【Abstract】 Objective To observe the effects of scoliosis on pulmonary function. Methods 31 cases of scoliosis were included and underwent pulmonary function test ( PFT) . The cases were divided into an adolescent group ( 16 cases) and an adult group ( 15 cases) according to age. Predicted value was used as a reference to assess various PFT parameters. Results In both groups, forced expiratory volume in one second, forced vital capacity, and pulmonary diffusion decreased. In the adolescent group, residual volume,functional residual volume, and total lung capacity decreased. In the adult group, vital capacity and maximal voluntary ventilation decreased, the ratio of forced expiratory volume in one second to forced vital capacity decreased, and resonance frequencies increased significantly compared with the adolescent group ( P lt; 0. 05) . Conclusion Scoliosis may lead to restrictive ventilation defect, which is mainly lung volume reduction in adolescent patients and more severe in adult patients.
【Abstract】 Objective To explore the clinical application and outcomes of preoperative second measurement of three-dimensional (3-D) CT reconstruction data for scoliosis orthopedic surgery. Methods Between August 2006 and March 2008, 11 patients with severe rigid scoliosis received surgery treatment, including 4 males and 7 females with an average age of 17.2 years (range, 15-19 years). Preoperative second measurement of 3-D CT reconstruction data was conducted to guide the surgery, including the angle and width of pedicle, the entry point, and the choice of screws whose lengths and diameters were suitable. A total of 197 pedicle screws were implanted. The operation time, blood loss, postoperative nerve function,and Cobb’s angles at sagittal and coronal view were all recorded, and the postoperative CT scan was performed to assess the accuracy of pedicle screw insertion according to Andrew classification. Results Pedicle screws were implanted within 1-11 minutes (mean, 5.8 minutes), and the blood loss was 450-2 300 mL (mean, 1 520 mL). The postoperative X-ray films showed the correction rates of Cobb’s angle were 68.5% in coronal view and 55.5% in sagittal view. The accuracy of pedicle screw insertion was rated as grade I in 77 screws (39.1%),grade II in 116 screws (58.9%), and grade III in 4 screws (2.0%) according to postoperative CT scan. All 11 cases were followed up 14 months to 2 years without any complications. Conclusion Preoperative second measurement of 3-D CT reconstruction data can make the surgery process easy and accurate in treatment of severe scoliosis.
Objective To introduce operation skill of the spinal wedge osteotomy by posterior approach for correction of severe rigid scol iosis and to discuss the selection of the indications and the range of fusion and fixation. Methods Between July 1999 and January 2009, 23 patients with severe rigid scol iosis were treated with spinal wedge osteotomy by posterior approach, including 16 congenital scol iosis, 5 idiopathic scol iosis, and 2 neurofibromatosis scol iosis. There were 11 males and 12 females with a median age of 15 years (range, 8-29 years). Two patients had previous surgery history. The Cobb’s angles of scol iosis and kyphosis before operation were (85.39 ± 13.51)° and (56.78 ± 17.69)°, respectively. The mean spinal flexibil ity was 14.4% (range, 4.7%-22.5%). The trunk shift was (15.61 ± 4.89) mm. The preoperative CT or MRI showed bony septum in the canal in 2 patients. Results The mean operative time was 241 minutes and the mean blood loss was 1 452 mL. The average fused vertebrae were 10.7 segaments (range, 8-14 segaments). The follow-up ranged from 1 to 4 years with an average of 2 years and 6 months. The postoperative Cobb’s angle of scol iosis was (38.70 ± 6.51)°, the average correction rate was 54.7%. The postoperative Cobb’s angle of kyphosis was (27.78 ± 6.01)°, the average correction rate was 51.0%. The trunk shift was improved to (4.69 ± 1.87) mm, the increased height was 5.2 cm on average (range, 2.8-7.7 cm). The Cobb’s angle of scol iosis was (41.57 ± 6.80)° with an average 2.9° loss of correction at the final follow-up; the Cobb’s angle of kyphosis was (30.39 ± 5.94)° with an average 2.6° loss of correction at the final follow-up; the trunk shift was (4.78 ± 2.00) mm at the final follow-up. There were significant differences (P lt; 0.05) in the Cobb’s angles of scol iosis and kyphosis and the trunk shift between preoperation and postoperation, between preoperation and last follow-up. Four cases had pedicle fracture, 1 had L1 nerve root injury, 2 had superior mesenteric artery syndrome, 1 had exudates of incision, and 2 had temporary dysfunction of both lower extremity. Conclusion Spinal wedge osteotomy by posterior approach is a rel iable and safe surgical technique for correcting severe rigid scol iosis. With segmental pedical screw fixation, both the spinal balance and stabil ity can be restored.
Objective To investigate the effect of removing the implanted plate-rod system for scol iosis (PRSS) on maintaining scol iosis curve correction and preserving spinal mobil ity in patients with scol iosis. Methods From June 1998 to February 2002, 119 cases of scol iosis were treated with the implant of PRSS, which was removed 26-68 months later (average46.8 months). Complete follow-up data were obtained in 21 patients, including 6 males and 15 females aged 11-17 years old (average 13.8 years old). The disease course was 9-16 years (average 12.1 years). There were 2 cases of congenital scol iosis and 19 cases of idiopathic scol iosis, which included 5 cases of IA, 2 of IB, 1 of IIA, 2 of IIB, 2 of IIC, 2 of IIIA, 3 of IIIB, and 2 of IVA according to Lenke classification. There were 13 cases of thoracic scol iosis and 8 of thoracolumbar scol iosis. AP view and the lateral and anterior bending view of X-ray films before and at 3 to 6 months after removing PRSS were comparatively analyzed, the coronal and the sagittal Cobb angle were measured, and the height of vertebral body on the concave side and the convex side were measured, so as to know the effect of PRSS on the growth of the vertebral endplates. Results All the implants were removed successfully with an average operation time of 2.5 hours (range 2-4 hours) and a small amount of intraoperative blood loss. Twenty-one cases were followed up for 6-72 months (average 34.4 months). The coronal Cobb angle before and after the removal of PRSS was (20.25 ± 8.25)° and (23.63 ± 8.41)°, respectively, indicating there was no significant difference (P gt; 0.05); while the sagittal Cobb angle was (39.44 ± 12.38)° and (49.94 ± 10.42)°, respectively, indicating there was a significant difference (P lt; 0.05). The height of the top vertebral body on the concave side before and after the removal of PRSS was (1.78 ± 0.40) cm and (2.08 ± 0.35) cm, respectively, and there was a significant difference (P lt; 0.01); while the height on the convex side was (2.16 ± 0.47) cm and (2.18 ± 0.35) cm, respectively, indicating no significant difference was evident (P gt; 0.05). All the 21 patients had good prognosis and no major operative compl ication occurred. Conclusion PRSS is an effective instrumentation for the management of scol iosis. After the removal of the PRSS, the correction of scol iosis can be maintained, and the spinal mobil ity can be protected and restored.
【Abstract】 Objective To discuss the main points of techniques and ranges of fusion in posterior operation ofdegenerated lumbar scol iosis compl icated spinal stenosis. Methods From February 2001 to September 2006, 23 cases with degenerated lumbar scol iosis stenosis were treated by posterior operation. There were 9 males and 14 females, with the average age of 65.3 years (ranging from 52 years to 71 years). The course of the diseases was 4 to 8 years. All patients were presented with severe low back pain. All patients were measured for Cobb angle of curves(17° to 53°), and lordosis angle of lumbar (-20° to -10° 10 cases, -40° to -20° 13 cases). Ten cases in which Cobb angle was smaller than 20° were operated by l imited segmental decompression of spinal canal, posterior intervertebral fusion and short transpedical instrument fixation. For the rest 13 cases in which Cobb angle was bigger than 20° were operated by canal decompression, longer instrument for scol iosis correction, intervertebral fusion and posterior-lateral fusion. The fixation and fusion were located at L4-S1 in 6 cases, L1-5 in 5, L2-5 in 4, L1-S1 in 5, L2-S1 in 2 and T10-S1 in 1. Results There was no patient who died from the operation. Average Cobb angle in coronal plane was 0° to 21° with the average of 15.6°. The lumbar lordosis angle was -48.0° to -18.2° with the average of -36.4°. There were 21 cases (91%) with sciatica and intermittent claudication who were clearly released. There were 20 cases (87%) whose low back pain intensely decreased. Three cases with drop-foot returned to normal activities. During the mean 15-month (6 to 54 months) follow-up for 23 cases, there was no change of corrected results and fusion rate was 100%. Conclusion For degenerated lumbar scol iosis patients, the most important purpose of the treatment is to improve cl inical symptoms through sufficient decompression of neural structures. Lumbar stabil ization reconstruction and benign spinal biomechanics l ine conduce to longterm curative effect. Overall estimate of the cl inical appearances and imageology characters is necessary when the decision, that segments are needed to be fixed and fused should be made. The strategy of the individual ized treatment may be the best choice.
Objective To evaluate the safety and efficacy of the operation performed under the video-assisted thoracoscope to release the anterior part of the spine of the patient with severe adolescent idiopathic scoliosis (AIS). Methods From April 2004 to July 2006, 24 patients with AIS (Illness course, 1.5-9 years; Lenke Ⅰ in 17 patients, Lenke Ⅱ in 7; right scoliosis in 22, left scoliosis in 2), among whom there were 9 males and 15 females, with an average age of 14.7 years (range, 11-21 years) at the time of the operation. Before operation, the thoracic vertebral Cobb anger at the coronal plane was averaged 78.3°(range, 65-125°). All the patients had normal muscle strength and muscle tension in their lower limbs, but 5 of the patients had a decrease of the superficial sensation in their lower limbs. All the patients had a moderately or severely decreased lung reserve function. Under general anesthesia, the patient was placed in the lateral position to set up a work channel for thoracoscopy. The releasing of the thoracic intervertebral space and the confluence of the bone grafts were performed. During Stage Ⅰ or Stage Ⅱ, the orthopedic procedures for the posterior part of the scoliosis spine, the internal fixation, and the confluence ofthe bone grafts were completed. ResultsAll the patients survived the periodof perioperation. During operation, there was a hemorrhage of 50-200 ml, averaged 100 ml, with a postoperative thoracic closely-drained fluid of 100-150 ml. The incision was healed by the first intention. Each patient underwent the releaseof 4-6 intervertebral spaces, with an average of 5.5 spaces released. The average coronal Cobb angle was 45.6°(range, 25-75°). The physiological curvatureat the sagittal plane was normal, with an improved shape of the spine. The follow-up for 3-18 months averaged 9.3 months revealed that the bilateral pulmonary markings were clear, with confluence of the orthopedic segment of the spine. The patients could live and work normally, and had a significantly-improved psychological condition and an active social participation because of their improved appearance. Conclusion The releasing of the anterior part of the spine under the video-assisted thoracoscope can effectively release the adolescent idiopathic scoliosis and improve the flexibility of the spine, with a smaller degree of the surgical wound and a faster and clearer exposure of the spinal column during operation.
目的 探讨比较色努式脊柱侧弯矫形器佩戴时间及功能锻炼对矫正治疗效果的影响。 方法 将2004年7月-20011年7月收治的126例脊柱侧弯患者,按自愿选择分为试验组和对照组,试验组佩戴色努式脊柱侧弯矫形器18~20 h,功能锻炼>90 min;对照组佩戴侧弯矫形器23 h,功能锻炼30~60 min。对比两组患者治疗前后的Cobb角、顶椎偏离中线距离(AVT)、顶椎旋转度(AVR)、躯干位移(TS)、脊柱柔韧性及肺功能指标的改善。 结果 经X线检查测定,治疗后两组患者的Cobb角、AVT、AVR、TS均低于治疗前(P<0.01),且试验组明显低于对照组(P<0.01)。肺功能指标:试验组治疗后肺活量(VC)、第1秒钟用力呼气容积(FEV1)、用力肺活量(FVC)、肺总量(TLC),等均高于治疗前,残气量(RV)低于治疗前(P<0.01),对照组治疗后VC、FEV1、FVC、TLC均低于治疗前,RV高于治疗前(P<0.01),且试验组优于对照组(P<0.01)。功能位Cobb角:两组患者的功能位主弯Cobb角、代偿弯Cobb角均低于治疗前(P<0.01),且试验组明显低于对照组(P<0.01)。 结论 色努式脊柱侧弯矫形器每天佩戴18~20 h,并结合适当的体操疗法,呼吸、肌力训练及麦肯基力学疗法,可使肺功能、腰背部肌力、脊柱柔韧性、身体的协调性、以及平衡能力得到改善,从而达到脊柱侧弯治疗的较好效果。
目的:观察在青少年脊柱侧凸患者中术前实施综合性呼吸操锻炼的临床效果方法:选取46例伴有不同程度肺功能障碍的青少年脊柱侧弯患者作为研究对象,对其自入院后第一天即开始实施综合性呼吸操锻炼,观察术前肺功能的变化情况及术后肺部并发症的发生情况。结果:锻炼后患者肺活量(VC)、肺容量(TLC)、用力肺活量(FVC)、最大通气量(MVV),等肺功能指标较锻炼前有明显改善,差异具有统计学意义(Plt;0.05);术后血氧饱和度gt;95%;无肺部并发症发生。结论:入院后即进行综合性呼吸操锻炼能在近期有效改善患者肺功能,提高患者对脊柱矫形手术的耐受力,对预防和减少术后肺部感染以及呼吸功能不全的发生有积极作用。
ObjectiveTo investigate the influence and management of blood pressure on intraoperative cortex somatosensory evoked potential (CSEP) in the surgery of severe scoliosis. MethodsFrom June 2009 to March 2012, CSEP monitoring during surgery of severe scoliosis were performed on 43 patients, in whom 4 had abnormal CSEP while blood pressure decline. There were 2 males and 21 females. The average age was 16.1 years. The average preoperative Cobb angle was 96.1° (88.7-107.5°). Latency and amplitude of cortical potentials were observed with the value of the latency extension more than 10% and peak amplitude reduction more than 50% defined as abnormality. The arterial blood pressure (ABP) was used to evaluate the intraoperative blood pressure. ResultThe incidence rate of bilateral CSEP wave abnormalities after blood pressure decline was 9.3% in the surgery of severe scoliosis. One case of CSEP abnormality occurred during the installing of pedicle screws; two cases during the Smith-Petersen osteotomy, and one case during the bone graft after correction. With the ABP dropping to about 92/57 mm Hg (1 mm Hg=0.133 kPa), the amplitude decreased 80% in 24-33 minutes. After the ABP increased to 113/75 mm Hg by treatment, the index was backed up normally in 5-10 minutes. There was no neurological complication after surgery. ConclusionA high incidence rate and significantly decreased amplitude of CSEP abnormality after blood pressure decline in the surgery of severe scoliosis are found. Intraoperative stable blood pressure should be maintained for patients with severe scoliosis. When the amplitude of CSEP decreases followed with blood pressure decline, blood pressure should be actively corrected by treatment, so that the CSEP may get back to normal as soon as possible.
ObjectiveTo analyze the pressure change and distribution of the intervertebral disc of upper thoracic spine in vertical pressure and 5° flexion, extension, or lateral bending. MethodsTwelve thoracolumbar spinal specimens were harvested from mini pigs and were divided into 2 groups (n=6). T1, 2, T3, 4, T5, 6, and T7, 8 segments were included in one group, and T2, 3, T4, 5, T6, 7, and T8, 9 segments were included in the other group. The data from both groups represented the complete upper thoracic vertebra data. Biomechanical machine and pressure sensitive film were used to measure the pressure on the vertebral columns under loadings of 100, 150, and 200 N in vertical pressures and 5° flexion, extension, or lateral bending. The pressure change of each intervertebral disc under different loads and in different movement conditions was analyzed. ResultsIn flexion, the anterior annulus pressure of the upper thoracic vertebra increased (P < 0.05), whereas the posterior annulus pressure showed no significant change (P > 0.05) or an increasing trend (P < 0.05). In extension, the anterior annulus pressure of the upper thoracic vertebra decreased (P < 0.05), whereas the posterior annulus pressure decreased (P < 0.05) or had no obvious change (P > 0.05). In lateral bending, the pressure on the concave side of the annulus increased significantly (P < 0.05). ConclusionThe upper thoracic vertebra has unique biomechanical characteristics under different loadings; moreover, the posterior vertebral structure plays an important role in the movement of the upper thoracic vertebral segment and pressure distribution. In lateral bending of the upper thoracic vertebra, the concave side pressure will increase significantly, which suggests that asymmetrical force is an important cause of scoliosis progression. Gravity plays an important role in the progression of scoliosis.