It is very difficult to repair large articular cartilage defect of the hip. From May 1990 to April 1994, 47 hips in 42 patients of large articuler cartilage defects were repaired by allograft of skull periosteum. Among them, 14 cases, whose femoral heads were grade. IV necrosis, were given deep iliac circumflex artery pedicled iliac bone graft simultaneously. The skull periosteum had been treated by low tempreturel (-40 degrees C) before and kept in Nitrogen (-196 degrees C) till use. During the operation, the skull periosteum was sutured tightly to the femoral head and sticked to the accetabulum by medical ZT glue. Thirty eight hips in 34 patients were followed up for 2-6 years with an average of 3.4 years. According to the hip postoperative criteria of Wu Zhi-kang, 25 cases were excellent, 5 cases very good, 3 cases good and 1 case fair. The mean score increased from 6.4 before operation to 15.8 after operation. The results showed, in compare with autograft of periosteum for biological resurface of large articular defect, this method is free of donor-site morbidity. Skull periosteum allograft was effective for the treatment of large articular cartilage defects in hip.
Based on the dye injection investigation, the territory of blood supply through the superficial temperal artery system was defined. Vascularized grafts, composed of temperal-parietal fascia, periosteum and outer-table of calvarial bone, can be transferred by microvascular anastomosis or transposed to repair full-thickness defects of skull bone was demonstrated. Six of such cases following electrical burn were successfully treated. The average size of skull bone defects was 50cm2. The largest one among them was 80cm2.
Objective To investigate the effect of tissue engineering bone compounded in vitro by nanohydroxyapatite/collagen/ polylactic acid (nHAC/PLA) and recombinant human bone morphogenetic protein 2 (rhBMP-2) in repairing rabbit critical calvarial defects. Methods Forty eight New Zealand rabbits, weighting 2.0-2.5 kg, were made the models of critical cranial defects(15 mm in diameter) and divided into 4 groups randomly. Defects were repaired with autoflank bone in the positive control group; with no implant in the blank control group; with nHAC/PLA in the negative control; and with active nHAC/PLA(AnHAC/PLA) in the experimental group(the average quality of each AnHAC/PLA absorbed rhBMP-2 was 1.431 mg). The reapir results were observed through X-ray,HE dyeing and Masson’s trichrism dyeing after 8 and 16 weeks. Results The difference of bone formation was observed by X-ray block degree of skull defect area at 8 and 16 weeks. In the 8 th week and 16 th week, the radiopacities on cranial defect were 67.21%±2.06% and 86.48%±1.73% in the positive control group; 5.84%±1.92% and 9.48%±2.72% in the blank control group; 19.13%±2.51% and 35.67%±3.28% in the negative control group; and 58.84%±2.55% and 8561%±3.36% in the experimental group. There were significant differences between the negative control and the positive control group, and between the experimental group and the positive control group at 8 weeks(Plt;0.05) . There were significant differences between the negative control and blank group, and between the experiment and the blank group at 8 and 16 weeks(P<0.05). The histology observation showed that the width of bone trabecula at 16 weeks was more than that at 8 weeks and bone defectwas full of bone tissue in positive control group. The bone defect was full of fibrous tissue at 8 and 16 weeks, and there was no new bone in the blank group. The bone defect was full of remnant material and fibrous tissue in the negative control group. The implanted area was replaced by the new bone at 8 weeks and the new bone was lamellar at 16 weeks in the experimental group; the residual material was less in defect area and there were more osteoblasts surrounding. Conclusion The nHAC/PLA is a good scaffoldmaterial of rhBMP-2 and AnHAC/PLA has agood ability in repairing bone defect. So it is hopeful to be applied in the clnical repair of large bone defect.
目的:探讨儿童颅骨血管瘤的临床特点和手术治疗。方法:报告自2002年1月至2008年12月我院收治的3例儿童颅骨血管瘤病例,结合相关文献分析该疾病的临床表现,影像学特征,病理特点及治疗方法。结果:儿童颅骨血管瘤临床上极为罕见。影像学检查显示颅骨呈蜂窝状溶骨性改变并向颅内外生长。病理切片显示骨结构异常,并伴有大小不等异常血管增生及血栓形成。结论:颅骨血管瘤是一种侵蚀颅骨内外板的破坏性疾病。手术应早期进行,完整切除后,患者预后良好。
Objective To investigate the clinical application of self-cranial bone powder in one stage cranioplasty.Methods From October 1999 to December 2002,self-cranial bone powder and medical adhesive were used to repair the skull defect, for one stage cranioplasty, caused by operations on cranium in 128 casesof severe dangerous craniocerebral injury, acute intracranial hematome, sick skull and intracranial tumor.The bone growth was observed by CT or X-ray examination 3-24 months after replantation of cranioplasty.Results The decompression and cranioplasty were performed simultaneously, the time prolonged 5-10 minutes than that of routine, the appearance of repaired cranial bone was normal, without concavity and convexity. After 12 months of operation, the replanted bone merged with the normal bone completely, with normal appearance. The operation successful rate was 96.1%(123/125) without any complication. Only fivecases were not better in growing because of less bone powder, but withoutcerebral pulse and defective syndrome. All the cases did not need secondary cranioplasty.Conclusion The effect of cranioplasty with self-cranial bone powder effect is good in taking shape. This new method can avoid the traditional secondary cranioplasty for skull defect and complications.
Craniofacial malformation caused by premature fusion of cranial suture of infants has a serious impact on their growth. The purpose of skull remodeling surgery for infants with craniosynostosis is to expand the skull and allow the brain to grow properly. There are no standardized treatments for skull remodeling surgery at the present, and the postoperative effect can be hardly assessed reasonably. Children with sagittal craniosynostosis were selected as the research objects. By analyzing the morphological characteristics of the patients, the point cloud registration of the skull distortion region with the ideal skull model was performed, and a plan of skull cutting and remodeling surgery was generated. A finite element model of the infant skull was used to predict the growth trend after remodeling surgery. Finally, an experimental study of surgery simulation was carried out with a child with a typical sagittal craniosynostosis. The evaluation results showed that the repositioning and stitching of bone plates effectively improved the morphology of the abnormal parts of the skull and had a normal growth trend. The child’s preoperative cephalic index was 65.31%, and became 71.50% after 9 months’ growth simulation. The simulation of the skull remodeling provides a reference for surgical plan design. The skull remodeling approach significantly improves postoperative effect, and it could be extended to the generation of cutting and remodeling plans and postoperative evaluations for treatment on other types of craniosynostosis.
In order to repair cartilage defect in joint with transplantation of cryopreserved homologous embryonic periosteum, 30 rabbits were used and divided into two groups. A 4 mm x 7 mm whole thickness cartilage defect was made in the patellar groove of femur of each rabbit. The homologous embryonic rabbit skull periosteum (ERSP), preserved in two-step freezing schedule, was transplanted onto the cartilage defect of joints of one group and autogenous periosteal graft was done in the joint defect of the other group. The knees were not immobilized, following operation and 16 weeks later, the newly formed tissue in the defects were assessed by gross observation, histochemical examination and biochemical analysis. The results showed that new hyaline-like cartilage was formed in the cryopreserved ERSP grafted knee, and had no significant difference from that of the knee receiving autogenous periosteal graft, but had significant difference from that of the fresh ERSP grafted knee and the non-grafted knee. Furthermore, the new hyaline-like cartilage had the biochemical characteristics of a fibrous cartilage. The conclusion was that this method might be feasible to repair articular cartilage defects.
Objective To investigate the effectiveness and adverse effect of the absorbable fixation system on cranial bone flap reposition and fixation after craniotomy. Methods Between July 2010 and December 2011, 67 cases underwent cranial bone flap reposition and fixation with absorbable fixation system after craniotomy and resection of intracranial lesions. There were 38 males and 29 females with a median age of 32 years (range, 5 months to 73 years). The disease duration ranged from 3 months to 6 years (median, 25 months). Forty-one lesions were located at supratentorial and 26 at subtentorial, including at the frontotemporal site in 13 cases, at the frontoparietal site in 12 cases, at the temporal oprietal site in 8 cases, at the temporooccipital site in 5 cases, at the occipitoparietal site in 4 cases, and at the posterior cranial fossa in 25 cases. The diagnosis results were glioma in 15 cases, cerebral vascular diseases (aneurysm, arteriovenous malformation, and cavemous angioma) in 8 cases, meningioma in 7 cases, arachnoid cyst in 7 cases, acoustic neurinoma in 5 cases, cholesteatoma in 3 cases, primary trigeminal neuralgia in 5 cases, cerebral abscess in 3 cases, hypophysoma in 2 cases, craniopharyngioma in 2 cases, metastatic tumor in 2 cases, radiation encephalopathy in 2 cases, medulloblastoma in 1 case, ependymocytoma in 1 case, germinoma in 1 case, atypical teratoma/rhabdoid tumor in 1 case, facial spasm in 1 case, and subdural hematoma in 1 case. Intracranial lesion size ranged from 3 cm × 2 cm to 7 cm × 5 cm. The changes of local incision and general condition were observed. Results Subcutaneous effusion occurred in 2 supratentorial lesions and 3 subtentorial lesions, which was cured at 2 weeks after puncture and aspiration. All incisions healed primarily and no redness or swelling occurred. CT scans showed good reposition of the cranial bone flap and smooth inner and outer surfaces of the skull at 2 weeks after operation. All 67 patients were followed up 3-20 months (mean, 10.3 months). During follow-up, the skull had satisfactory appearance without discomfort, local depression, or effusion. Moreover, regular CT and MRI scans showed no subside, or displacement of the cranial bone flap or artifacts. Conclusion Absorbable fixation system for reposition and fixation of the cranial bone flap not only is simple, safe, and reliable, but also can eliminate the postoperative CT or MRI artifact caused by metals fixation system.