Prognosis of spontaneous thoracic curve correction after the selective anterior fusion of thoracolumbar/lumbar (Lenke 5C) curves in idiopathic scoliosis

Background contextPrognosis of minor lumbar curve correction after selective thoracic fusion in idiopathic scoliosis is well defined. However, the prognosis of minor thoracic curve after isolated anterior fusion of the major lumbar curve has not been well described.PurposeTo define the prognosis of spontaneous thoracic curve correction after selective anterior fusion of the lumbar/thoracolumbar curve in idiopathic scoliosis.Study designA retrospective cohort study on the prognosis of the minor curve after selective anterior correction and fusion of the lumbar/thoracolumbar curve in idiopathic scoliosis.Patient sampleIdiopathic lumbar scoliosis patients treated with anterior spinal fusion.Outcome measuresThe Scoliosis Research Society 22 questionnaire was used as an outcome measure at the final follow-up.MethodsTwenty-eight patients were included in this study. Four patients were male, 24 patients were female, and average age at the time of surgery was 16 years. Mean follow-up was 48 months. According to the Lenke Classification, 22 patients were 5CN, 5 were 5C?, and 1 was 5C+. All operations were performed in the same institution. Standing long posterior-anterior and lateral radiographs were taken just before surgery, 1 week after surgery, and at final follow-up.ResultsThe mean preoperative Cobb angle of the lumbar (major) curve was 53° (standard deviation [SD]=8.6) and that of the thoracic (minor) curve was 38.4° (SD=6.24). The lumbar and thoracic curves were corrected to 10° (SD=7.6) and 25° (SD=8.3) postoperatively and measured 17° (SD=10.6) and 27° (SD=7.7), respectively, at the last follow-up. There was a significant difference between the preoperative and postoperative measurements of the minor curves (p<.05). However, there was no significant difference between the early postoperative and the final follow-up measurements (p>.05). Regarding the overall sagittal balance, there was no significant difference between preoperative, early, and late postoperative measurements (p>.05).ConclusionsSelective anterior fusion of the major thoracolumbar/lumbar curve was an effective method for the treatment of Lenke Type 5C curves. Minor thoracic curves did not progress after selective fusion of thoracolumbar/lumbar curves in minimum 2-year follow-up.     

青少年特发性脊柱侧凸的选择性胸椎融合治疗

目的　探讨青少年特发性脊柱侧凸选择性胸椎融合治疗的适应证。方法　回顾性分析12例行选择性胸椎融合患者术前、术后及随访时的X光像 ,对侧凸类型、侧凸Cobb角、顶椎旋转度、顶椎偏距、侧凸柔韧性、躯干偏移及胸腰段矢状面Cobb角进行测量和分析。患者 12例中男 2例 ,女10例 ,平均年龄 15 1(13～ 18)岁。侧凸均为KingⅡ型 ,其中PUMCⅡb1型 9例 ,Ⅱc3型 3例。所有病例均行选择性胸椎融合 ,平均随访 3 5 (1～ 10 5 )年。结果　手术前后胸弯冠状面Cobb角分别为5 4 0°、19 0° ,平均矫正率 6 2 7% ;腰弯冠状面Cobb角分别为 34 6°、12 5° ,自动矫正率为 6 4 7%。最后随访时 ,胸、腰弯的冠状面Cobb角分别为 18 8°、15 9°;腰弯冠状面Cobb角、顶椎偏距及顶椎旋转度与术后相比无显著变化。术后发生胸腰段后凸 1例 ,最终随访时未见进一步加重。无躯干失平衡现象发生。选择性胸椎融合较后路融合双弯平均减少 3 5个融合节段。结论　对腰弯柔韧性好且度数较小的KingⅡ (PUMCⅡb1和部分Ⅱc3)型特发性脊柱侧凸 ,可安全有效地行选择性胸椎融合     

Thoracic curve correction after posterior fusion and instrumentation of structural lumbar curves in patients with adolescent idiopathic scoliosis

Introduction

Spontaneous thoracic curve correction may occur following selective anterior spinal fusion in patients with adolescent idiopathic scoliosis (AIS). However, a few reports have described outcomes in patients following selective posterior fusion. The aim of this retrospective study was to assess curve correction in AIS patients with major lumbar curves and secondary thoracic curves after selective posterior fusion of the major curve.

Methods

The records of 42 AIS patients with major lumbar and minor thoracic curves who had received selective posterior lumbar fusion with segmental pedicle screw fixation were examined. Preoperative and follow-up radiographs were examined and the following were determined: curve flexibility, Cobb angle measurements of the major and minor curves, thoracolumbar/lumbar and thoracic Cobb measurements. Also, thoracolumbar/lumbar to thoracic Cobb ratios were determined. Minimum follow-up was 2?years. Patients were compared with respect to whether final thoracic curve improvement was (group A) or was not (group B) apparent. Improvement was indicated by a final thoracic curve that was less than the preoperative thoracic curve.

Results

Thoracic curve improvement was apparent in 32 of 42 patients after surgery. The mean preoperative thoracic curve in group A was 22.5° and 15.0° at follow-up, while corresponding values in group B were 35.0° and 39.8°. There were no cases in group A and eight cases in group B in which the preoperative thoracic curve was >30°. All patients in group B had preoperative thoracic curves on lateral bending >20°. Thoracic curvature at final follow-up was strongly correlated with preoperative thoracic curvature (r?=?0.911) and thoracic curvature on lateral bending (r?=?0.948).

Conclusions

Selective posterior fusion with segmental pedicle screw fixation in patients with major lumbar AIS resulted in curve correction in the majority of cases. Preoperative thoracic curvature and thoracic curvature on lateral bending were strongly correlated with the final thoracic curvature.     

Use of a vascularized fibula for spinal reconstruction in neurofibromatosis

We report a case of reconstruction of a dysplasic thoracic spine with vascularized fibula in Recklinghausen's disease. We present the case of a thirteen-year-old lady with neurofibromatosis type 1 who developed a dystrophic thoracic kyphoscoliosis. A T9 compression due to a severe scaloping of the thoracic spine caused an important deformation and a medullar compression (with dorsal pain, right sciatica and a pyramidal syndrome). The surgery consisted in medullar liberation by a T9-T10 corporectomy and an osteosynthesis with arthrodesis T3-L3. A free vascularized fibula bone graft, with an end-to-end anastomosis on a thoracic pedicle, was realized to fill the T8-T11 spinal defect. All the symptoms decreased after surgery and the patient could walk normally few months later. At one-year follow-up the radiographs showed a stable montage and a solid bony fusion. Analysing the literature, vascularized bone graft can be recommended to fill the bony spinal defect due to surgery in cases of tumor, infection, trauma or severe scoliosis. Compared to non-vascularized grafts, which are exposed to resorption, fatigue fracture and then instability, the vascularized fibula grafts provide a rapid fusion, a biomechanically stable and long-standing support with low risks of infection.     

Segmental pedicle screw instrumentation in idiopathic thoracolumbar and lumbar scoliosis

The role of posterior correction and fusion in thoracolumbar and lumbar scoliosis as well as pedicle screw instrumentation in scoliosis surgery are matters of debate. Our hypothesis was that in lumbar and thoracolumbar scoliosis, segmental pedicle screw instrumentation is safe and enables a good frontal and sagittal plane correction with a fusion length comparable to anterior instrumentation. In a prospective clinical trial, 12 consecutive patients with idiopathic thoracolumbar or lumbar scolioses of between 40° and 60° Cobb angle underwent segmental pedicle screw instrumentation. Minimum follow-up was 4 years (range 48– 60 months). Fusion length was defined according to the rules for Zielke instrumentation, normally ranging between the end vertebrae of the major curve. Radiometric analysis included coronal and sagittal plane correction. Additionally, the accuracy of pedicle screw placement was measured by use of postoperative computed tomographic scans. Major curve correction averaged 64.6%, with a loss of correction of 3°. The tilt angle was corrected by 67.0%, the compensatory thoracic curve corrected spontaneously according to the flexibility on the preoperative bending films, and led to a satisfactory frontal balance in all cases. Average fusion length was the same as that of the major curve. Pathological thoracolumbar kyphosis was completely corrected in all but one case. One patient required surgical revision with extension of the fusion to the midthoracic spine due to a painful junctional kyphosis. Eighty-five of 104 screws were graded “within the pedicle”, 10 screws had penetrated laterally, 5 screws bilaterally and 4 screws medially. No neurological complications were noted. In conclusion, despite the limited number of patients, this study shows that segmental pedicle screw instrumentation is a safe and effective procedure in the surgical correction of both frontal and sagittal plane deformity in thoracolumbar and lumbar scoliosis of less than 60°, with a short fusion length, comparable to anterior fusion techniques, and minimal loss of correction. Received: 23 September 1999 Revised: 20 January 2000 Accepted: 26 January 2000     

Scoliosis in patients with Friedreich's ataxia

We reviewed 31 consecutive patients with Friedreich's ataxia and scoliosis. There were 24?males and seven females with a mean age at presentation of 15.5 years (8.6 to 30.8) and a mean curve of 51° (13° to 140°). A total of 12 patients had thoracic curvatures, 11 had thoracolumbar and eight had double thoracic/lumbar. Two patients had long thoracolumbar collapsing scoliosis with pelvic obliquity and four had hyperkyphosis. Left-sided thoracic curves in nine patients (45%) and increased thoracic kyphosis differentiated these deformities from adolescent idiopathic scoliosis. There were 17 patients who underwent a posterior instrumented spinal fusion at mean age of 13.35 years, which achieved and maintained good correction of the deformity. Post-operative complications included one death due to cardiorespiratory failure, one revision to address nonunion and four patients with proximal junctional kyphosis who did not need extension of the fusion. There were no neurological complications and no wound infections. The rate of progression of the scoliosis in children kept under simple observation and those treated with bracing was less for lumbar curves during bracing and similar for thoracic curves. The scoliosis progressed in seven of nine children initially treated with a brace who later required surgery. Two patients presented after skeletal maturity with balanced curves not requiring correction. Three patients with severe deformities who would benefit from corrective surgery had significant cardiac co-morbidities.     

Anterior surgery for adolescent idiopathic scoliosis

Anterior open scoliosis surgery using the dual rod system is a safe and rather effective procedure for the correction of scoliosis (50–60 %). Thoracic hypokyphosis and rib hump correction with open anterior rather than posterior instrumentation appear to be the better approaches, although the latter is somewhat controversial with current posterior vertebral column derotation devices. In patients with Risser grade 0, hyperkyphosis and adding-on may occur with anterior thoracic spine instrumentation. Anterior thoracoscopic instrumentation provides a similar correction (65 %) with good cosmetic outcomes, but it is associated with a rather high risk of instrumentation (pull-out, pseudoarthrosis) and pulmonary complications. Approximately 80 % of patients with adolescent idiopathic scoliosis (AIS) curves of >70° have restrictive lung disease or smaller than normal lung volumes. AIS patients undergoing anterior thoracotomy or anteroposterior surgery will demonstrate a significant decrease in percentage of predicted lung volumes during follow-up. The thoracoabdominal approach and thoracoscopic approach without thoracoplasty do not produce similar changes in detrimental lung volume. In patients with severe AIS (>90°), posterior-only surgery with TPS provides similar radiographic correction of the deformity (44 %) with better pulmonary function outcomes than anteroposterior surgery. Vascular spinal cord malfunction after segmental vessel ligation during anterior scoliosis surgery has been reported. Based on the current literature, the main indication for open anterior scoliosis instrumentation is Lenke 5C thoracolumbar or lumbar AIS curve with anterior instrumentation typically between T11 and L3.     

Maintaining lumbar lordosis with anterior single solid-rod instrumentation in thoracolumbar and lumbar adolescent idiopathic scoliosis.

STUDY DESIGN: A prospective radiographic evaluation of 20 consecutive patients with primary lumbar or thoracolumbar adolescent idiopathic scoliosis who were treated with anterior convex compressive single solid-rod spinal instrumentation and structural titanium mesh (Harms) cages. OBJECTIVES: To evaluate a lordosis-preserving anterior single solid-rod instrumented fusion technique for these specific adolescent idiopathic curves. SUMMARY OF BACKGROUND DATA: Maintaining instrumented segmental lumbar lordosis after anterior fusion and instrumentation for thoracolumbar and lumbar curves has been difficult. Twenty consecutive patients who underwent anterior single solid-rod fusion, aged 18 or younger with a primary thoracolumbar or lumbar curve, were observed for preservation of lordosis for a minimum of 2 years. METHODS: All patients underwent an identical anterior surgical technique, involving discectomies and anulectomies of all convex discs, structural titanium mesh (Harms) cages placed in the anterior half of all disc spaces below T12, morselized rib autograft packed in all disc spaces to be fused and inside the cages, and anterior single solid-rod (5.0-mm or 5.5-mm diameter) convex compressive spinal instrumentation with appropriate lordotic rod contour and rod rotation as necessary. The anterior rod was placed just posterior to the cages to optimize lordotic contouring of the spine during compression. None of the patients was braced after surgery. The lowest instrumented vertebrae (LIV) were L2 (n = 3), L3 (n = 15), and L4 (n = 2), typically the lower end vertebra of the Cobb measurement. RESULTS: Measurements for the primary coronal Cobb before surgery, 1 week after surgery, and 2 years after surgery were 48 degrees, 11 degrees, and 12 degrees; for C7 plumb line deviation from the midline: 3.6 cm, 1.9 cm, and 1.2 cm; for lowest instrumented vertebra translation: 31 mm, 15 mm, and 15 mm; and for LIV tilt: 29 degrees, 6 degrees and 6 degrees, respectively. Sagittal measurements before surgery, 1 week after surgery, and 2 years after surgery were: T12-L2: -1 degree, -6 degrees, and -6 degrees; T12-LIV: -8 degrees, -13 degrees, -9 degrees; T12-S1: -61 degrees, -56 degrees, -60 degrees; and entire instrumented levels: -6 degrees, -9 degrees, and -6 degrees, respectively. Coronal plane correction improved: 75% in the primary Cobb, 66% in the plumb line, 50% in LIV translation, and 80% in LIV tilt. Sagittal plane alignment improved in T12-L2 lordosis (P < 0.01) with preservation of physiologic lordosis in the instrumented levels, T12-LIV, and T12-sacrum. There were no instrumentation failures, pseudarthroses, or reoperations. CONCLUSIONS: Coronal plane correction with preservation of thoracolumbar and lumbar lordosis 2 years after anterior convex compressive spinal instrumentation was accomplished using a lordotically contoured single solid rod with structural cages placed anteriorly in the disc spaces of patients with primary thoracolumbar or lumbar adolescent idiopathic scoliosis.     

Spinal deformities in patients with muscular dystrophy other than Duchenne. A review of 11 patients having surgical treatment

Eleven patients diagnosed as having muscular dystrophy and who underwent posterior spinal fusion were reviewed: Becker dystrophy in one, limb girdle in two, facioscapulohumeral in one, myopathia unspecified in one, myotonia dystrophica in two, myotonia congenita in one, and hypotonia congenita in three. There were eight females and three males. The curve pattern was thoracic in four, thoracolumbar in three, double thoracic and thoracolumbar in three, and thoracolumbar lordosis in one. Scoliosis was associated with kyphosis in two, with lumbar lordosis in one, and thoracic lordosis in four patients associated with poor vital capacity and shortness of breath. Seven patients had nonoperative treatment, five showing increase of the curve, and two having control of the curve. All patients had posterior spinal fusion with instrumentation with a follow-up of 9-89 months (average, 41 months). Postoperative support was used in all but one. Major complications occurred in four patients: a symptom of vascular obstruction of the duodenum in two, extubation delayed until the 7th day postoperatively in one and pseudarthrosis in one resulting in an increasing curve and refusion. One patient (limb girdle), 6 years after surgery at 21 years died from cardiomyopathy. The second (limb girdle) lost ambulation at age 22 years, 6.6 years after spinal surgery. In conclusion, patients with muscular dystrophies other than Duchenne generally have slowly evolving curves, and the use of an orthosis in the juvenile years controlled the curve until the pubertal growth spurt, when progression occurred. Surgical treatment was successful in stabilizing the deformities.     

Successful heart-lung transplantation in a patient with kyphoscoliosis.

The association is well established between congenital heart disease and spinal deformities such as scoliosis or kyphosis, but data are not available for risks and the outcome of heart surgery in patients with spinal deformities. We report a case of successful orthotopic heart lung transplantation in a patient with complex congenital heart disease and severe chest deformity who had undergone previous spinal fusion surgery for progressive right convex thoracic kyphoscoliosis.     

Spinal deformities in patients with Friedreich ataxia: a review of 19 patients

Nineteen patients with Friedreich ataxia and scoliosis were reviewed. The curve pattern was thoracic in six, thoracolumbar in six, double thoracic and lumbar in two, and double thoracic and thoracolumbar in five. Scoliosis was associated with hyperkyphosis in eight patients. Nonoperative treatment with braces was unsuccessful because of either increase of the curve despite the brace or difficulties with balance and coordination. Twelve patients underwent posterior spinal fusion with instrumentation. Average follow-up was 32 months. Postoperative immobilization was used in 10 patients and resulted in functional problems in only three. All fusions were solid at follow-up.     

Surgical treatment of scoliosis using allograft bone from a regional bone bank

Introduction

Routine spinal fusion techniques have involved removal of all soft tissues and articular facets, decortication of all posterior elements, and application of bone graft to the fusion area. Bone grafting has been performed mainly using the patient’s own bone (autograft bone), most commonly from the iliac crest. The use of autograft bone is accompanied by complications or problems because of harvesting and donor-site morbidity. Several studies have already reported the use of allograft bone in scoliosis surgery. However, these studies are small series with short-term follow-up.

Method

Twenty-two patients with scoliosis who underwent posterior spinal fusion and pedicle-screw-alone fixation using banked allograft bone obtained from the regional bone bank in Japan were analyzed. The average age at surgery was 13 years 5 months. The average follow-up was 2 years 7 months, and the average age at the last follow-up was 15 years 6 months. Scoliosis curves were divided into two groups (single curve group and double curve group).

Results

For the single curve group, the average preoperative coronal curve measured 78° (48°–85°) and the postoperative curve measured 22° (8°–35°), with no loss of correction at the last follow-up. For the double curve group, the average preoperative thoracic curve measured 64° (48°–85°) and the lumbar curve measured 42° (38°–60°). The average postoperative thoracic curve measured 12° (8°–34°) and lumbar curve measured 15° (8°–32°), with no significant loss of correction at the last follow-up. No patients had clinical complaints in the region of surgery at 9 months after surgery and thereafter. There were no complications including loss of correction, nonunion, infection and instrumentation failure. At the last follow-up, patients/parents were interviewed and asked to complete an outcome satisfaction questionnaire. They were asked to rate the outcome as very satisfactory, satisfactory, neither satisfactory nor unsatisfactory, unsatisfactory, or very unsatisfactory. Seventeen patients (77%) were very satisfied, four patients (17%) were satisfied, and one patient (6%) was neither satisfied nor unsatisfied. Autograft bone and banked allograft bone appear to yield comparable results and clinical outcomes.

Conclusion

However, in Japan, various expenses accrue to supply a safe and premium quality of banked allograft bone. Financial issue must be resolved as soon as possible.     

Radiographic evaluation of selective anterior thoracolumbar or lumbar fusion for adolescent idiopathic scoliosis

According to Lenke classification of adolescent idiopathic scoliosis (AIS), patients with type 5 curve in which the structural major curve is thoracolumbar or lumbar curve with nonstructural proximal thoracic and main thoracic curves, could be surgically treated with selective anterior thoracolumbar or lumbar (TL/L) fusion. This study retrospectively analyzed the radiographies of selective anterior TL/L fusion in 35 cases of AIS with Lenke type 5 curve. Segmental fixation with a single rigid rod through anterior thoracoabdominal approach was applied in all patients. Measurements of scoliosis curve in preoperative, immediate postoperative and follow-up radiographies were analyzed. The average follow up time was 36 months (24-42 months). The average preoperative Cobb angle of the TL/L curve was 45.6 degrees and improved into 9.7 degrees immediate postoperatively, with 79.7% curve correction. In addition, the minor thoracic curve decreased from 29.7 degrees preoperatively to 17.6 degrees postoperatively, with a spontaneous correction of 41.5%. During the follow-up, a loss of 4.6 degrees correction was found and the average Cobb angle of TL/L increased to 14.4 degrees . Also, the minor thoracic curve increased to average 20.1 degrees with a loss of 2.4 degrees correction. Trunk shift deteriorated slightly immediate postoperatively and improved at the follow-up. The lowest instrumented vertebra (LIV) tilt was improved significantly and maintained its results at the follow-up. During the follow-up, the coronal disc angle immediately above the upper instrumented vertebra (UIVDA) and below the LIV (LIVDA) aggravated, while the sagittal contours of T5-T12 and T10-L2 were well maintained. The lumbar lordosis of L1-S1 and the sagittal Cobb angle of the instrumented segments were reduced slightly postoperatively and at the follow-up. There were no major complications or pseudarthrosis. The outcomes of this study show that selective anterior thoracolumbar or lumbar fusion with solid rod instrumentation is effective for surgical correction of AIS with Lenke type 5 curve. The TL/L curve, minor thoracic curve, and LIV title can be improved significantly, with good maintenance of sagittal contour. However, the UIVDA and LIVDA aggravate postoperatively when the trunk rebalances itself during follow-up. The degeneration of LIV disc warrants longer-term follow-up.     

Scoliosis in Steinert syndrome: a case report.

BACKGROUND CONTEXT: Steinert syndrome is described as an autosomal dominant condition characterized by progressive muscular wasting, myotonia, musculoskeletal manifestations and rare spinal defects. Little is reported about spinal deformity associated with this syndrome. PURPOSE: We present a patient with Steinert syndrome complicated by scoliosis. In the literature on muscular dystrophy, other than Duchenne, little mention is given to the problem of scoliosis in general and its treatment in particular. STUDY DESIGN: A case report of a patient with Steinert syndrome associated with thoracic scoliosis and hypokyphosis is presented. METHODS: A 17-year-old boy presented with King type II right thoracic scoliosis (T5-T11, Cobb angle of 40 degrees) and hypokyphosis--10 degrees. He was treated with posterior stabilization and instrumentation at level T3-L2 with a postoperative correction of the scoliotic curve to 20 degrees. Histopathologic examination of the muscles confirmed the diagnosis of Steinert myotonic dystrophy. RESULTS: At 30-month follow-up, the patient was clinically pain free and well balanced. Plain radiographs showed solid spine fusion with no loss of deformity correction. CONCLUSIONS: Scoliosis in Steinert syndrome shares the characteristic of an arthrogrypotic neuromuscular curve and demands the extensive soft tissue release for optimal surgical correction. Intraoperative observations included profound tissue bleeding, abnormally tough soft tissues and a difficult recovery from anaesthesia.     

Reversing the concept: correction of adolescent idiopathic scoliosis using the convex rod de-rotation maneuver

Purpose

To show the radiological results of adolescent idiopathic scoliosis (AIS) patients treated with posterior fusion using all-pedicle-screw construct with correction carried out using a convex rod reduction technique.

Methods

Between October 2004 and June 2007, 42 AIS patients were treated with posterior fusion using all-pedicle-screw construct with correction done through the convex side. Two patients were lost to follow-up and were not included in the study. Forty patients had a minimum follow-up of 2 years. Patients were evaluated for the deformity correction in coronal and sagittal planes and for spinal balance.

Results

The mean preoperative Cobb angle of the major curve and secondary minor curves was 60° and 41°, respectively. Immediate postoperative mean Cobb angle of the major curve and secondary minor curves was 17° and 13°, respectively. Postoperative 2-year average major curve loss of correction was 7 %. Postoperative 2-year average minor curve loss of correction was 5 %. Preoperative thoracic kyphosis of 28° was changed to 22° in 2-years follow-up. The loss of thoracic kyphosis was most noted in hyperkyphotic patients.

Conclusions

The correction of AIS by convex-sided pedicular screws yields a coronal correction comparable to what is described in the literature for segmental concave-sided screws.     

A novel approach to gradual correction of severe spinal deformity in a pediatric patient using the magnetically-controlled growing rod

Background contextAcute correction of severe spinal deformities significantly increases the risk of neurologic complications. Previously used methods to safely correct these deformities include halo-traction devices and internal distraction rods.PurposeThis report introduces a novel method for gradual correction of severe spinal deformity by using the magnetically controlled growing rod (MCGR).Study designThis is a case report.MethodsA 12-year-old girl with severe kyphoscoliosis and concurrent syringomyelia and Arnold-Chiari Type I malformation underwent implantation of the MCGR. After implantation of the device, daily distractions of the implant were performed over the course of 2.5 months.ResultsThe patient underwent MCGR implantation without acute correction of her left-sided thoracic scoliosis (109° from T6 to T11) and upper thoracic kyphosis (72°). After 2.5 months of daily distractions in the ward, the scoliosis improved to 66° and the kyphosis to 62°. Final fusion was performed without problems, and her overall truncal balance was much improved.ConclusionsThis report is the first to note the safety and efficacy of the MCGR in treating young patients with severe spinal deformities. This technique allows correction of the deformity while the patient is awake so that neurology can be continuously monitored. The patient is also ambulatory throughout the distraction process and can be distracted on an outpatient basis. Repeated surgery can be avoided, and the MCGR has been shown to be safe and effective with this case illustration.     

Is anterior release necessary in severe scoliosis treated by posterior segmental pedicle screw fixation?

With the advent of segmental pedicle screw fixation that enables more powerful corrective forces, it is postulated that an additional anterior procedure may be unnecessary even in severe deformities. The purpose of this paper is to evaluate the results of a posterior procedure alone using segmental pedicle screw fixation in severe scoliotic curves over 70°. Thirty-five scoliosis patients treated by pedicle screw fixation and rod derotation were retrospectively analyzed after a minimum follow-up of 2 years (range 2–10.4). The mean age of patients was 15.3 years (range 9.8–34.2). Diagnoses were idiopathic scoliosis in 29, neuromuscular scoliosis in 3 and scoliosis associated with Marfan syndrome in 3. Scoliosis consisted of single thoracic curve in 18, double thoracic in 5 and double major in 12. Twenty-five patients showed a major thoracic curve greater than 70° (range 70–100), and different ten patients showed a major lumbar curve greater than 70° (range 70–105), pre-operatively. The deformity angle, lowest instrumented vertebral tilt (LIVT) and spinal balance were measured. Pre-operatively there were nine patients with coronal decompensation. The pre-operative thoracic curve of 80 ± 9° with the flexibility of 45 ± 11% (45 ± 11° in side-bending film) was corrected to 27 ± 10° at the most recent follow-up, showing a correction of 66% (53°) and loss of correction of 3.0% (3.7°). The pre-operative lumbar curve of 79 ± 12° with the flexibility of 62 ± 14% (30 ± 11° in side-bending film) was corrected to 33 ± 14° at the most recent follow-up [59% (46°) curve correction, 3.5% (3.0°) loss of curve correction]. The pre-operative LIVT of 30 ± 8° was corrected to 11 ± 6°, showing a correction of 62% (19°). Residual coronal decompensation was observed in three patients postoperatively. Pre-operative thoracic kyphosis of 27° (range 0–82) improved postoperatively to 31° (range 14–53). In conclusion, posterior segmental pedicle screw fixation without anterior release in severe scoliosis had satisfactory deformity correction without significant loss of curve correction. In this series a posterior procedure alone obviated the need for the anterior release and avoided complications related anterior surgery.     

Trunk rotation in scoliosis the influence of curve type and direction in 150 children

We compared the angle of trunk rotation (ATR) from scoliometer readings with Cobb angle measurements of the lateral deviation of the spine in 150 children referred to hospital for evaluation of scoliosis. the mean Cobb angle in thoracic curves was 16 °, in thoracolumbar curves 17° and in lumbar curves 20°. in thoracic curves and in right convex curves no patient with a Cobb angle of 25° or more had an ATR below 9°. in thoracolumbar and lumbar and in left convex curves, 7° ATR was occasionally associated with scoliosis of 25° or more. the correlation coefficient between the ATR and Cobb angle in right convex curves was 0.65 compared to 0.57 in left convex curves. We conclude that a criterion of 7° ATR for thoracic or right convex curves and one of 6° ATR for thoracolumbar and lumbar or left convex curves seem adequate for identification of patients with Cobb angles of 25° or more, which reduces the need for spinal radiography and follow-up outside the school screening programs.     

Surgical correction of spinal deformities after solid organ transplantation in childhood

A review of the current literature reveals no systematic analyses of the results of surgical correction of spinal deformity after pediatric organ transplantation. We therefore evaluated clinical and radiographic outcomes of spinal deformity correction after solid organ transplantation in childhood and adolescence. All 211 cases of heart, liver, and kidney transplantations performed in children in our country were reviewed. Six patients had undergone surgical correction of spinal deformity at a mean age 14.6 (range 12–17) years. Clinical data of the patients were evaluated. Radiographs of the whole spine were taken preoperatively, immediately after, at 2-year, and final follow-up visits. The Scoliosis Research Society (SRS) questionnaire was completed and a physical examination was performed at the final follow-up visit. The mean follow-up after spinal surgery was 4.9 years (range 2–7.6 years). Four patients developed scoliosis after organ transplantation without any evidence of scoliosis prior to organ transplantation. One patient with congenital scoliosis was operated on after kidney transplantation. One boy had osteoporosis and severe local kyphosis due to vertebral compression fractures. Four patients underwent anterior and posterior surgery, two posterior only. The mean preoperative Cobb angle of the thoracic curve was 54° (range 42–69°) in the patients with scoliosis. The postoperative values were 30° (26–38°) immediately after instrumentation and 39° (34–42°) at the final follow-up visit. The patient with vertebral compression fractures and progressive kyphosis had 70° curve before surgery, 23° immediately after the operation, and 60° at the final check up. The mean total score on the SRS questionnaire was 95.5 (range 90–101). There is a relatively high incidence (2.8%) of spinal deformities needing operative treatment after solid organ transplantation. Possible etiologies for spinal deformities are growth disturbance and muscle weakness due to the basic disease. The other important factors are related to immunosupressive medication, especially glucocorticoids needed after transplantation. Primary correction of these deformities was satisfactory, but during follow-up, a certain amount of recurrence of the curves was evident. Poor bone quality may explain some of the loss of correction.     

Treatment of severe thoracolumbar kyphoscoliosis on the ground of ganglioneuroblastoma of the diaphragm: a case report

The treatment of an unusual case with severe kyphoscoliotic deformity of the thoracolumbar spine, in association with a ganglioneuroblastoma invading the adjacent diaphragm, is presented in this report. Severe scoliotic deformity of the spine, associated with ganglioneuroblastoma of the diaphragm is a rare combination and treatment can be very challenging, as both entities require extensive surgery. To the best of our knowledge, only two reports related to a similar condition have been published in the literature so far. A 9-year-old girl had been treated in another institution since the age of 5 years for thoracolumbar kyphoscoliosis with bracing. She was referred to our department with a stiff right kyphoscoliotic curve at the thoracolumbar region (T8-L2), with measurements of 105 and 90° for the scoliotic and kyphotic elements, respectively. There were no neurological signs detected at the preoperative work-up, which included clinical and radiological evaluation (plain X-rays and computed tomographic scan). The patient was treated with a two-stage spinal fusion. During the anterior approach through a right thoracotomy, a tumor was discovered infiltrating half of the diaphragm and extended to the frontal surface of the lower thoracic vertebral bodies. The vertebrae were cleared of the tumorous masses and anterior discectomies (T8-L2) were successfully carried out according to the preoperative plan. The histopathology report indicated ganglioneuroblastoma in both the prevertebral material and the speciments excised from the diaphragm. A week later a T3-L4 posterior fusion was carried out and the deformity was corrected and fixed with an SFS instrumentation system. Both the scoliotic and the kyphotic curves were reduced to 46°. Postoperatively the patient was referred to the oncology department of another hospital for the treatment of the diaphragm tumor. During the last follow-up (4 years), the scoliotic curve remains steady and the tumor shows no recurrence. Although there are cases of ganglioneuroblastoma associated with scoliotic deformity, the combination of this tumor infiltrating the diaphragm and a very severe deformity of the spine is extremely rare. Nevertheless, the treatment undertaken has proven to be successful so far.