Objective Currently, there are few researches on lordosis associated with scol iosis. To explore the effects of nickel-titanium memory alloy staple (Staple) on the growth of thoracic lordosis by observing the histological changes of cartilage cells in the osteoepiphysis of the thoracic vertebrates in goats. Methods Eighteen 2-3 months old female goats, weighing 8-12 kg, were randomly divided into long staple group (n=6), short staple group (n=6), and blank control group (n=6). Long staple (7 mm) and short staple (4 mm) were implanted into T6-11 segments of goats in long and short staplegroups by anterior approach, respectively. The blank control group was not treated. The X-ray examination was performedpre-operatively and at 3 months post-operatively to observe the changes of Cobb angle. Then the growth plates and inferior facet processes of the apex vertebral body were harvested to observe the histological grades of cartilage by HE staining, and to observe prol iferation and apoptosis of chondrocytes through immunohistochemistry double label ing staining with poly-ADPribose- polymerase-p85 and prol iferating cell nuclear antigen. Results At 3 months after operation, the T6-11 Cobb angles were significantly higher than those of pre-operation in short staple group and long staple group, which were significantly higher than those in blank control group (P lt; 0.05), but there was no significant difference between short staple group and long staple group (P gt; 0.05). The results of HE staining and immunohistochemistry double staining showed that the number of chondrocytes were reduced obviously with irregular columnar arrangement and increased volume ratio of surrounding extracellular matrix in prol iferative zone and hypertrophic zone of growth plate and inferior articular process in both long and short staple groups, and this tendency was more noticeable in long staple group. There were significant differences in the grades of prol iferation viabil ity of chondrocytes between 2 staple groups and blank control group (P lt; 0.05), but there was no significant difference tewteen long staple group and short staple group (P gt; 0.05). The prol iferation viabil ities of chondrocytes in growth plate and inferior articular process were significantly higher in blank control group than in 2 staple groups (P lt; 0.01), but there was no significant difference between long staple group and short staple group (P gt; 0.05). Conclusion The histological evidences prove that the Staple implantation by anterior approach can reduce prol iferation viabil ity of chondrocytes in growth plate and inferior articular process of the thoracic vertebrates in goats, which conduces the growth direction of thoracic vertebrates to kyphosis.
Objective To evaluate pulmonary function changes in patients with severe scol iosis undergoing anterior release, posterior segmental fixation and fusion, and convex thoracoplasty by resecting a short length of rib. Methods FromJanuary 2006 to July 2007, 16 patients with severe scol iosis were treated with anterior release, posterior segmental fixation and fusion, and convex thoracoplasty by resecting a short length of rib. There were 6 males and 10 females with an average age of 16.9 years (range, 10-24 years). There were 1 case of Lenke 1 curve, 9 cases of Lenke 2 curve, and 6 cases of Lenke 4 curve. The preoperative Cobb angle was (104.8 ± 10.9)° and the preoperative thoracic kyphotic angle was (30.0 ± 4.2)°. The preoperative height of “razor back” deformity was (5.9 ± 1.2) cm. Before operation, the actual value of forced vital capacity (FVC) was (2.04 ± 0.63) L and that of forced expiratory volume in 1 second (FEV1.0) was (1.72 ± 0.62) L. The percentage of actual values to expected ones in FVC was 70% ± 16%, and that in FEV1.0 was 67% ± 15%. All patients had pulmonary function tests before operation and 3, 6, 12, 24 months after operation. Results All wounds healed by first intention. The Cobb angle at 24-month follow-up was (53.4 ± 18.6)° and the correction rate was 49.0% ± 15.3%. The thoracic kyphotic angle at 24-month follow-up was (34.0 ± 2.4)° and the correction rate was 13.3% ± 2.2%. The height of “razor back” deformity at 24-month follow-up was (2.2 ± 0.8) cm. Compared with preoperative level, all these data showed significant differences (P lt; 0.05). At 3 and 6 months, the actual values of FVC and FEV1.0 decl ined, but no significant difference was found (P gt; 0.05). At 12 and 24 months, the actual values of FVC andFEV1.0 were close to the preoperative level (P gt; 0.05). The percentages of actual values to expected ones in FVC and FEV1.0 indicate continued improvement in pulmonary function from the postoperative 3 to 24 months follow-up. Compared with preoperative level, the percentages of actual values in FVC decl ined 19% 3 months postoperatively (P lt; 0.05) and 12% 6 months postoperatively (P lt; 0.05). The percentages of actual values to expected ones in FEV1.0 decl ined 16% 3 months postoperatively (P lt; 0.05), and 10% 6 months postoperatively (P lt; 0.05). The percentages of actual values to expected ones in FVC and FEV1.0 were close to the preoperative level 12 and 24 months after operation (P gt; 0.05). Conclusion In severe scol iosis patients who are treated with anterior release, posterior segmental fixation and fusion, and convex thoracoplasty by resecting a short length of rib, pulmonary function decreases obviously 3-6 months after operation. And it returns to the operative baseline 12-24 months after operation.
Objective To analyze the cl inical features of scol iosis associated with Chiari I malformation in adolescent patients, and to explore the val idity and safety of one-stage posterior approach and vertebral column resection for the correction of severe scol iosis. Methods Between October 2004 and August 2008, 17 adolescent patients with scol iosis associated with Chiari I malformation were treated with surgical correction through posterior approach and pedicle instrumentation. There were 9 males and 8 females with an average age of 15.1 years (range, 12-19 years). The MRI scanning showed that 16 of 17 patients had syringomyel ia in cervical or thoracic spinal cord. Apex vertebra of scol iosis were located atT7-12. One-stage posterior vertebral column resection and instrumental correction were performed on 9 patients whose Cobb angle of scol iosis or kyphosis was more than 90°, or who was associated with apparent neurological deficits (total spondylectomy group). Other 8 patients underwent posterior instrumental correction alone (simple correction group). All patients’ fixation and fusion segment ranged from upper thoracic spine to lumbar spine. Results The operative time and the blood loss were (384 ± 65) minutes and (4 160 ± 336) mL in total spondylectomy group, and were (246 ± 47) minutes and (1 450 ± 213) mL in simple correction group; showing significant differences (P lt; 0.05). In total spondylectomy group, coagulation disorder occurred in 1 case, pleural perforation in 4 cases, and lung infection in 1 case. In simple correcction group, pleural perforation occurred in 1 case. These patients were improved after symptomatic treatment. All patients were followed up 24-36 months (32.5 months on average). Bony heal ing was achieved at 6-12 months in total spondylectomy group. No breakage or pull ingout of internal fixator occurred. The angles of kyphosis and scol iosis were significantly improved at 1 week after operation (P lt; 0.01) when compared with those before operation. The correction rates of scol iosis and kyphosis (63.4% ± 4.6% and 72.1% ± 5.8%) in total spondylectomy group were better than those (69.4% ± 17.6% and 48.8% ± 19.3%) in simple correction group. Conclusion Suboccipital decompression before spine deformity correction may not always be necessary in adolescent scol iosis patients associated with Chiari I malformation. In patients with severe and rigid curve or apparente neurological deficits, posterior vertebral column resection would provide the opportunity of satisfied deformity correction and decrease the risk of neurological injury connected with surgical correction.
Objective To further investigate the possible mechanism of the correction of scol iosis with Staple by quantifying the effect of Staple on growth rate of vertebral growth plates in goat scol iosis. Methods Experimental scol iosis was created in 10 juvenile female goats by using unilateral pedicle screws asymmetric tethering. After 8-10 weeks, goats were divided randomly into Staple treated group (n=5) and control group (n=5). All tethers were removed in both groups and Staplegroup underwent anterior vertebral stapl ing with 4-5 shape memory alloy Staples along the convexity of the maximal curvature after posterior tether being removed. All goats were observed for an additional 8-13 weeks, the Cobb angle were measured to observe the correction of scol iosis. The fluorochromes Oxytetracycl ine and Calcein were administered respectively 18 and 3 days before death to label the ossifying front under the growth plates. Superior intervertebral disc of apical vertebra and two adjacent growth plates were completely harvested in all goats. All specimens were embedded with polymethyl methacrylate and sl iced undecalcified. The growth rates of the vertebral growth plates were calculated by measuring the distance between the two fluorescent l ines with fluorescence microscope. Results Nine (5 in Staple treated group and 4 in control group) of 10 tethered goats had progressive scol iotic curves of significant magnitude after 8-10 weeks of tethering. In Staple treated group, the Cobb angles were (34.8 ± 12.4)° at the instant after treatment , and (15.6 ± 11.7)° 8-13 weeks after treatment; showing statistically significant difference (P lt; 0.05). In the control group, the Cobb angles were (49.3 ± 18.0)° at the instant after treatment, and(49.0 ± 17.6)° 8-13 weeks after treatment; showing no statistically significant difference (P gt; 0.05). In Staple treated group, the growth rate of growth plate in the concavity (3.27 ± 0.96) μm/d was higher than that in convexity (1.84 ± 0.52) μm/d (P lt; 0.05), while the growth rate of the concavity did not differ significantly from that of the convexity in control group (P gt; 0.05). Conclusion Staple can significantly alter the growth rates of two sides of vertebrae in scol iosis with the growth rate of concavity exceeding the one of convexity, which results in correction of deformity.
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.