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.
As a worldwide challenge in the field of neurosurgery, there is no effective treatment method for pediatric skull defects repair in clinic. Currently clinical used cranioplasty materials couldn’t undergo adjustment in response to skull growth and deformation. An ideal material for pediatric cranioplasty should fulfill the requirements of achieving complete closure, good osseointegration, biodegradability and conformability, sufficient cerebral protection and optimal aesthetic, and functional restoration of calvaria. Biomimetic mineralized collagen-based bone material is a kind of material that simulates the microstructural unit of natural bone on the nanometer scale. Because of its high osteogenic activity, it is widely used in repair of all kinds of bone defects. Recently, the biomimetic mineralized collagen-based bone materials have successfully been applied for cranial regeneration and repair with satisfactory results. This review mainly introduces the characteristics of the biomimetic mineralized collagen-based bone materials, the advantages for the repair of pediatric skull defects, and the related progresses.
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.
Objective To explore the clinical application value of mineralized collagen (MC) bone scaffolds in repairing various types of skull defects, and to assess the suitability and repair effectiveness of porous MC (pMC) scaffolds, compact MC (cMC) scaffolds, and biphasic MC composite (bMC) scaffolds. Methods A retrospective analysis was conducted on the clinical data of 105 patients who underwent skull defect repair with pMC, cMC, or bMC between October 2014 and April 2022. The cohort included 63 males and 42 females, ranging in age from 3 months to 55 years, with a median age of 22.7 years. Causes of defects included craniectomy after traumatic surgery in 37 cases, craniotomy in 58 cases, tumor recurrence or intracranial hemorrhage surgery in 10 cases. Appropriate MC scaffolds were selected based on the patient’s skull defect size and age: 58 patients with defects <3 cm² underwent skull repair with pMC (pMC group), 45 patients with defects ≥3 cm² and aged ≥5 years underwent skull repair with cMC (cMC group), and 2 patients with defects ≥3 cm² and aged <5 years underwent skull repair with bMC (bMC group). Postoperative clinical follow-up and imaging examinations were conducted to evaluate bone regeneration, the biocompatibility of the repair materials, and the occurrence of complications. Results All 105 patients were followed up 3-24 months, with an average of 13 months. No material-related complication occurred in any patient, including skin and subcutaneous tissue infection, excessive ossification, and rejection. CT scans at 6 months postoperatively showed bone growth in all patients, and CT scans at 12 months postoperatively showed complete or near-complete resolution of bone defects in all patients, with 58 cases repaired in the pMC group. The CT values of the defect site and the contralateral normal skull bone in the pMC group at 12 months postoperatively were (1 123.74±93.64) HU and (1 128.14±92.57) HU, respectively, with no significant difference (t=0.261, P=0.795). Conclusion MC exhibits good biocompatibility and osteogenic induction ability in skull defect repair. pMC is suitable for repairing small defects, cMC is suitable for repairing large defects, and bMC is suitable for repairing pediatric skull defects.
摘要:目的:进行深低温贮存回植自体颅骨瓣的临床应用效果研究。方法:将74例患者术后骨瓣深低温(零下80℃)贮存,2~12月后予以原位回植,术中取骨标本病检,随诊1~36月。结果:74例中72例伤口Ⅰ期愈合,颅骨复位良好。病检示回植骨有正常骨细胞,与新鲜颅骨对照无骨母细胞。2例患者回植骨吸收明显,失去支撑作用而再次行修补钛网,2例感染,余下70例患者2~4月后骨缝不同程度增宽1~2 mm,6月后骨缝不再增宽,12~36月后骨缝部分变窄,达骨性愈合,而颅骨钻孔处及颞下骨缝较宽区未见骨性结构,为纤维疤痕愈合。结论:深低温贮存的自体颅骨部分骨细胞能长时间存活,回植后无免疫排异性。回植手术简便,患者容易接受,临床应用效果较好。
Objective To observe the relationship of osteoblasts, endothelial cells and ceramic scaffold during reconstruction of rat critical size calvarial defects with tissue engineering technique under transmission electron microscope. Methods Fourteen male adult Sprague Dawley rats were divided randomly into experimental and control groups. Bone marrow was obtained from left femurs and tibias of all rats. In experimental group, respective autogenous osteoblasts derived from bone marrow stromal cells(MSCs) different iated and proliferated in vitro and then were seeded and subcultured on porous calcium phosphate ceramics. The cell-ceramic compounds were used to repair critical-sized (8 mm diameter) calvarial defects in the corresponding rats. In control group, the ceramic without autogenous osteoblosts was used. One rat of each group was sacrificed postoperatively in the 4th, 8th, 12th, 24th, 28th weeks respectively and involved samples were removed to make decalcified ultrath in sections and observed under transmissionelectron microscope. Results Osteoblasts or osteoblast-like cells always located next to sprouting capillaries and the relationship between osteoblasts and endothelial cells was relevant in experimental group. There was a calcium depositzone distributed along the boundary of newly formed bone and the remnants of decalcified ceramic, which meant osseointegration between the ceramic and newly formed bone. The above changes did not appear in control group simultaneously.Conclusion The nanometer scale structure of ceramic scaffold benefits to angiogenesis, osteogenesis and extracellular matrix formation in repair bone defects with tissue engineering technique.
Objective To investigate the operative procedure and the effectiveness of cranial bone reconstruction after one-stage resection of scalp squamous carcinoma invading the skull. Methods Between January 2005 and December 2008,14 patients with scalp squamous carcinoma invading the skull were treated. There were 6 males and 8 females with a median age of 53 years (range, 29-76 years). The disease duration ranged from 3 to 8 years (mean, 6 years). The tumor locations were right temporal area in 2 cases, left temporal area in 2 cases, right frontal area in 3 cases, left frontal area in 1 case, right occi pital area in 1 case, left occi pital area in 2 cases, frontal area in 2 cases, and the top of the head in 1 case. Scalp lesions showed exogenous growth, and lesion diameter ranged from 5 to 12 cm (mean, 8 cm). TNM classification showed T4N0M0 tumor in all cases. MRI showed that tumors invaded the skull, 12 cases had smooth intradural side and 2 cases had brain involvement without lymph node metastasis or detected distant metastasis. Under general anesthesia, all the lesions of the scalp, skull, dura, and brain tissue were removed completely. The size defect of the scalp, skull, and dura ranged from 8 cm × 7 cm to 15 cm × 14 cm, from 5 cm × 4 cm to 12 cm × 12 cm, and from 4 cm × 4 cm to 9 cm × 8 cm, respectively, which were repaired with artificial patch, titanium metal, mesh, and local flaps, respectively. The donor site was repaired by spl it-thickness skin graft. Results The skin flaps and grafts survived and incision healed by first intention without cerebrospinal fluid leakage, intracranial and subdural hemorrhage, andother compl ications. All patients were followed up 2 to 5 years (mean, 4 years), and no recurrence was found. The compatibil ity of titanium mesh and local tissue was good. The patients had good hair growth without exposure of titanium mesh, seizures, partial paralysis, and other neurological damage performance. Conclusion After one-stage resection of scalp squamous carcinoma invading the skull, it is effective to reconstruct the skull with titanium mesh and to repair dural defects with artificial dura.
ObjectiveTo observe and compare the effects of peptides on the repair of rabbit skull defects through two different binding modes of non-covalent and covalent, and the combination of carboxyl (-COOH) and amino (-NH2) groups with materials.MethodsTwenty-one 3-month-old male ordinary New Zealand white rabbits were numbered 1 to 42 on the left and right parietal bones. They were divided into 5 groups using a random number table, the control group (group A, 6 sides) and the material group 1, 2, 3, 4 (respectively group B, C, D, E, 9 sides in each group). All animals were prepared with 12-mm-diameter skull defect models, and bone morphogenetic protein 2 (BMP-2) non-covalently bound multiwalled carbon nanotubes (MWCNT)-COOH+poly (L-lactide) (PLLA), BMP-2 non-covalently bound MWCNT-NH2+PLLA, BMP-2 covalently bound MWCNT-COOH+PLLA, and BMP-2 covalently bound MWCNT-NH2+PLLA were implanted into the defects of groups B, C, D, and E, respectively. At 4, 8, and 12 weeks after operation, the samples were taken for CT scanning and three-dimensional reconstruction, the ratio of bone tissue regeneration volume to total volume and bone mineral density were measured, and the histological observation of HE staining and Masson trichrome staining were performed to quantitatively analyze the volume ratio of new bone tissue.ResultsCT scanning and three-dimensional reconstruction showed that with the extension of time, the defects in groups A-E were filled gradually, and the defect in group E was completely filled at 12 weeks after operation. HE staining and Masson trichrome staining showed that the volume of new bone tissue in each group gradually increased with time, and regenerated mature bone tissue appeared in groups D and E at 12 weeks after operation. Quantitative analysis showed that at 4, 8, and 12 weeks after operation, the ratio of bone tissue regeneration volume to total volume, bone mineral density, and the volume ratio of new bone tissue increased gradually over time; and at each time point, the above indexes increased gradually from group A to group E, and the differences between groups were significant (P<0.05).ConclusionThrough covalent binding and using -NH2 to bound peptides with materials, the best bone repair effect can be achieved.