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
2010年
6期
962-966
,共5页
贺月秋%陈惠金%钱龙华%陈冠仪
賀月鞦%陳惠金%錢龍華%陳冠儀
하월추%진혜금%전룡화%진관의
脑室周围白质软化%分化%神经干细胞%干细胞%胎鼠
腦室週圍白質軟化%分化%神經榦細胞%榦細胞%胎鼠
뇌실주위백질연화%분화%신경간세포%간세포%태서
背景:脑室周围白质软化是早产儿脑损伤的主要类型,迄今尚无防治方法.对丢失大量少突胶质细胞的白质进行神经干细胞移植,理论上应是治疗脑室周围白质软化最为理想的方案.目的:体外培养制备具有多向分化潜能的胎鼠神经干细胞,以供后期实验经脑室移植应用.方法:取孕12~14 d胎鼠大脑皮质组织,剪成1.0 mm~3小块制备单细胞悬液分离纯化,待形成细胞球后加入含小牛血清的DMEM/F12培养基进行诱导分化培养.观察神经干细胞的原代、传代培养情况,免疫组化法对神经干细胞分化情况进行鉴定.结果与结论:培养的神经干细胞活力为(94.3±2.2)%,原代培养3 d形成神经球,体外传至10代左右,神经球的细胞团增殖速度明显减慢,部分细胞老化.各代神经球均呈巢蛋白染色阳性,可确认为神经干细胞.进一步对第4代神经球诱导分化培养后,免疫组化结果分别呈GFAP,β-tublin和O4阳性.提示所制备的神经干细胞具有自我更新和增殖能力,并具备向神经元、星形胶质细胞及少突胶质细胞分化的潜能.
揹景:腦室週圍白質軟化是早產兒腦損傷的主要類型,迄今尚無防治方法.對丟失大量少突膠質細胞的白質進行神經榦細胞移植,理論上應是治療腦室週圍白質軟化最為理想的方案.目的:體外培養製備具有多嚮分化潛能的胎鼠神經榦細胞,以供後期實驗經腦室移植應用.方法:取孕12~14 d胎鼠大腦皮質組織,剪成1.0 mm~3小塊製備單細胞懸液分離純化,待形成細胞毬後加入含小牛血清的DMEM/F12培養基進行誘導分化培養.觀察神經榦細胞的原代、傳代培養情況,免疫組化法對神經榦細胞分化情況進行鑒定.結果與結論:培養的神經榦細胞活力為(94.3±2.2)%,原代培養3 d形成神經毬,體外傳至10代左右,神經毬的細胞糰增殖速度明顯減慢,部分細胞老化.各代神經毬均呈巢蛋白染色暘性,可確認為神經榦細胞.進一步對第4代神經毬誘導分化培養後,免疫組化結果分彆呈GFAP,β-tublin和O4暘性.提示所製備的神經榦細胞具有自我更新和增殖能力,併具備嚮神經元、星形膠質細胞及少突膠質細胞分化的潛能.
배경:뇌실주위백질연화시조산인뇌손상적주요류형,흘금상무방치방법.대주실대량소돌효질세포적백질진행신경간세포이식,이론상응시치료뇌실주위백질연화최위이상적방안.목적:체외배양제비구유다향분화잠능적태서신경간세포,이공후기실험경뇌실이식응용.방법:취잉12~14 d태서대뇌피질조직,전성1.0 mm~3소괴제비단세포현액분리순화,대형성세포구후가입함소우혈청적DMEM/F12배양기진행유도분화배양.관찰신경간세포적원대、전대배양정황,면역조화법대신경간세포분화정황진행감정.결과여결론:배양적신경간세포활력위(94.3±2.2)%,원대배양3 d형성신경구,체외전지10대좌우,신경구적세포단증식속도명현감만,부분세포노화.각대신경구균정소단백염색양성,가학인위신경간세포.진일보대제4대신경구유도분화배양후,면역조화결과분별정GFAP,β-tublin화O4양성.제시소제비적신경간세포구유자아경신화증식능력,병구비향신경원、성형효질세포급소돌효질세포분화적잠능.
BACKGROUND: Periventricular leukomalacia is a major syndrome of premature infant brain injury, which has been not prevented and cured yet. Theoretically, neural stem cells which were transplanted into white matter with an absence of oligodendroglial cells might be an ideal method to cure periventricular leukomalacia. OBJECTIVE: To prepare the multi-lineage potential of neural stem cells for the use of intraventricular transplantation. METHODS: Cerebral cortex was obtained from 12-14-day fetal rats and sectioned into 1.0-mm~3 sections. The single cell suspension was separated and purified. The neurospheres were incubated with DMEM/F12 culture medium containing fetal bovine serum to observe primary and passage culture of neural stem cells. The differentiation of neural stem cells was determined using immunohistochemical method. RESULTS AND CONCLUSION: The viability of cultured neural stem cells was (94.3±2.2)%. The neurosphere was formed at day 3 after primary culture. The proliferation of neurosphere slowed down after 10-passage culture, and some cells became old. All neurospheres were positively Nestin-staining, thus they were considered as neural stem cells. A further incubation of 4-passage neurospheres, immunohistochemical method indicated that the neurosphere was positively GFAP, β-tublin, and O4 staining, respectively. This suggested that cultured neural stem cells are able to self-renew, proliferate, and differentiate into neurons, astrocytes and oligodendroglial cells.
