposed as a non-fusion strategy for treatment of idiopathic scoliosis, although the effect of this treatment modality on intervertebral disc health has not been evaluated in detail. The objectives of this in vivo study were to assess the creation of three-dimensional spinal deformity during six months of growth modulation compared with that in sham-surgery controls, and to compare, with use of magnetic resonance imaging (MRI), gross morphological, histological, and biochemical analyses, disc health between control animals and animals treated with a spinal tether.MethodsSix immature Yucatan mini-pigs underwent anterior spinal instrumentation with vertebral screws connected by a polyethylene tether over four consecutive thoracic vertebrae (T8-T11). An additional six animals underwent sham surgery (screw placement only [the control group]). Radiographs were obtained preoperatively, postoperatively, and monthly thereafter during six months of growth. Computed tomography (CT) and MRI studies were performed ex vivo, and the spines were sectioned for histological and biochemical analyses. Multivariate analysis of variance (MANOVA) was used to compare six-month postoperative data between the control and tethered animals, with the alpha level of significance set at 0.05.ResultsRadiographs and CT images demonstrated the creation of significant three-dimensional deformity (p < 0.013) in the tethered animals compared with the controls. Macroscopic, MRI, and histological evaluation revealed no signs of disc degeneration, with a bulging gelatinous nucleus pulposus, discrete fibrous anular lamellae, and uniformly hyperintense T2-signal intensity within the nuclei pulposi. Biochemical analysis demonstrated no significant difference in the nuclei pulposus between the tethered and control vertebrae; however, the water content (p < 0.001) of both sides of the anulus fibrosus and the glycosaminoglycan content (p < 0.001) of the left side of the anulus fibrosus differed significantly between the two groups.ConclusionsSix months of spinal growth modulation created significant spinal deformity in all three planes compared with what was found in the sham-surgery controls. Although disc health was qualitatively maintained, quantitative changes in the anulus fibrosus water content and the disc height were observed on the side opposite to the tether. These changes likely represent metabolic responses of the discs to compressive loads generated by the flexible tether.

Project description:Preclinical studies involving large animal models aim to recapitulate the clinical situation as much as possible and bridge the gap from benchtop to bedside. To date, studies investigating intervertebral disc (IVD) degeneration and regeneration in large animal models have utilized a wide spectrum of methodologies for outcome evaluation. This paper aims to consolidate available knowledge, expertise, and experience in large animal preclinical models of IVD degeneration to create a comprehensive tool box of anatomical and functional outcomes. Herein, we present a Large Animal IVD Scoring Algorithm based on three scales: macroscopic (gross morphology, imaging, and biomechanics), microscopic (histological, biochemical, and biomolecular analyses), and clinical (neurologic state, mobility, and pain). The proposed algorithm encompasses a stepwise evaluation on all three scales, including spinal pain assessment, and relevant structural and functional components of IVD health and disease. This comprehensive tool box was designed for four commonly used preclinical large animal models (dog, pig, goat, and sheep) in order to facilitate standardization and applicability. Furthermore, it is intended to facilitate comparison across studies while discerning relevant differences between species within the context of outcomes with the goal to enhance veterinary clinical relevance as well. Current major challenges in pre-clinical large animal models for IVD regeneration are highlighted and insights into future directions that may improve the understanding of the underlying pathologies are discussed. As such, the IVD research community can deepen its exploration of the molecular, cellular, structural, and biomechanical changes that occur with IVD degeneration and regeneration, paving the path for clinically relevant therapeutic strategies.