Aim:. Right-Handed Girls With Rt-Ais Measured Using Holtain Equipment Have Upper Arm Length Asymmetry (Right-Minus-Left) Which Is: 1) Relatively Longer On Scoliosis Curve Convexity; 2) Significantly Associated With Scoliosis Curve Severity (Cobb Angle And Apical Vertebral Rotation); And 3) Transient, Decreasing With Age And Years After Menarche [1,2]. The Aim Is To Test Whether The Right Upper Arm Length Relative Overgrowth And Spinal Deformity Severity Were Associated With Right Or Left Upper Arm Length Size-For-Age. Method:. 94 Right-Handed Girls With Rt-Ais, Age 11–18 Years, (Mean Cobb Angle 46 Degrees, Range 10–102 Degrees), Were Evaluated Using A Harpenden Anthropometer For Upper Arm Length Asymmetry, Plotted Against Right And Left Upper Arm Length Standard Deviation Scores (Sds), Calculated From 378 Normal Girls, Age 11–18 Years. Results:. The Findings Show That Upper Arm Length Asymmetry Correlates Significantly With Right, But Not Left, Upper Arm Length Sds (Right Arm Spearman's Rho=0.330 P=0.001; Left Arm Rho=−0.013 P=0.902), And With No Other Limb Or Trunk Skeletal Region Sds. Cobb Angle And Avr Also Correlate Significantly With Right, But Not Left, Upper Arm Length Sds. Discussion:. The Abnormal Asymmetry Of Upper Arm Lengths Results From Relative Overgrowth Of Right Upper Arm. We Suggest This Asymmetry Results From An Abnormal Asymmetry Process (Eg Neurogenic) With Growth Velocity That Together Also Initiate The Trunk Deformity, Wherein Additional Factors Contribute To Scoliosis Progression Such As Upright Posture, Melatonin-Signalling Dysfunction And Osteopenia. The Right Upper Arm Length Overgrowth May Provide A Sentinel Of The Relative Anterior Spinal Overgrowth. Conflict Of Interest Statement: No conflict of interest

We undertook a comparative study of magnetic resonance imaging (MRI) vertebral morphometry of thoracic vertebrae of girls with adolescent idiopathic thoracic scoliosis (AIS) and age and gender-matched normal subjects, in order to investigate abnormal differential growth of the anterior and posterior elements of the thoracic vertebrae in patients with scoliosis. Previous studies have suggested that disproportionate growth of the anterior and posterior columns may contribute to the development of AIS. Whole spine MRI was undertaken on 83 girls with AIS between the age of 12 and 14 years, and Cobb’s angles of between 20° and 90°, and 22 age-matched controls. Multiple measurements of each thoracic vertebra were obtained from the best sagittal and axial MRI cuts. Compared with the controls, the scoliotic spines had longer vertebral bodies between T1 and T12 in the anterior column and shorter pedicles with a larger interpedicular distance in the posterior column. The differential growth between the anterior and the posterior elements of each thoracic vertebra in the patients with AIS was significantly different from that in the controls (p < 0.01). There was also a significant positive correlation between the scoliosis severity score and the ratio of differential growth between the anterior and posterior columns for each thoracic vertebra (p < 0.01). Compared with age-matched controls, the longitudinal growth of the vertebral bodies in patients with AIS is disproportionate and faster and mainly occurs by endochondral ossification. In contrast, the circumferential growth by membranous ossification is slower in both the vertebral bodies and pedicles.

Introduction. In patients with adolescent idiopathic scoliosis (AIS), anomalous extra-spinal left-right skeletal length asymmetries in upper limbs, periapical ribs, and ilia beg the question as to whether these bilateral asymmetries are connected in some way with pathogenesis. The upper arm and iliac length asymmetries correlate significantly with adjacent spinal curve severity respectively in thoracic and lower (thoracolumbar and lumbar) spine. In lower limbs, skeletal length asymmetries and proximo-distal disproportion are unrelated to spinal curve severity. Overall, these observations raise questions about mechanisms that determine skeletal bilateral symmetry of vertebrates in health and disorder, and whether such mechanisms are involved in the cause of this disease. We investigated upper arm length (UAL) asymmetries in two groups of right-handed girls aged 11–18 years, with right thoracic adolescent idiopathic scoliosis (RT-AIS, n=98) from preoperative and screening referrals (mean Cobb angle 45°) and healthy controls (n=240). Methods. Right and left UAL were measured with a Harpenden anthropometer of the Holtain equipment, by one of four observers (RGB, AAC, RKP, FJP). UAL asymmetry was calculated as UAL difference, right minus left, in mm. Repeatability of the measurements was assessed by technical error of the measurement (TEM) and coefficient of reliability (R). Results. In girls with RT-AIS, UAL asymmetry was greater than it was in healthy girls (mean 5·9 mm vs 2·5 mm, ANOVA p<0·001, correcting for age), regressed negatively with age (p<0·001, r= –0·374), and correlated significantly with Cobb angle (r=0·342, p=0·001) and apical vertebral rotation (Perdriolle, r=0·291, p=0·004). In healthy girls, UAL asymmetry was unrelated to age. Plotted against years after estimated menarcheal age, right UAL overgrowth reduced significantly for girls with RT-AIS (r= –0·312, p=0·006, n=76) but not for healthy girls (r=0·000, p=0·985, n=121), which was a significant finding (p=0·052, ANOVA). Conclusions. The abnormal overgrowth of right upper arm length may be secondary, or pathogenetically associated with the RT-AIS trunk deformity. The negative regression of UAL asymmetry may result from (1) older girls having less residual growth and/or (2) a transient, or resolving, asymmetry process common to arm and trunk. We hypothesise that the pathogenetic process of RT-AIS may include two components: a transient bilateral asymmetry process and growth velocity, both of which affect trunk and arm growth. In the spine, these rarely lead to scoliosis resolution because biomechanical, postural, melatonin-signalling, and other factors sustain and aggravate the curve. Four pathomechanisms may induce the asymmetry process in trunk and arms involving (1) neuromuscular function, (2) motor cortex, (3) sympathetic nervous system, and (4) intrinsic time-tallies in growth plates, some of which suggest therapeutic possibilities

Aims

This systematic review aims to identify 3D predictors derived from biplanar reconstruction, and to describe current methods for improving curve prediction in patients with mild adolescent idiopathic scoliosis.

Aims

To systematically evaluate whether bracing can effectively achieve curve regression in patients with adolescent idiopathic scoliosis (AIS), and to identify any predictors of curve regression after bracing.

Introduction. Marfan syndrome (MFS) is a common connective tissue disorder affecting one in 3300 people worldwide, and is caused by unique mutations in the 65 exon gene for fibrillin-1—an essential microfibril component of ligaments, tendons, and muscle. A recently discovered feature in the Marfan mouse model is increased concentrations of transforming growth factor β, resulting in overgrowth. 70% of patients with MFS have scoliosis of some degree. Can lessons be learned from MFS aetiology and treatment that apply to idiopathic adolescent scoliosis? We aimed to establish whether there is a relationship between the type and location of mutation, and the presence and degree of severity of scoliosis, in patients with MFS. Methods. Of 181 consecutive patients with MFS with known causative fibrillin-1 mutations, 93 were male (51%) and 88 female (49%). 28 (15%; ten males, 18 females) of the total group had moderate to severe scoliosis, including two females and two males who had corrective surgery. Of the 16 patients with severe scoliosis (three males, 13 females), FBN1 mutations clustered in the latter half of the gene in exons 33–63. Of these 16 mutations, ten were severe (seven stop codons, three splice site mutations); the others were point mutations, three involving added cysteine and three substituted cysteine, in calcium-binding EGF-like regions. Height A rapid adolescent growth spurt to excessive height is a documented clinical feature in MFS. The age of clinical diagnosis as an indication of severity was on average 11·3 years (range 2 days to 36 years), and ten patients were diagnosed before the age of 12 years. Conclusions. Genotype-phenotype correlation for patients with MFS with moderate to severe scoliosis shows the trend/association of severe mutations in 25%, with 50% of the total in the latter half of the gene (exons 33–63) with stop codons and splice site mutations. Cysteine substitutions in calcium binding EGF-like regions occurred in a further 25% of mutations. Disruption of spinal support together with rapid excessive early pubertal growth presents a human model for production of scoliosis, and a rationale for attempted preventive irbesartan therapy in Marfan mouse models and human patients. The 21-centre national AIMS Trial of irbesartan in MFS commences in January, 2011, and skeletal measurements will be of interest

Introduction. Despite extensive research, the cause of adolescent idiopathic scoliosis (AIS) is still largely unclear. Girls with AIS tend to be taller and leaner, and have a lower body-mass index (BMI) and lower bone mass, than do healthy girls. Recent MRI studies have shown the presence of relative anterior spinal overgrowth in girls with AIS. The lower bone mineral status and BMI could be related to dysfunctional central regulation pathway of growth, bodyweight, and bone metabolism. Following several interesting reports on the role of leptin in regulation of the above pathway in animals and human beings, our recent study has shown a low leptin concentration in girls with AIS girls compared with healthy adolescents. This finding leads to our new hypothesis that abnormal leptin bioavailability could be associated with the lower bodyweight, lower bone mineral density, and relatively disproportional endochondral skeletal growth in AIS. This study aimed to investigate the leptin bioavailability in girls with AIS. Methods. 53 girls with AIS and 27 healthy girls (aged 11–16 years) were recruited in this preliminary study. Clinical and anthropometric data were obtained. Blood samples were obtained for ELISA of leptin and soluble leptin receptor (sOB-R). Independent Student's t test and multivariate regression were used in group comparison. Results. The AIS group had significantly lower BMI and longer arm span than did controls. Additionally, girls with AIS had significantly higher soluble leptin receptor concentrations (22·1 ng/mL [□}6·9] vs 17·8 ng/mL [4·4]; p<0·01). However, the leptin concentration (7·6 ng/mL [□}5·3] vs 8·7 ng/mL [□}6·0]) and the leptin/sOB-R ratio (0·38 [□}0·28] vs 0·56 [□}0·47]) were similar to that of the controls. In girls with AIS, the leptin, sOB-R, and the leptin/sOB-R ratio correlated well with bodyweight and BMI. After adjustment for BMI, sOB-R in girls with AIS was significantly higher than in controls (r=0·37, p=0·042). Conclusions. This preliminary report showed that the soluble leptin receptor could be abnormal in girls with AIS. Leptin and sOB-R are related to bodyweight. sOB-R is a major modulator of leptin concentration in circulation, the abnormality of which may lead to the retention of leptin in the circulation and thus abnormal regulatory effect. In this study, girls with AIS had lower BMI and longer arm span, which may reflect the possible change resulting from abnormal leptin bioavailability. Further longitudinal study with larger sample size would be useful to help to understand the long-term effect of the low leptin and high sOB-R in girls with AIS on their bodyweight and skeletal development. It is also noteworthy to study the mechanism of increased sOB-R in AIS

Aims

Significant correction of an adolescent idiopathic scoliosis in the coronal plane through a posterior approach is associated with hypokyphosis. Factors such as the magnitude of the preoperative coronal curve, the use of hooks, number of levels fused, preoperative kyphosis, screw density, and rod type have all been implicated. Maintaining the normal thoracic kyphosis is important as hypokyphosis is associated with proximal junctional failure (PJF) and early onset degeneration of the spine. The aim of this study was to determine if coronal correction per se was the most relevant factor in generating hypokyphosis.

Aims

The aim of this study was to investigate the impact of maturity status at the time of surgery on final spinal height in patients with an adolescent idiopathic scoliosis (AIS) using the spine-pelvic index (SPI). The SPI is a self-control ratio that is independent of age and maturity status.

A self-control ratio, the spine-pelvis index (SPI), was proposed for the assessment of patients with adolescent idiopathic scoliosis (AIS) in this study. The aim was to evaluate the disproportionate growth between the spine and pelvis in these patients using SPI. A total of 64 female patients with thoracic AIS were randomly enrolled between December 2010 and October 2012 (mean age 13 years, standard deviation (sd) 2.17; 9 to 18) and a further 73 healthy female patients with a mean age of 12.4 years (mean age 12.4 years, sd 2.24; 9 to 18), were randomly selected from a normal control database at our centre. The radiographic parameters measured included length of spine (LOS), height of spine (HOS), length of thoracic vertebrae (LOT), height of thoracic vertebrae (HOT), width of pelvis (WOP), height of pelvis (HOP) and width of thorax (WOT). SPI was defined as the ratio LOS/HOP. The SPI and LOT/HOP in patients with AIS showed a significant increase when compared with normal girls (p < 0.001 and p < 0.001 respectively), implying an abnormal pattern of growth of the spine relative to the pelvis in patients with AIS.

No significant difference in SPI was found in different age groups in the control group, making the SPI an age-independent parameter with a mean value of 2.219 (2.164 to 2.239). We also found that the SPI was not related to maturity in the control group.

This study, for the first time, used a self-control ratio to confirm the disproportionate patterns of growth of the spine and pelvis in patients with thoracic AIS, highlighting that the SPI is not affected by age or maturity.

Cite this article: Bone Joint J 2015;97-B:1668–74.