Anterior vertebral body tethering (AVBT) is a growth modulating procedure used to manage idiopathic scoliosis by applying a flexible tether to the convex surface of the spine in skeletally immature patients. The purpose of this study is to determine the preliminary clinical outcomes for an adolescent patient cohort. 18 patients with scoliosis were selected using a narrow selection criteria to undergo AVBT. Of this cohort, 11 had reached a minimum follow up of 2 years, 4 had reached 18 months, and 3 had reached 6 months. These patients all demonstrated a primary thoracic deformity that was too severe for bracing, were skeletally immature, and were analysed in this preliminary study of coronal plane deformity correction. Using open-source image analysis software (ImageJ, NIH) PA radiographs taken pre-operatively and at regular follow-up visits post-operatively were used to measure the coronal plane deformity of the major and compensatory curves. Pre-operatively, the mean age was 12.0 years (S.D. 10.7 – 13.3), mean Sanders score 2.6 (S.D. 1.8-3.4), all Risser 0 and pre-menarchal, with mean main thoracic Cobb angle of 52° (S.D. 44.2-59.8°). Post-operatively the mean angle decreased to 26.4° (S.D. 18.4-32°) at 1 week, 30.4° (S.D. 21.3-39.6°) at 2 months, 25.7° (S.D. 18.7-32.8°) at 6 months, 27.9° (S.D. 16.2-39.6°) at 12 months, and 36.8° (S.D. 22.6– 51.0°) at 18 months and 38.2° (S.D. 27.6-48.7°) at 2 years. The change in curve at 2 years post-operative was statistically significant (P=0.004). There were 4 tether breakages identified that did not require return to theatre as yet, one patient underwent a posterior spinal instrumented fusion due to curve progression. AVBT is a promising new growth modulation technique for skeletally immature patients with progressive idiopathic scoliosis. This study has demonstrated a reduction in scoliosis severity.
The relationship between radiologic union and clinical outcome in thoracoscopic scoliosis surgery is not clear, as apparent non-union does not always correspond to a poor clinical result. Our aim was to evaluate CT fusion rates 2yrs after thoracoscopic surgery, and explore the relationship between fusion scores and; (i) rod diameter, (ii) graft type, (iii) fusion level, (iv) implant failure, and (v) lateral position in disc space. Between 2000 and 2006 a cohort of 44 patients had thoracoscopic scoliosis correction. Discectomies were performed and defect was packed with either autograft (n=14) or allograft (n=30). Instrumentation consisted of either 4.5mm (n=24) or 5.5mm (n=20) single titanium anterior rod and vertebral body screws. Fusion quality and implant integrity were evaluated 2yr following surgery using low-dose CT. At each disc space, left, right and mid-sagittal CT reconstructions were generated and graded using the Sucato 4-point scale (Sucato, 2004) which is based on calculated percentage of fusion across disc space. Fusion scores were measured for 259 disc spaces in 44 patients. Rod diameter had a strong effect on fusion score, with a mean score of 2.12±0.74 for 4.5mm Ti rod, decreasing to 1.41+0.55 for 5.5mm Ti rod, and to 1.09+0.36 for 5.5mm Ti-alloy rod. Mean fusion scores for autograft and allograft subgroups were 2.13±0.72 and 2.14±0.74 respectively. Fusion scores were highest in the middle of implant construct, dropping off by 20–30% toward the ends. Fusion scores adjacent to the rod (2.19±0.72) were significantly higher than on the contralateral side of the disc (1.24±0.85). Levels where rod fracture occurred (n=11) had lower fusion scores than those without fracture (1.09±0.67 vs 1.76±0.80). Levels where top screw pullout occurred (n=6) had lower CT fusion scores than those without (1.25±0.60 vs 1.83±0.76). Rod diameter (larger), intervertebral level (proximal or distal), lateral position in disc (further from rod) and rod fracture or screw pullout all reduce fusion scores, while graft type does not affect scores. The assumed link between higher fusion score and better clinical outcome must be treated with caution, because rod fractures did not necessarily occur in patients with lower fusion scores. It is possible that with a stiffer rod, less bony fusion mass is required for a stable construct. We propose that moderate fusion scores secure successful clinical outcomes in thoracoscopic scoliosis surgery.
Luk (Luk et al. Spine vol 23(21) 2303-2307 1998) has shown that in posterior surgery, the correction achieved can be predicted by fulcrum bending films. The relevance to anterior correction has been disputed, as this commonly involves shortening the spine by the removal of intervertebral discs. The aim of the study was to see whether the pre-operative bending angle reflected the degree of correction achieved. 91 patients with a structural thoracic curve had an anterior endoscopic correction using a single rod. The mean age was 16.1 years. (range 10-46) The majority of curves were Lenke type 1 (79%) or Type 2 (8%). In all cases disc clearance and bone grafting were performed. All had pre-operative fulcrum bending films. The mean Cobb angle achieved at the pre-operative bending film was compared with the post-operative correction at 2 months. The FBCI (Fulcrum Bending Correction Index) and correction rates were also calculated. The FBCI is calculated by dividing the correction rate by the fulcrum flexibility and expressed as a percentage. It takes into account the pre-operative flexibility of the curve.Introduction
Method
1. To evaluate how radiological parameters change during the first 3 years following anterior endoscopic surgery. 2. To report complications encountered in this period. Between April 2000 and June 2006,106 patients underwent an anterior endoscopic instrumented fusion. There were 95 females and 11 males. Average age was 16.1 years (range 10-46). 103 (97%) had right-sided idiopathic curves. The majority were Lenke type 1 (79%). Patients were assessed at 3, 6, 12, 24, and 36 months. 83 patients had 1 year follow-up, 69 had 2 years or more. The following were investigated; the structural curve, instrumented curve, non-structural curves, skeletal age at operation and sagittal profile (T5-T12).Purpose
Methods
Radiographic parameters have been shown to have a poor correlation with clinical outcome after open scoliosis procedures. However this has not been previously addressed after endoscopic surgery. The purpose of our study was to examine prospectively the relationship between curve correction and clinical outcome for endoscopic scoliosis surgery. We studied 50 consecutive patients who underwent endoscopic instrumentation, with a minimum follow-up of two years. All patients were assessed pre-operatively and at 24 months post-operatively. Radiological parameters were measured from plain standing radiographs including the coronal Cobb angle, sagittal alignment, coronal alignment and shoulder elevation. Clinical outcome was assessed using the Scoliosis Research Society Outcomes Instrument (SRS-24). Correlation between radiological parameters and SRS-24 scores were determined using the Pearson correlation coefficient.Introduction
Methods
There was a positive correlation between instrumented Cobb angle and total SRS-24 score (p=0.03, r2=0.085) and between curve correction and total SRS-24 score (p=0.04, r2=0.081). No correlation was found between coronal alignment, sagittal alignment, shoulder elevation or size of rib hump and the SRS-24 scores (p>
0.05).
Autograft – Since before modern surgical techniques were described, ancient Greeks new of the possibilities for bone to grow after fracture. Studying open fractures, often post mortem, they new of the importance of both the “amount and integrity of bone architecture” that was necessary for two ends of a bone to heal. More recently, modern spinal surgical techniques, many pioneered by surgeons such as John Moe MD, use the same knowledge that for the intentional arthrodesis of two or more bony spinal levels there requires a certain amount and quality of bone – both capturing osteoinductive and osteoconductive properties. Autograft can be harvested in many ways for spinal arthrodesis and can be taken from iliac crest, tibia or fibula, and from local vertebral sources. Often requiring a separate skin and/or fascial incision, morbidities such as pain, neurovascular injury, infection, blood loss, haematoma, seroma, and fracture can plague the technique. Limited quantities, especially in children, can also be an issue with autograft. Cancellous or cortico-cancellous structural grafts can be milled and used for posterolateral fusion, interbody fusion, and can be mixed with other graft substitutes/expanders. Morbidity profile aside, autograft still remains the gold standard for spinal arthrodesis with regards “ideal properties” of bone grafts. Allograft – Currently, allograft is the most common substitute for autograft bone in spinal fusion. Allograft is primarily osteoconductive, with minimal osteoinductive potential. Avoidance of donor site morbidity, quantity issues, and surgical time saving are all features of allograft. Increased costs and potential for infection are negative issues. Preparation can vary and fresh unprocessed grafts are no longer used. Freeze drying (lyophilization) involves drying of the grafts before freezing at sub zero temperatures, and the technique reduces immunogenicity, though upon rehydration, structural strength is lost by around 50%. Low dose radiation (<
20kGy) can also be used to process the grafts, as can ethylene oxide, yet both techniques also reduce mechanical strength of the trabecular architecture. With adequate donor screening and tissue processing, the risk of developing HIV from an allograft is estimated to be less than 1 in a million. Incorporation of allograft is similar to that of autograft, though the process takes more time. Allograft cancellous particles provide a larger surface area and therefore incorporate faster. Studies suggest that mulched allograft femoral heads provides as good a fusion rate in posterior spinal surgeries for children with scoliosis as does the use of autograft. Combination of osteoinductive agents (BMP etc) with allograft is now possible and will likely enhance its further use. Structural fibular allografts in cervical interbody fusion and femoral ring allografts in lumbar interbody fusion have been well described and have very high rates of fusion.