From the many human studies that attempt to identify genes for adolescent idiopathic scoliosis (AIS), the view emerging is that AIS is a complex genetic disorder with many predisposing genes exhibiting complex phenotypes through environmental interactions. Although advancements in genomic technology are transforming how we undertake genetic and genomic studies, only some success has been reached in deciphering complex diseases such as AIS. Moreover, the present challenge in AIS research is to understand the causative and correlative effects of discovered genetic perturbations. An important limitation to such investigations has been the absence of a method that can easily stratify patients with AIS. To overcome these challenges, we have developed a functional test that allows us to stratify patients with AIS into three functional subgroups, representing specific endophenotypes. Interestingly, in families with multiple cases of AIS, a specific endophenotype is shared among the affected family members, indicating that such a transmission is inherited. Moreover, increased vulnerability to AIS could be attributable to sustained exposure to osteopontin (OPN), a multifunctional cytokine that appears to be at the origin of the Gi-coupled receptor signalling dysfunction discovered in AIS. We examined the molecular expression profiles of patients with AIS and their response to OPN. Osteoblasts isolated from patients with AIS were selected for each functional subgroup and compared with osteoblasts obtained from healthy matched controls. We used the latest gene chip human genome array Affymetrix (HuU133 Plus 2.0 array) that allows for the analysis of the expression level of 38 000 well characterised human genes. Raw data were normalised with robust multiarray analysis method. Statistical analysis was done by the EB method with FlexArray software. Selection criteria for in-depth analysis include the magnitude of change in expression (at least □} 3-fold) and 5% false discovery rate as stringency selection. Validation of selected candidate genes was done by qPCR and at the protein level by Western blot and ELISA methods. Plasma OPN concentrations were measured by ELISA on a group of 683 consecutive patients with AIS and were compared with 262 healthy controls and 178 asymptomatic offspring, born from at least one scoliotic parent, and thus considered at risk of developing the disorder. The regulation of OPN signalling pathway in normal and AIS cells were validated in vitro by cellular dielectric spectroscopy (CDS).Introduction
Methods
Current research strategies for studying articular cartilage (AC) repair include the observation of chondrocyte behaviour in monolayer cultures, the use of artificial matrices and animal models. Since AC relies on the diffusion of joint synovial fluid for nourishment, we hypothesised that it should be possible to develop a research model in which full-depth AC explants are maintained under established tissue culture conditions. Successful maintenance of explants for prolonged periods of time would represent a novel approach and provide a very powerful research tool to address a wide range of chondrocyte biology and matrix synthesis questions. The objective of the project was to examine the cell viability within an AC explant model maintained in tissue media. AC samples were obtained from the femoral condyles of total knee arthroplasty patients. Cylindrical dowels (10mm in diameter) were harvested from these samples. The dowels consisting of full-depth AC with several mm of subchondral bone attached were placed in tissue culture flask (T-25) containing 15mls of the respective culture media and maintained at 37oC in an incubator containing 5% CO2. Dowels were cultured in a variety of different media formulations (DMEM/F12, CGM (chondrocyte growth medium)) as well as PBS (phosphate buffered saline) which served as a negative control. AC chondrocyte viability was evaluated after five weeks. After having determined the best medium for cartilage maintenance, a second study with a broader range of end-points was undertaken. All dowels collected, rated 2/4 on the Outerbridge scale for osteoarthritis, and were then grown for zero, four, eight or twelve weeks in DMEM/F12 and CDM (chondrocyte differentiating medium). At each time interval, the dowels were evaluated for viability (live/dead stain), general morphology (trichrome stain), distribution of matrix proteins and proteoglycans (aggrecan, Types I and II collagen – immunofluorescence). After five weeks in PBS, there were no viable cells in the explant. Viability in the explants maintained in DMEM/F12 was 71% compared to 59.6% in the CGM treatment. The viability of the cells in the second study was 90% with DMEM/F12. After twelve weeks, the explant models stained well for general morphology and the distribution of proteoglycans and collagen was well maintained. To our surprise, the DMEM/F12 medium actually demonstrated the highest cell viability. Typically, AC requires joint motion to pressurise the synovial fluid into the matrix, which augments the transport of nutrients to the cells. Given that this study did not include any form fluid pressurization, it is surprising that such high cell viability was observed. This suggests that passive diffusion alone may provide adequate nourishment in this model system. In conclusion, the explant model for studying AC damage and repair examined in this research appears to be quite promising. This novel approach may serve as the foundation for subsequent research into new treatment strategies for AC injury.
Articular cartilage (AC) has a poor innate healing capacity following significant injury. Autologous chondrocyte implantation is a repair technique which utilises in vitro-expanded chondrocytes combined with a periosteal patch. The chondrocytes are enzymatically digested from arthroscopically harvested tissue at an initial surgery and expanded in monolayer culture prior to implantation at a second procedure. Unfortunately, in vitro expanded chondrocytes appear unable to retain their fundamental phenotype resulting in dedifferentiated cells which produce a matrix of inferior quality. This study compares the matrix-component gene expression profiles of chondrocytes in their native chondrons and through multiple divisions in monolayer culture. We hypothesised that there would be a rapid decline of matrix-component gene expression within a few cell replications in monolayer culture. The goal is to understand more fully the process of chondrocyte dedifferentiation and to compare matrix-component gene expression during cellular expansion in vitro. Human AC was obtained from tissue donors and operative patients. A portion of the AC was stored at −80°C for use as a control while the remainder was homogenised and enzymatically digested with collagenase. The released cells were plated in monolayer culture and passaged (2:1) when they approached confluence. RNA was extracted from the frozen cartilage control and the passaged chondrogenic cell lines from which cDNA was generated. Real time PCR was performed with primers specific for collagen I, collagen II, aggrecan, and GAPDH. Gene expression was quantified and profiles from the cells in their native chondron and passaged cells (p0-p9) were compared. Cells, when removed from the extra-cellular matrix and plated in monolayer, experienced an immediate upregulation of collagen I which persisted throughout all passages. In contrast, there was a stepwise decrease in collagen II with each successive passage until p8-p9 when the expression became undetectable. Aggrecan expression only decreased minimally as the cells were passaged. Rapid dedifferentiation of monolayer cultured chondrocytes is a persistent barrier to AC tissue engineering including ACI. This study quantified the expression of relevant genes relating to AC generation and is an important first step to understanding cellular events, as alternative expansion techniques and cellular alternatives are sought.
Research project supported by La Fondation Yves Cotrel de l’Institut de France
To develop a model that incorporates pedicle growth and growth modulation into an existing finite element model of the thoracic and lumbar spine already integrating vertebral growth and growth modulation Using the model to investigate whether pedicle asymmetry, either alone or combined with other deformations, could be involved in scoliosis pathomechanisms.
Vertebral growth remains a mystery, especially with regards to the contribution of different growth plates and the mechanisms of growth after closure of these plates. As an example of vertebral growth in general, the growth of the vertebral canal was assessed in a rat model using fluorochromes. Although 80–90% of vertebral canal growth was due to growth plates, the remaining canal growth occurred via periosteal absorption and deposition. This is contrary to the traditional idea that periosteal mechanisms do not change the shape or dimensions of bone and suggests that the vertebrae exhibit a different model of growth than typical bones. Vertebral growth remains largely a mystery. The contributions of different growth plates and the mechanisms of growth after closure of these plates requires further exploration. As an example of vertebral growth, vertebral canal growth was assessed in a living rat model using fluorochromes. Vertebral canal growth and presumably vertebral growth in general occurred by different mechanisms at different phases of development. Growth plates accounted for the majority of growth although periosteal mechanisms also resulted in changes in the size and shape of the vertebrae. This is contrary to the traditional concept of periosteal growth and suggests that vertebrae may exhibit a different model of growth than typical bones. The growth of the vertebrae in a particular dimension and during a particular phase of development is dependent on different mechanisms of growth, which may play a role in interpreting vertebral growth anomalies. The interspinous junction closed by the end of the first week, whereas the neurocentral junction closed between weeks three and four. By four weeks, the vertebral canal had achieved 80–90% of its growth in area and diameter. After growth plate closure, the canal continued to grow by periosteal mechanisms and was displaced posteriorly. Thirty-six Sprague-Dawley rats (age one week-seven weeks) were injected with tetracycline and alizarin using a dosing interval of four days. Thoracic vertebrae were sectioned using a cryostat and examined under a fluorescence microscope. In addition to noting fluoro-chrome deposition, the dimensions of the growth plates and canal were noted.
This study was designed to examine the components of the MR image of the neurocentral junction (NCJ) and to explore the discrepancy between the age of closure of the NCJ as determined by anatomic and imaging studies. MR images of one hundred and fourteen porcine NCJs were correlated with anatomic and histologic sections. Whereas gross anatomic visualization did not reveal the NCJ site, MRI was sensitive for cartilage detection and accurately determined the age of NCJ closure although it overestimated the extent of closure. Based on this study, MRI characterization of the NCJ appears reliable and the NCJ cartilage does not close until adolescence. This study examined the composition of the MR image of the neurocentral junction (NCJ) and the discrepancy between the age of closure of the NCJ as determined by anatomic and imaging studies.
MRI was sensitive for cartilage detection and accurately determined the age of NCJ closure (i.e. absence of cartilage on histologic examination). MRI underestimated the extent of NCJ closure, with NCJs in the process of closure often presenting as completely open on MRI. MRI and histologic characterization of the NCJ provided better description of closure patterns than anatomic examination. Disparate NCJ development has been implicated as a potential cause of adolescent idiopathic scoliosis. Whereas autopsy studies have refuted this theory by suggesting that the NCJ closes before adolescence, MRI studies have resurrected this idea by suggesting later closure. MRI-histologic correlation suggests that the NCJ cartilage remains present until adolescence and therefore further exploration of the disparate growth hypothesis is required. Gross anatomic visualization did not reveal the NCJ site, even after removal of the periosteum. In contrast, the presence or absence of an NCJ image correlated with the presence or absence of cartilage although MRI overestimated the extent of this cartilage. Vertebrae were grossly examined for any evidence of the NCJ site. Sagittal and transverse MR images of one hundred and fourteen porcine NCJs in various stages of development (thirty-eight open, sixty-four closing, twelve closed) were correlated with anatomic and histologic sections acquired at the same position.
Introduction: No appropriate animal model for studying adolescent idiopathic scoliosis (AIS) exists and this hampers research. In recent years, we have been examining a model in which scoliosis consistently develops in young chickens following pinealectomy and which has been shown to have many characteristics similar to those seen in AIS. Not all of the pinealectomised chickens develop scoliosis following the pinealectomy and so we have the opportunity to examine differences between the two groups. The obvious candidate for study of the mechanism underlying this phenomenon is melatonin which is the principal product of the pineal gland. In this study we have measured the serum melatonin levels of pinealectomised chickens that have developed scoliosis and compared these with similar measurements taken from chickens that have developed scoliosis. Methods and results: Newly-hatched chickens were obtained from a local hatchery and kept in a single pen with standard heating and lighting. A 12:12 light dark cycle was introduced immediately and the two-thirds of the chickens were pinealectomised three days later. The remainder acted as controls. At weekly intervals following surgery, the chickens were radiographed in a supine position while anaesthetised and the presence of scoliosis was determined from the radiographs. Three weeks after surgery the chickens were euthanised and blood samples were collected and analysed using radioimmunological techniques to determine levels of serum melatonin. The samples were collected in the presence of red light in the middle of the dark cycle when melatonin levels have been shown to be at their highest. Approximately 55% of the pinealectomised chickens developed scoliosis within the three weeks following surgery whereas none of the control chickens developed scoliosis. The results showed that the serum melatonin levels of pinealectomised chickens were significantly lower than the normal controls and were in fact all close to zero. However, there was no significant difference in serum melatonin levels between those chickens that developed scoliosis and those that did not. Conclusion: The results of this study have shown that pinealectomy significantly reduces serum melatonin levels close to zero in all chickens. The results also show that there is no significant difference in serum melatonin levels between those pinealectomised chickens that develop scoliosis and those that do not. Unless there is a subtle threshold level that is unable to be detected using our methodology or that melatonin levels in the days immediately after surgery are of critical importance, these results suggest that other causes for this phenomenon need to be examined. An understanding of the underlying cause would be of great importance and might represent a significant breakthrough in the study of AIS.
Introduction: Although there are several known causes of scoliosis, most are of unknown cause and develop during adolescence, making adolescent idiopathic scoliosis (AIS) the most common form. It has long been hypothesised that unilateral closure of the neurocentral junction accompanied by continued growth on the opposite side could lead to vertebral rotation and subsequent lateral curvature. However, autopsy studies of neurocentral junction closure in children has revealed that these joints close at approximately six years of age consequently excluding this hypothesis as a cause of AIS. In contrast, a recent MRI study has suggested that in some children at least, the NCJ does not close until much later in development around the time of puberty thereby resurrecting this hypothesis as a potential cause of AIS. This study was designed to investigate closure time and pattern of closure of the NCJ in normal patients to determine whether further examination of this hypothesis might be warranted. Methods and results: The morphology of the NCJs in 20 patients between the ages of 3 and 15 were observed in MR images taken for purposes other than spinal anomaly. The structure of individual NCJs were observed and reconstructed in 3-dimensions. The age at which NCJs became closed was determined and pattern of closure of a typical NCJ was created using the reconstructed images. The pattern of closure of the NCJs along the vertebral column was also determined and any differences between right and left sides at the same level was also noted. The results showed that there was a sequence of closure along the vertebral column for the NCJs with those in the cervical and lumbar regions being the first to close and those at the approximate level of T8 being the last to close. While the NCJs in the cervical and lumbar regions close at 5–6 years of age, those in the thoracic region, that are the last to close, do so at approximately 12 years of age. No significant difference between the stage of closure of the left and right sides was seen at any level. Conclusion: The results of this study have shown that the closure of the NCJs in those vertebrae that form at approximately the most common level for the apical vertebra associated with AIS (midthoracic) does not occur until the time of puberty. This contrasts sharply with previously held views on the age of closure. Although no significant difference in closure between left and right sides was seen among these particular patients it does not exclude unilateral closure as a cause of AIS at least in some patients. These results suggest that examination of this hypothesis should be resurrected and that further study is well warranted. MR examination of young patients with small, initial curves could be well worthwhile.