12C6＋离子辐照人胃癌细胞系BGC823的氧效应研究

氧效应; 碳离子; 人胃癌细胞系BGC823 ;兰州重离子加速器     

面向空间高能重离子与辐射屏蔽材料的反应截面地基研究

空间辐射尤其是高能重离子辐射可造成生物机体的严重损伤, 所以对高能重离子进行恰当的辐射屏蔽, 成为实现载人航天的关键性因素之一。 研究表明, 由于高能重离子与不同屏蔽材料发生相互作用, 所产生的核碎片等次级粒子, 直接影响空间辐射屏蔽材料的屏蔽性能研究和屏蔽结构设计。 介绍了太空辐射的分类与组成, 综述了国际地基辐射屏蔽材料与实验现状。 根据文献中的地基实验数据, 重点描述了被动式屏蔽方法: 以相近能量多种重离子, 不同能量的56Fe和28Si重离子分别与C, H, Al和Cu材料相互作用的总反应截面和碎片产生截面, 并结合510 MeV/u 56Fe与不同厚度CH2相互作用产生的碎片通量分布、 碎片平均LET分布和不同厚度CH2的单位入射离子剂量减少量等方面, 系统讨论分析了C, H, Al, Cu和CH2等常用空间辐射屏蔽材料的屏蔽性能。 Cosmic radiation, particularly the high energy heavy ion radiation, may cause serious injury on living organism. Therefore, it is one of critical restriction factor in Manned Spaceflight. Studies show that high energy heavy ions interacting with the shielding materials can produce numerous kinds of fragments and secondaries. These particles have a direct impact on evaluation of shielding properties of different shielding materials, the optimal shielding structure design and low dose evaluation after shielding materials. From perspectives of divisions of cosmic rays and passive shielding methods, this paper introduces the ground based research of shielding materials. The passive shielding method was discussed, based on the experimental data of the total cross sections and fragment（production） cross sections of the aspects of different heavy ions with approximately same energy and 56Fe, 28Si heavy ions with different energies on H, C, CH2, Al and Cu radiation shielding materials. In addition, the fragment fluency distribution, the average LET distribution and the dose reduction per particle of 510 MeV/u 56Fe in different depth of CH2 material were also discussed.     

辐射诱发体内旁效应特征的研究进展

大量的细胞生物学研究显示, 辐射诱发旁效应的传输信号包括活性氧自由基（ROS）、 一氧化氮自由基（NO）以及一些细胞因子。 近年来,越来越多的文献报道关于体内旁效应特征的研究, 并已经证实在生物体内辐射诱导的旁效应不仅能发生在相邻组织, 还可发生在远源器官。这些体内旁效应包括DNA损伤、表观遗传学改变、miRNA及基因表达改变、 细胞增殖和凋亡等。 为了总结和分析辐射诱发体内旁效应的特征, 本文综述了辐射诱发体内旁效应的特点, 包括其与性别、 传播途径、辐射品质的关系以及相关机制的研究。 Radiation induced bystander effect is defined as the induction of damage in neighboring non hit cells by signals released from directly irradiated cells. ROS, NO and cytokines are involved in signaling pathways of bystander effects. Recently, the bystander effects in vivo have been reported more and more. It has been indicated that radiation induced bystander effect was localized not only in bystander tissues but also in distant organs. This effect includes many biological endpoints such as DNA damage, epigenetic, miRNA and gene expression changes, cell proliferation and apoptosis. In this review we described different aspects of ionizing radiation induced bystander effects such as its characteristics, sex specific, signaling transfer, dose and LET dependence, and related mechanisms.     

酵母β-葡聚糖对C离子辐射损伤小鼠免疫系统的防护作用

用12C6+离子束对小鼠进行一次性全身辐照, 检测不同剂量的酵母β-葡聚糖对12C6+辐射损伤小鼠免疫系统的防护作用。 辐照后观察小鼠的体重、 毛色及行为变化, 照后第2天和第7天检测小鼠外周血中白细胞含量, 照后第8天检测小鼠胸腺和脾脏内SOD, GSH PX活性和MDA含量。 实验结果表明, 给予酵母β 葡聚糖能减缓辐照引起的小鼠体重急剧下降, 增加小鼠外周血中白细胞含量,不同程度地恢复胸腺和脾脏SOD和GSH PX活性, 降低胸腺和脾脏MDA含量。 表明酵母β-葡聚糖对12C6+引起的小鼠辐射损伤具有防护作用。 To detect Yeast β-glucan’s protective effect on mice’s immune system after C ion beam radiation, mice were used as the test model. We observed the weight, hair color and behavior of mice everyday within a 7 d period of time after irradiation. Meanwhile, the content of white blood cell, on the 2nd and 7th day after irradiation was detected. We detected the thymus and spleen SOD, GSH PX activity and MDA content of the mice on the 8th day. The results showed that yeast β glucan could reduce the rapid weight loss of mice, increase white blood cell content, increase thymus and spleen SOD, GSH PX activity, decrease MDA content of thymus and spleen. These results indicate that yeast β glucan can protect mice’s immune system against C ion beam radiation damage.     

空间辐射生物学研究进展

空间电离辐射尤其是高能带电粒子辐射可造成生物机体的严重损伤, 是载人航天飞行的关键性限制因素之一。 研究表明, 带电粒子的生物学效应与其性质、 剂量以及不同生物学终点有关; 此外, 微重力环境可能会影响空间辐射生物学效应。 从多年来的空间搭载实验研究和地基模拟实验研究两个方面, 综述了空间辐射的生物损伤效应及其与微重力环境复合作用的生物效应。Space radiation, particularly induced by the high energy charged particles, may cause serious injury on living organisms. So it is one critical restriction factor in Manned Spaceflight. Studies have shown that the biological effects of charged particles were associated with their quality, the dose and the different biological end points. In addition, the microgravity conditions may affect the biological effects of space radiation. In this paper we give a review on the biological damage effects of space radiation and the combined biological effects of the space radiation coupled with the microgravity from the results of space flight and ground simulation experiments.     

不同LET射线对细胞的生物学效应

以人肝癌细胞系和正常肝细胞系为材料,报道了不同传能线密度射线辐射引发细胞染色体原初断裂及24 h内的修复情况。 计算了相对生物学效应的值。 以L02染色体总断裂数量得出的RBE值96.05 keV/μm的12C6+ 为3.6, 512 keV/μm 36Ar18+ 为2.9。 而以7721染色体总断裂数量得出的RBE值: 96.05 keV/μm的12C6+ 为3.5,512keV/μm 36Ar18+也为2.9。用产生等点染色单体断裂计算,则RBE更高。对比得出,高LET对增加等点染色单体断裂量的作用要远远大于对增加染色单体断裂量的作用。等点染色单体的断裂修复难度要远远大于染色单体断裂的修复难度, 这也是高LET高致死率的一个重要原因。 Human hepatoma SMMC 7721 and normal liver L02 cells were irradiated with γ rays,12C6+ and 36Ar18+ ion beams at the Heavy Ion Research Facility in Lanzhou(HIRFL). We reported the kinetic repair of chromosome breaks of L02 and SMMC 7721 cells in 24 h of post irradiation time. The relative biological effectiveness(RBE) for inducing chromatid breaks were 3.6 for L02 and 3.5 for SMMC 7721 cell lines at the linear energy transfer(LET) peak of 96.55 keV/μm 12C6+ ions, and 2.9 (both of the two cell lines) at 512 keV/μm 36Ar18+ ions.It suggested that the RBE of isochromatid type breaks induced by 36Ar18+ was higher than those by 12C6+. We concluded that the high production of isochromatid type breaks, induced by the densely ionizing track structure, could be regarded as a signature of high LET radiation exposure.     

模拟微重力效应对辐射致细胞DNA损伤修复效应的影响

在地面模拟微重力的情况下, 应用碱性单细胞凝胶电泳（SCGE）技术对80 MeV/u Ne离子辐射诱发人血淋巴细胞DNA损伤修复效应进行了研究。 在不同时刻对相同剂量辐照后的淋巴细胞经单细胞电泳处理后显示, 在模拟微重力下孵育的彗星尾更长, 彗星头面积更小。 这表明, 相对地面环境而言, 模拟微重力环境对淋巴细胞的DNA损伤修复有一定的抑制作用。 Effect of the modeled microgravity (MMG) on heavy ion induced lymphocytes DNA repair by using single cell gel electrophoresis (SCGE) has been studied. The results showed that residual DNA damage induced by Ne ions irradiation increased more in cultures incubated in MMG than in 1 g, which indicated that MMG incubation after Ne ions irradiation reduce the DNA damage repair capacity.