中国组织工程研究与临床康复
中國組織工程研究與臨床康複
중국조직공정연구여림상강복
JOURNAL OF CLINICAL REHABILITATIVE TISSUE ENGINEERING RESEARCH
2008年
45期
8931-8934
,共4页
李晋%曲戎梅%戴景兴%周志涛%原林
李晉%麯戎梅%戴景興%週誌濤%原林
리진%곡융매%대경흥%주지도%원림
生物相容性%材料%骨移植%组织工程
生物相容性%材料%骨移植%組織工程
생물상용성%재료%골이식%조직공정
背景:骨组织工程研究的核心是构建类似人体骨组织结构和性能的组织工程支架.目的:对比观察猪骨支架材料与人骨支架材料的理化性能及力学性能.设计、时间及地点:对比观察实验,于2006-03/12在南方医科大学临床解剖学研究所和广东省组织构建与检测重点试验室完成.材料:新鲜健康成人尸体4具由广州市红十字会南方医科大学遗体捐献接收点提供,家属知情同意.市售低温深冻6个月的成年猪6只.方法:取人和猪髂骨,剔除软组织,刮除骨髓和骨膜,用锯骨机将松质骨切成5 mm×5 mm×40mm左右的骨条,超声清洗、H2O2和乙醇浸泡、甩干、冻干、辐照处理得到猪骨支架材料和人骨支架材料.主要观察指标:对两种支架材料进行扫描电镜观察;对比两种支架材料孔隙率、蛋白质和钙、磷含量及力学性能.结果:扫描电镜下两种材料均具有骨本身的骨小梁、小梁间隙及骨内管腔系统,具有天然网状结构.三维支架系统形态完整,其中猪骨支架材料较人骨支架材料具有更多的三维孔隙,2种材料的孔隙大小接近,均在400 μm左右.猪骨支架材料孔隙率高于人骨支架材料(P<0.05),蛋白质含量低于人骨支架材料(P<0.05),钙、磷含量与人骨支架材料相当(P>0.05).两种支架材料弹性模量比较差异无显著性意义(P>0.05).结论:猪骨支架材料在理化性能和力学性能方面与人骨支架材料极相近.
揹景:骨組織工程研究的覈心是構建類似人體骨組織結構和性能的組織工程支架.目的:對比觀察豬骨支架材料與人骨支架材料的理化性能及力學性能.設計、時間及地點:對比觀察實驗,于2006-03/12在南方醫科大學臨床解剖學研究所和廣東省組織構建與檢測重點試驗室完成.材料:新鮮健康成人尸體4具由廣州市紅十字會南方醫科大學遺體捐獻接收點提供,傢屬知情同意.市售低溫深凍6箇月的成年豬6隻.方法:取人和豬髂骨,剔除軟組織,颳除骨髓和骨膜,用鋸骨機將鬆質骨切成5 mm×5 mm×40mm左右的骨條,超聲清洗、H2O2和乙醇浸泡、甩榦、凍榦、輻照處理得到豬骨支架材料和人骨支架材料.主要觀察指標:對兩種支架材料進行掃描電鏡觀察;對比兩種支架材料孔隙率、蛋白質和鈣、燐含量及力學性能.結果:掃描電鏡下兩種材料均具有骨本身的骨小樑、小樑間隙及骨內管腔繫統,具有天然網狀結構.三維支架繫統形態完整,其中豬骨支架材料較人骨支架材料具有更多的三維孔隙,2種材料的孔隙大小接近,均在400 μm左右.豬骨支架材料孔隙率高于人骨支架材料(P<0.05),蛋白質含量低于人骨支架材料(P<0.05),鈣、燐含量與人骨支架材料相噹(P>0.05).兩種支架材料彈性模量比較差異無顯著性意義(P>0.05).結論:豬骨支架材料在理化性能和力學性能方麵與人骨支架材料極相近.
배경:골조직공정연구적핵심시구건유사인체골조직결구화성능적조직공정지가.목적:대비관찰저골지가재료여인골지가재료적이화성능급역학성능.설계、시간급지점:대비관찰실험,우2006-03/12재남방의과대학림상해부학연구소화광동성조직구건여검측중점시험실완성.재료:신선건강성인시체4구유엄주시홍십자회남방의과대학유체연헌접수점제공,가속지정동의.시수저온심동6개월적성년저6지.방법:취인화저가골,척제연조직,괄제골수화골막,용거골궤장송질골절성5 mm×5 mm×40mm좌우적골조,초성청세、H2O2화을순침포、솔간、동간、복조처리득도저골지가재료화인골지가재료.주요관찰지표:대량충지가재료진행소묘전경관찰;대비량충지가재료공극솔、단백질화개、린함량급역학성능.결과:소묘전경하량충재료균구유골본신적골소량、소량간극급골내관강계통,구유천연망상결구.삼유지가계통형태완정,기중저골지가재료교인골지가재료구유경다적삼유공극,2충재료적공극대소접근,균재400 μm좌우.저골지가재료공극솔고우인골지가재료(P<0.05),단백질함량저우인골지가재료(P<0.05),개、린함량여인골지가재료상당(P>0.05).량충지가재료탄성모량비교차이무현저성의의(P>0.05).결론:저골지가재료재이화성능화역학성능방면여인골지가재료겁상근.
BACKGROUND: The core of bone tissue engineering is to construct a scaffold that is similar to human bone tissue structure and features.OBJECTIVE: To compare pathochemical and mechanical characteristics between pig and human bone scaffold materials.DESIGN, TIME AND SETTING: Contrast study was performed at Clinical Anatomy Institute, South Medical University; Guangdong Province Key Laboratory of Tissue Construction and Detection from March to December 2006.MATERIALS: Four fresh health adult human cadavers were provided by South Medical University, Guangzhou Red Cross Society, and the relatives knew the fact. Ultra low temperature freezing 6-month iliac bones of 6 adult swines were also used in this study.METHODS: Pig iliac and healthy adults iliac bones were obtained to remove soft tissue, curettage periosteum and bone marrow. Bone sawing machine was used to cut cancellous bone into smaller bone sections around 5 mm×5 mm×40 mm, which underwent ultrasonic cleaning, H2O2 and alcohol soaking, freeze drying and radiation treatment; finally, xenogeneic bone scaffold and allogeneic bone scaffold were obtained.MAIN OUTCOME MEASURES: Xenogeneic bone scaffold material and human allograft bone scaffold were observed with scanning electron microscopy to compare porosity, contents of protein content, calcium and phosphorus, and mechanical properties.RESULTS: Xenogeneic bone scaffold and allogeneic bone scaffold both had intrinsical bone trabecula, trabecular spaces and bone cavity system. Both of them had unabridged natural three dimensional network structure. The 3D supporting frames of them were complete. The xenogeneic bone scaffold had more spaces than allogeneic bone scaffold. The size of both scaffolds was approximation, about 400 μm. The interval porosity of xenogeneic bone scaffold was higher than the allogeneic bone scaffold (P<0.05). And the protein of xenogeneic bone scaffold was not as many as it of allogeneic bone scaffold (P<0.05). The contents of Ca and P were similar (P>0.05), and there was no significant difference in Young's modulus of xenogeneic bone scaffold and allogeneic bone scaffold (P>0.05).CONCLUSION: Xenogeneic bone scaffold may completely meet the clinical demands for bone grafting or be the scaffold of bone tissue engineering in mechanical chemical properties.