Long-term three-dimensional changes of the spine after posterior spinal instrumentation and fusion in adolescent idiopathic scoliosis

This is a prospective study comparing the short- and long-term three-dimensional (3D) changes in shape, length and balance of the spine after spinal instrumentation and fusion in a group of adolescents with idiopathic scoliosis. The objective of the study was to evaluate the stability over time of the postoperative changes of the spine after instrumentation with multi rod, hook and screw instrumentation systems. Thirty adolescents (average age: 14.5 ± 1.6 years) undergoing surgery by a posterior approach had computerized 3D reconstructions of the spine done at an average of 3 days preoperatively (stage I), and 2 months (stage II) and 2,5 years (stage III) after surgery, using a digital multi-planar radiographic technique. Stages I, II and III were compared using various geometrical parameters of spinal length, curve severity, and orientation. Significant improvement of curve magnitude between stages I and II was documented in the frontal plane for thoracic and lumbar curves, as well as in the orientation of the plane of maximum deformity, which was significantly shifted towards the sagittal plane in thoracic curves. However, there was a significant loss of this correction between stages II and III. Slight changes were noted in apical vertebral rotation, in thoracic kyphosis and in lumbar lordosis. Spinal length and height were significantly increased at stage II, but at long-term follow-up spinal length continued to increase while spinal height remained similar. These results indicate that although a significant 3D correction can be obtained after posterior instrumentation and fusion, a significant loss of correction and an increase in spinal length occur in the years following surgery, suggesting that a crankshaft phenomenon may be an important factor altering the long-term 3D correction after posterior instrumentation of the spine for idiopathic scoliosis. Received: 3 March 1998 Revised: 22 August 1998 Accepted: 15 September 1998     

The timing of spinal fusion in adolescent idiopathic scoliosis

102 cases of idiopathic adolescent scoliosis seen over a period of 5 years were studied. 59 patients who were treated surgically and followed up for a minimum of 48 months, fell into one of two groups: Group I - those operated on within 3 years following the adolescent growth spurt, and Group II - those who were operated on at or after skeletal maturity. 35 patients were treated by Harrington instrumentation and posterior fusion and 24 by Harrington instrumentation, segmental sublaminar wiring and posterior fusion. In 7 patients anterior release was performed initially. In Group I, the extent of deformity correction and elimination of the rib hump were better, and complications such as neurological deficit, hook dislodgement and implant breakage were encountered less frequently. Harrington instrumentation, segmental sublaminar wiring and posterior fusion gave better results than instrumentation and fusion. Our results suggest that surgical correction should be done within 3 years following growth spurt, i.e. 14 to 16 years of age.     

Double-segment total vertebrectomy for the surgical treatment of congenital kyphoscoliosis: a case report

BACKGROUND CONTEXT: Congenital kyphosis or kyphoscoliosis is an uncommon deformity that usually is progressive without surgical intervention. In the lately diagnosed or neglected cases of congenital kyphoscoliosis, the patients may come with shoulder-trunk imbalance anomalies, severe deformity in coronal and sagittal plane, rib cage deformities, pelvic tilt, presence of intramedullary anomalies, neurological deficit, and difficulty in walking and cardiopulmonary problems. PURPOSE: To present a technical note related with double-segment total vertebrectomy for the surgical treatment of a patient who had neglected congenital kyphoscoliosis in lumbar spine. STUDY DESIGN: Case report. METHODS: A 19-year-old girl had submitted to our center with complaints of deformity and pain in her back. Her physical examination revealed scoliosis and gibbosity in lumbar region. Her neurological examination was normal. In the radiological examination, X-ray films showed 42 degrees lumbar scoliosis in frontal plane and 35 degrees kyphotic curvature in the sagittal plane. RESULTS: Three-staged (posterior-anterior-posterior) surgery in the same session (same anesthesia) was performed. CONCLUSION: Total or partial vertebrectomy on the apex of the deformity and the adjacent vertebral bodies along with anterior stabilization by means of a cylindrical cage combined in one operative procedure preceded by temporary posterior instrumentation and followed by posterior instrumentation and fusion may be preferred for the treatment of congenital kyphoscoliosis in neglected cases to provide spinal cord decompression.     

Comparative analysis of pedicle screw and hook instrumentation in posterior correction and fusion of idiopathic thoracic scoliosis

Posterior correction and fusion with segmental hook instrumentation represent the gold standard in the surgical treatment of progressive idiopathic thoracic scoliosis. However, there is a debate over whether pedicle screws are safe in scoliosis surgery and whether their usage might enable a better curve correction and a shorter fusion length. The details of curve correction, fusion length and complication rate of 99 patients with idiopathic thoracic scoliosis treated with either hook or pedicle screw instrumentation were analyzed. Forty-nine patients had been operated with the Cotrel-Dubousset system using hooks exclusively ("hook group"). Fifty patients had been operated with either a combination of pedicle screws in the lumbar and lower thoracic and hooks in the upper thoracic spine or exclusive pedicle screw instrumentation using the Münster Posterior Double Rod System ("screw group"). The preoperative Cobb angle averaged 61.3 degrees (range 40 degrees-84 degrees ) in the hook group and 62.5 degrees (range 43 degrees-94 degrees ) in the screw group. Average primary curve correction was 51.7% in the hook group and 55.8% in the screw group ( P>0.05). However, at follow-up (2-12 years later) primary curve correction was significantly greater ( P=0.001) in the screw group (at 50.1%) compared to the hook group (at 41.1%). Secondary lumbar curve correction was significantly greater ( P=0.04) in the screw group (54.9%) compared to the hook group (46.9%). Correction of the apical vertebral rotation according to Perdriolle was minimal in both groups. Apical vertebral translation was corrected by 42.0% in the hook group and 55.6% in the screw group ( P=0.008). Correction of the tilt of the lowest instrumented vertebra averaged 48.1% in the hook group and 66.2% in the screw group ( P=0.0004). There were no differences concerning correction of the sagittal plane deformity between the two groups. Fusion length was, on average, 0.6 segments shorter in the screw group compared to the hook group ( P=0.03). With pedicle screws, the lowest instrumented vertebra was usually one below the lower end vertebra, whereas in the hook group it was between one and two vertebrae below the lower end vertebra. Both operative time and intraoperative blood loss were significantly higher in the hook group ( P<0.0001). One pedicle screw at T5 was exchanged due to the direct proximity to the aorta. There were no neurologic complications related to pedicle screw instrumentation. Pedicle screw instrumentation alone or in combination with proximal hook instrumentation offers a significantly better primary and secondary curve correction in idiopathic thoracic scoliosis and enables a significantly shorter fusion length.     

Pre-, intra-, and postoperative three-dimensional evaluation of adolescent idiopathic scoliosis

The authors measured and compared the pre-, intra-, and postoperative three-dimensional shape of the spine during corrective surgery to quantify the specific contribution of positioning, anesthesia, surgical exposure, surgical instrumentation, and postural adaptation of the thoracic and lumbar spine. In 58 adolescent girls with idiopathic scoliosis undergoing corrective surgery by a posterior approach, the three-dimensional geometry of the thoracic and lumbar spine was documented in the standing position before and after surgery using a three-dimensional reconstruction technique based on multiplanar radiography, and the intraoperative three-dimensional geometry was measured using a three-dimensional magnetic digitizer before and after installation of the first rod. Prone positioning, anesthesia, and surgical exposure are responsible for a considerable decrease in all curves in the frontal and sagittal plane. Instrumentation with the first rod produces additional substantial and favorable three-dimensional changes with partial restoration of the normal sagittal curves and sagittal shift of the plane of maximum deformity. Although no loss of correction was observed in the frontal plane when patients resumed their standing position, a "spring-back" effect on the spine was noted in the sagittal plane and a loss of three-dimensional correction was seen in the orientation of the plane of maximum deformity. Surgeons can use the knowledge of these various changes to achieve better results by more careful attention to the preoperative positioning of patients and to curve correction in the sagittal plane when instrumentation is applied to the spine.     

The rib deformity in adolescent idiopathic scoliosis. A prospective study to evaluate changes after Harrington distraction and posterior fusion

A prospective study to investigate changes in the rib hump or rib deformity after correction of the lateral curvature in adolescent idiopathic scoliosis is reported. The operative treatment for 47 patients was by a Harrington distraction rod and posterior fusion. Before operation and at follow-up, measurements of the Cobb angle, of vertebral rotation, and of the rib deformity were taken. Despite operative correction of the lateral curve, there was a progression of the rib deformity in 64% of the cases after four years. Correction of the lateral curve may thus have no effect on vertebral rotation and cannot be guaranteed to effect a permanent reduction of the rib hump.     

Structural vertebral changes in the horizontal plane in idiopathic scoliosis and the long-term corrective effect of spine instrumentation

Summary The rotation and structural changes of the apex vertebra in the horizontal plane as well as of the thoracic cage deformity were quantified by measurements on computed tomography (CT) scans from patients with right convex thoracic idiopathic scoliosis (IS). The CT scans were obtained from 12 patients with moderate scoliosis (mean Cobb angle 25.8°, r 13°–30°) and from 33 with severe scoliosis (mean Cobb angle 46.2°, r 35°–71°). In addition, CT scans of thoracic vertebrae from 15 patients without scoliosis were used as reference material. Ten of the scoliotic cases had had Cotrel-Dubousset instrumentation (CDI) and posterior fusion and had entered a longitudinal study on the effect of operative correction on the re-modelling of the apical vertebra. An increasingly asymmetrical vertebral body, transverse process angle, pedicle width and canal width were found in the groups with scoliosis as compared with the reference material. Vertebral rotation and rib hump index were significantly larger in patients with early and advanced scoliosis than in normal subjects. The modelling angle of the vertebral body, the transverse process angle index and the vertebral rotation in relation to the middle axis of the thoracic cage were significantly greater in patients with severe than with moderate scoliosis. The results of this longitudinal study suggest that the structural changes of the apical vertebra regress 2 years or more after CD instrumentation.     

The suprapedicle claw construct in anterior scoliosis surgery

Proximal screw pullout is a well-recognized problem in anterior scoliosis surgery, with a rate of pseudarthrosis or screw pullout ranging from 15 to 30%. To prevent screw pullout at the top of the construct, the authors have devised the concept of a claw for the top instrumented vertebra. The claw consists of a classic anterior vertebral body screw inserted parallel to the inferior end-plate and in the posterior portion of the vertebral body 8 mm in front of the spine canal. After rib desarticulation, a laminar hook of a small size is inserted over the superior aspect of the pedicle of the same vertebra. The rod is then inserted into the two side openings of the screw and the hook. Compression across the hook and the screw is then performed, making a claw construct. This concept can also be extended in the case of early revision for a proximal screw pullout, where it is possible to revise the instrumentation with an offset connector linking the rod to the superior portion of the pedicle where the suprapedicule hook has been inserted. We report two cases where a suprapedicle claw was successfully used in anterior scoliosis correction of a right thoracic curve. Such a concept may represent the solution to proximal screw pullout in anterior scoliosis correction.     

Role of conservative treatment of cervical spine injuries

This is a clinical radiographic study, spanning over three decades, analyzing the three-dimensional (3-D) changes in spine geometry after corrective surgery for adolescent idiopathic scoliosis (AIS) using four generations of instrumentation systems. The objective of this study was to retrospectively evaluate the evolution of spinal instrumentation over time by measuring the 3-D changes of spinal shape before and after surgical correction of subjects with AIS using Harrington/Harrington-Luque (H/HL) instrumentation, original and recent generations of Cotrel-Dubousset Instrumentation (CDI) with rod rotation maneuvers, as well as third generation systems using thoracic pedicle screws and direct vertebral derotation (DVD) manoeuver in order to determine if the claims for improved 3-D correction from generation to next generation could be substantiated. The 3-D shape of the thoracic and lumbar spine was recorded from a pair of standing radiographs using a novel 3-D reconstruction technique from uncalibrated radiographs in 128 adolescents with AIS undergoing surgery by a posterior approach. Changes in coronal Cobb angles, kyphosis, lordosis, as well as in a series of 3-D parameters computed from the spine reconstructions before and after surgery were used to compare the four groups. Results demonstrate statistically significant differences (P = 0.05) between generations with regards to the correction of the coronal Cobb angle, and different loss of physiological lordosis. More importantly, significant differences in the 3-D correction of the spine based on the orientation of the planes of maximal curvature were observed (20/−6% H/HL vs. 39/39% CDI vs. 42/18% DVD for the thoracic/lumbar regions, respectively), confirming that recent CDI and third generation instrumentations coupled with DVD can bring the deformity significantly closer to the sagittal plane. An increased correction in apical vertebra axial rotation was observed with the DVD manoeuver (74%), while fewer notable differences were found between DVD and recent CDI systems in terms of 3-D correction. This is the first quantitative study to clearly demonstrate that the rod derotation and DVD maneuvers can significantly improve 3-D correction of scoliotic deformities, thereby supporting the transition towards these more elaborate and costly instrumentation technologies in terms of 3-D assessment.     

Sagittal balance of thoracic lordoscoliosis: anterior dual rod instrumentation versus posterior pedicle screw fixation

Posterior pedicle screw fixation is now the standard treatment for surgical correction of idiopathic scoliosis and has largely replaced anterior techniques, but there have been reports describing a lordogenic effect of segmental pedicle screw instrumentation in the thoracic spine. This clinical study compared anterior dual rod instrumentation with posterior pedicle screw fixation for idiopathic thoracic lordoscoliosis, including 42 patients (7 male, 35 female; average age 16 years, range 12–34) who underwent posterior pedicle screw fixation (n = 20) or anterior dual rod instrumentation (n = 22) at two centers. The average follow-up period was 33 months (24–108 months). Inclusion criteria were a diagnosis of adolescent idiopathic scoliosis with a structural thoracic curve (Lenke 1–3) and thoracic hypokyphosis (T4–T12 < 20°). The main thoracic curve magnitude and sagittal profile on standing radiographs were evaluated. Thoracic kyphosis was significantly restored from preoperatively 10.2° to 23.4° postoperatively in the anterior group and from 7.6° to 12.9° in the posterior group (P < 0.005). Kyphosis improved significantly better in the anterior group than in the posterior group (P < 0.005). The preoperative and postoperative main thoracic curve values were 63° (48–80°) and 25.2° in the anterior group and 60.6° (50–88°) and 23.6° in the posterior group, with no significant differences between the groups. No neurological or other severe complications were observed. Anterior dual rod instrumentation in patients with thoracic lordoscoliosis allows significantly better restoration of thoracic kyphosis than posterior pedicle screw instrumentation.     

3-D study of the immediate effect of the Boston brace on the scoliotic lumbar spine]

In order to study the immediate 3-D effect of the Boston brace on lumbar scoliosis, 31 adolescents with idiopathic scoliosis King type I or II had a 3-D computerised reconstruction of their deformity with and without the brace. Results demonstrate that the brace produces a distraction of the lumbar spine similar to that produced by the Harrington instrumentation by correcting the frontal deformity at the expense of a significant reduction of the physiological lumbar lordosis. No significant effect on rotation of the apical vertebra or "detorsion" of the spine could be measured. We feel that a orthosis that provides a real 3-D correction of the deformity has yet to be developed.     

Anterior dual rod instrumentation in idiopathic thoracic scoliosis

For anterior correction and instrumentation of thoracic curves single rod techniques are widely used. Disadvantages of this technique include screw pullouts, rod fractures and limited control of kyphosis. This is a prospective study of 23 consecutive patients with idiopathic thoracic scoliosis treated with a new anterior dual rod system. Aim of the study was to evaluate the safety and efficacy of this new technique in the surgical treatment of idiopathic thoracic scoliosis. To the best knowledge of the authors, this is the largest series on dual rod dual screw instrumentation over the entire fusion length in thoracic scoliosis. Twenty-three patients with an average age of 15 years were surgically treated with a new anterior dual rod system through a standard open double thoracotomy approach. Average clinical and radiological follow-up was 28 months (24–46 months). Fusion was carried out mostly from end-to-end vertebra. The primary curve was corrected from 66.6° to 28.3° (57.5% correction) with an average loss of correction of 2.0° at Cobb levels and of 1.3° at fusion levels. Spontaneous correction of the secondary lumbar curve averaged 43.2% (preoperative Cobb angle 41.2°). The apical vertebral rotation was corrected by 41.1% with a consecutive correction of the rib hump of clinically 66.7%. The thoracic kyphosis measured 29.2° preoperatively and 33.6° at follow-up. In seven patients with a preoperative hyperkyphosis of on average 47.3° thoracic kyphosis was corrected to 41.0°. This new instrumentation enables an entire dual rod instrumentation over the whole thoracic fusion length. It offers primary stability without the need of postoperative bracing. Dual screw dual rod instrumentation offers the advantages of a high screw pullout resistance, an increased overall stability and satisfactory sagittal plane control.     

Screws versus hooks: implant cost and deformity correction in adolescent idiopathic scoliosis

Objective  

To compare the costs of two spinal implants—hook and hybrid constructs and pedicle screw constructs—in posterior spinal fusion for adolescent idiopathic scoliosis (AIS) as they relate to intraoperative deformity correction.     

Biomechanics of scoliosis]

Scoliosis is defined as a three-dimensional deformity of the spine. The most pronounced component of scoliosis is in the frontal plane, comprising the lateral bending of the spine. Rotation of vertebra takes place in the transverse plane. In most cases of idiopathic scoliosis a decrease of thoracic kyphosis in the sagittal plane occurs. A more rare event is the appearance of a junctional kyphosis between the primary and secondary curve. The instrumentation introduced by Harrington dealt mainly with balancing the bending forces in the frontal plane (distraction of the concavity of the curve), along with fusion of the instrumented area. The multisegmental CD instrumentation allowed for the diminution of the lateral curve in the frontal plane, while at the same time "forcing" an increase of thoracic kyphosis in single curves, and restoration of physiological sagittal curves (thoracic kyphosis lumbar lordosis) in double curve scoliosis. The CD method achieved this good by a 90 degrees rotation of the rod towards the concavity of the curve, "changing" the lateral curve into kyphotic curve. In the AO USS (Universal Spine System) correction is achieved by pulling the hooks towards the rod. The procedure ends with the linking of two rods with transverse connectors forming this way a stable framework. The degree of correction achieved with this method is based on the biomechanic inter relation between the spine and the instrumentation system (application of distraction forces, compensatory forces and translocation of the instrumented segment). Post-op decompensation of the spine is usually the result of incorrect hook fixation, inadequate application of forces (distraction and compression) and use of a standard hook pattern for thoracic curves (type III) in other types of scoliosis.     

Lenke 5型脊柱侧凸前路单棒矫形术中放置钛网对术后矢状面重建的影响

目的 探讨放置钛网对Lenke 5型青少年特发性脊柱侧凸(adolescent idiopathic scoliosis, AIS)行选择性前路单棒矫形加植骨融合术后矢状面重建的影响.方法 40例Lenke 5型AIS患者,根据术中植骨方式分为两组,均接受选择性前路单棒矫形术.术中椎间融合植骨时,A组患者放置钛网,B组则单纯以剪碎的自体肋骨和髂骨骨粒植骨.A组女19例,男1例;年龄12～18岁.B组女17例,男3例;年龄13～20岁.两组患者获得1.5年以上的随访.对术前、术后和末次随访时的冠状面矫形与矢状面重建指标进行分析.结果 在术后和随访中,两组患者主弯的矫正率大于70%,继发弯也获得较满意的自发性纠正.无内固定相关和假关节形成等并发症发生.两组患者术后和随访中也获得较满意的矢状面重建.其中,术后和随访中胸椎后凸增加,胸腰交界性后凸轻微变化,腰椎前凸无明显丢失,内固定近端后凸成角轻度增大,内固定区成角前凸轻度减小,这些指标在两组间差别无统计学意义.末次随访时,A组患者SVA和L1到C7PL线的距离平明显小于其术前和术后的测量值,而这些指标在B组均无显著变化.结论 选择性前路单棒矫形加椎间植骨融合术是治疗Lenke 5型脊柱侧凸的有效方法.与自体植骨相比,钛网植骨可较好地改善矢状面的整体平衡.     

Short posterior fusion for patients with thoracolumbar idiopathic scoliosis.

Fifteen percent of all scolioses are idiopathic thoracolumbar and are characterized by significant imbalance in the frontal plane. A large curve of more than 40 degrees creates a trunk shift and under these circumstances an active correction is necessary. It is this imbalance that is the cause of increasing muscular fatigue. Arthritic changes may appear later which also are responsible for pain. The aim of a surgical procedure is to stop the progression of scoliosis, to obtain the reequilibrium of the spine in a frontal and a sagittal plane, and to correct the deformity. During the 1960s Dwyer6 developed his anterior instrumentation mainly for thoracolumbar and lumbar curves. In 1980 Hall developed the concept of a short anterior fusion with overcorrection for patients with thoracolumbar curves. In the present study 10 patients are presented who were operated on for thoracolumbar adolescent idiopathic scoliosis using short posterior fusion instrumented by segmental convex transpedicle screw fixation and concave hook stabilization. With a mean followup of 49 months, the results show that frontal and sagittal balances are restored. In the present study all patients achieved frontal and sagittal balances at the last followup. The angular correction achieved by surgery always is more effective than what is visualized in radiographs of the patient in the bending position obtained before surgery. The correction of the major curve in the frontal plane improved from a mean angle of 47 degrees preoperatively to 14 degrees postoperatively and to 17 degrees at the last followup. In all cases, mobile discs in the lower lumbar area are open. The posterior short fusion has the same power of correction as the anterior fusion with the advantage of an easier surgical approach and a better control of the lordosis. This paper will describe the operative indications, the choices of instrumented levels, and the medium term followup results.     

Cervical spine sagittal alignment variations following posterior spinal fusion and instrumentation for adolescent idiopathic scoliosis

The aim of this study is to quantify the changes in the sagittal alignment of the cervical spine in patients with adolescent idiopathic scoliosis following posterior spinal fusion. Patients eligible for study inclusion included those with a diagnosis of mainly thoracic adolescent idiopathic scoliosis treated by means of posterior multisegmented hook and screw instrumentation. Pre and post-operative anterior–posterior and lateral radiographs of the entire spine were reviewed to assess the changes of cervical sagittal alignment. Thirty-two patients (3 boys, 29 girls) met the inclusion criteria for the study. The average pre-operative cervical sagittal alignment (CSA) was 4.0° ± 12.3° (range −30° to 40°) of lordosis. Postoperatively, the average CSA was 1.7° ± 11.4° (range −24° to 30°). After surgery, it was less than 20° in 27 patients (84.4%) and between 20° and 40° in 5 patients (15.6%). The results of the present study suggest that even if rod precontouring is performed and postoperative thoracic sagittal alignment is restored, improved or remains unchanged after significant correction of the deformity on the frontal plane, the inherent rigidity of the cervical spine limits changes in the CSA as the cervical spine becomes rigid over time.     

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.     

Spinal fusions to the pelvis augmented by Cotrel-Dubousset instrumentation for neuromuscular scoliosis.

Eighteen patients with spinal deformity secondary to a neuromuscular disorder were treated with posterior fusion using Cotrel-Dubousset instrumentation (CDI) to the pelvis. The mean frontal plane curve was 70 degrees preoperatively and 38 degrees postoperatively. The mean loss of correction was 3 degrees at an average follow-up of 28 months. Pelvic obliquity improved in nine patients from a preoperative mean of 22 degrees to 11 degrees at follow-up. Lumbar lordosis was maintained with preoperative and postoperative means of -36 degrees. Complications included perioperative hardware failure in one case and one late, deep infection. There were no neurologic complications, pseudarthroses, or rod breakage. Posterior spinal fusion with CDI to the pelvis is an effective treatment for patients with neuromuscular scoliosis.