Pelvic pain in Maigne’s syndrome—a multi-segmental approach

Background Maigne’s syndrome is a poorly understood condition that affects the thoracolumbar junction. The symptoms can range from pain in the low back, pelvis, hip, lower abdomen, and groin. These symptoms can have bio-mechanical and neurophysiological attributions due to the complexity of spinal mechanics. Thoraco-lumbar junction (T12-L1) is a transitional zone with a higher degree of mean angular motion and a mean translation motion than T10-T11 and T11-T12. This higher degree of translational and rotation mobility predisposes these segments to a higher degree of stress, making them more prone to biomechanical faults such as dysfunctions and positional faults. These altered static and dynamic mechanics can create a cascade of problems along the biomechanical chain. The co-existence of thoracolumbar junction problems with pelvic pain and dysfunctions strengthens the idea of regional interdependence. Case presentation The patient is a 44-year-old Caucasian male who reported pain in the low back with symptoms radiating to the right hip, iliac region, lower abdomen, and gluteal region. The patient tested positive for Sacroiliac joint dysfunction with both Laslett’s cluster testing and palpatory sacroiliac examination. In addition, the segmental examination showed restriction in thoracolumbar junction with positive skin rolling test and hypomobility in manual segmental testing. Thus, the manual therapy treatment targeted the thoracolumbar junction and sacroiliac joint to address the underlying biomechanical dysfunctions. Conclusions The manual therapy targeting both sacroiliac and thoracolumbar spine can improve pelvic and thoracic spine mobility. In addition, therapeutic exercises can focus on enhancing anterior and posterior chain force generation capacity. This combined approach helped improve functional outcomes with a significant decrease in the Modified Oswestry Disability index and significant improvement on Visual analog scale.

FREQUENCY OF THORACOLUMBAR JUNCTION DYSFUNCTION AMONG EQUESTRIAN POLO ATHLETES

Background: Low back pain among equestrian sports is because of the significant connection between thoracolumbar junction dysfunction (TLJD) and its commencement in equestrian sports; appearing as low back ache spreading out to the adjoining sites and structures. Objective: To determine the frequency of Thoracolumbar Junction Dysfunction (TLJD) among Equestrian Polo Athletes Methods: A descriptive cross-sectional study with a sample size of n=108 was conducted at different polo clubs of Lahore and Islamabad Pakistan for the duration of 6 months from July 2020 to December 2020. Participants were selected via non-probability convenient sampling technique. Male athletes between 18 to 50 years of age, non-competitive with mechanical low back pain were included in the study. Athletes who fulfill the inclusion criteria were assessed using Robert Maigne’s Gold standard examination protocol. SPSS version 21 was used for data entrance and Descriptive analysis was done to present the results of study. Results: The mean age of the subjects was 36.86±6.65 years, duration in sports was 13.58±4.81 in years and frequency of participation in sports was 3.648±0.75 days per week. Total n=108 athletes were examined for TLJD, 66.7% (n=72) were found to be positive with the thoracolumbar junction dysfunction. Conclusion: Thoracolumbar Junction Dysfunction among Equestrian Polo Athletes was an immensely prevailing condition Keywords: Athletes, athletic injuries, dysfunction, overuse injuries.

X-ray and CT scan predictors of damage to the posterior ligamentous complex in fractures of the vertebral bodies of the thoracolumbar junction: systematic review and meta-analysis

Objective of the review was to identify, basing on literature data, the most reliable X-ray and CT signs of damage to the posterior ligamentous complex (PLC) in fractures of the vertebral bodies of the thoracolumbar junction, initially interpreted as type A according to the AOSpine classification. The systematic review was carried out according to the recommendations of PRISMA. The search in PubMed, MEDLINE and Cochrane Library databases revealed 491 articles on relevant issues. Once the inclusion and exclusion criteria have been met, 7 original articles from peer-reviewed scientific journals for the last 10 years were selected for a systematic review, 6 of which were included in the meta-analysis. In all articles, the authors identified two groups of patients: with and without damage to the PLC. The PLC damages were confirmed by MRI and intraoperatively. Radiographic and CT spondylometric parameters were identified, which had statistically significant differences between the groups. To determine predictors of PLC damage, the values of these parameters were subjected to regression analysis. This was followed by a meta-analysis of random and fixed effects models depending on the homogeneity of the data. Statistical heterogeneity was assessed using the X-square test with the null hypothesis of the absence of significant differences in all studies, as well as the heterogeneity index – I2. For the graphical display of the results, forest plots were built. Local kyphosis angle >25°, Cobb angle >16° and difference between interspinous distances >2.54 mm are CT scan predictors of PLC damage. The parameters characterizing the interspinous relationship were studied in no more than two studies, but at the same time they always had statistically significant differences between the groups with and without PLC injuries, therefore, they cannot be ignored during diagnosis. Anterior/posterior vertebral height ratio, anterior vertebral height ratio, sagittal index and suprajacent/subjacent parameters are not the predictors of PLC damage.

Novel Method for Evaluation of Sagittal Spinal Alignment Using Cluster Analysis of Slope of Each Vertebra.

Background: The parameters of sagittal spinal alignment proposed to date measure only the specific sectional angle or the specific sectional distance of the entire spine. To evaluate the alignment of the entire spine without segmentation, we sought to measure and analyze the slope of each vertebral body from skull to pelvis. The purpose of this study was to confirm the effectiveness of this novel analytic method for the evaluation of spinal alignment that considers the slope of each spinal vertebra using graph and cluster analysis.Methods: Every spinal slope from McGregor’s slope to the sacral slope of 88 patients who underwent standing whole spine radiography was measured. Subsequently, we conducted cluster analysis of each spinal slope to understand the characteristics of sagittal alignment.Results: Cluster analysis of whole spinal slopes did not provide useful results in this study because the number of cases per cluster was small due to the large number of parameters. Therefore, we focused the cluster analysis on only the cervical spine slopes. Then, we categorized cervical alignment into four groups (named Normal, Mismatch, Straight, and Sigmoid) based on the results of the cluster analysis. Patients in the Normal and Mismatch groups were older and had lower lumbar apex (L4), apparent lordo-kyphosis around the thoracolumbar junction, and high thoracic kyphosis (TK). Patients in the straight and sigmoid groups were younger, had a higher lumbar apex (L3), flat thoracolumbar junction, and low TK. There was no significant difference between the four groups with respect to pelvic incidence (PI) or pelvic tilt (PT).Conclusion: We proposed a novel method for visually understanding sagittal alignment. Using this analysis method, differences and similarities of sagittal alignment between each group can be easily identified. More detailed analysis of the whole spine may be possible by increasing the number of cases.

Biomechanical evaluation of the pedicle screw insertion depth and role of cross-link in thoracolumbar junction fracture surgery: a finite element study under compressive loads

Introduction. The thoracolumbar junction is one of the most frequently damaged parts of the human spine when exposed to a traumatic factor. Corpectomy in combination with posterior decompression and restoration of the spinal support function is often performed using an interbody implant and posterior transpedicular stabilization to achieve adequate decompression and stabilization in severe traumatic injuries of this level. The surgery of this type is characterized by significant instability of the operated segment and determines increased requirements for the rigidity and reliability of posterior fixation. We have modeled the situation of a two-level corpectomy with subsequent replacement of bodies with a mesh implant and posterior transpedicular stabilization with 8 screws. Objective. To study the stress-strain state of the thoracolumbar spine model after resection of the Th12-L1 vertebrae with different variants of transpedicular fixation under the influence of a compressive load. Materials and methods. A mathematical finite element model of the human thoracolumbar spine has been developed, the components of which are the Th9 ‒ Th11 and L2-L5 vertebrae (vertebrae Th12-L1 are removed), as well as elements of hardware - interbody support and transpedicular system. Four variants of transpedicular fixation were modeled: using short screws and long screws passing through the cortical layer of anterior wall of vertebral body, as well as two cross links and without them. The stress-strain state of the models was studied under the influence of a vertical compressive distributed load, which was applied to the body of the Th9 vertebra and its articular surfaces. The load value was 350 N, corresponding to the weight of the upper body. Results. d It was found that transpedicular fixation of the thoracolumbar vertebrae with the use of long screws reduces the level of tension in the bone elements of the models. In the area of screw entry into the pedicle of the T10, T11, L2 and L3 vertebral arch, the load when using short screws was 3.1, 1.7, 3.9 and 12.1 MPa, respectively, when using bicortically installed screws - 2.9, 1.8, 3.8 and 10.6 MPa. The addition of two cross-links also reduces the maximum load values in critical areas of the model to a certain extent. In case of short screws combination and two cross-links, the load in these areas was 2.8, 1.7, 3.6 and 11.5 MPa, when using bicortical screws and cross-links - 2.8, 1.6, 3.3 and 9.3 MPa. The study of the stress-strain state of other parts of the model revealed a similar trend. Conclusions. The use of long screws with fixation in the cortical bone of anterior part of the vertebral bodies reduces the level of tension in the bone elements of the models. The use of cross links provides greater rigidity to the transpedicular system, that also reduces the tension in the bone tissue.