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光学分子影像技术及其在药物研发领域的应用 总被引:2,自引:0,他引:2
光学分子影像技术是一种发展迅速的生物医学影像技术,能够利用生物发光技术或荧光蛋白等,对生物体内特定的生物过程进行无创的定性或定量研究。应用该技术可以对药物进行筛选,选取具有潜在治疗效果的药物进行后续研究,而终止对可能无效药物的研究,同时可以评价药物对肿瘤的代谢、增殖、血管形成、凋亡和组织乏氧等方面的影响。本文主要介绍光学分子影像技术及其在药物研发,尤其是抗肿瘤药物研发领域的应用。 相似文献
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WU HongYan ZOU DingHui & GAO KunShan Marine Biology Institute Shantou University Shantou China State Key Laboratory of Marine Environmental Science Xiamen University Xiamen China 《中国科学:生命科学英文版》2008,51(12):1144-1150
Marine photosynthesis drives the oceanic biological CO2 pump to absorb CO2 from the atmosphere, which sinks more than one third of the industry-originated CO2 into the ocean. The increasing atmos-pheric CO2 and subsequent rise of pCO2 in seawater, which alters the carbonate system and related chemical reactions and results in lower pH and higher HCO3- concentration, affect photosynthetic CO2 fixation processes of phytoplanktonic and macroalgal species in direct and/or indirect ways. Although many unicellular and multicellular species can operate CO2-concentrating mechanisms (CCMs) to util-ize the large HCO3- pool in seawater, enriched CO2 up to several times the present atmospheric level has been shown to enhance photosynthesis and growth of both phytoplanktonic and macro-species that have less capacity of CCMs. Even for species that operate active CCMs and those whose photo-synthesis is not limited by CO2 in seawater, increased CO2 levels can down-regulate their CCMs and therefore enhance their growth under light-limiting conditions (at higher CO2 levels, less light energy is required to drive CCM). Altered physiological performances under high-CO2 conditions may cause genetic alteration in view of adaptation over long time scale. Marine algae may adapt to a high CO2 oceanic environment so that the evolved communities in future are likely to be genetically different from the contemporary communities. However, most of the previous studies have been carried out under indoor conditions without considering the acidifying effects on seawater by increased CO2 and other interacting environmental factors, and little has been documented so far to explain how physi-ology of marine primary producers performs in a high-CO2 and low-pH ocean. 相似文献
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将钝顶螺旋藻培养在含有不同NaCl浓度(0、0.4、0.8mol·L^-1)的培养基中,并置于室外全波段太阳辐射、阳光辐射滤除uvB以及光合有效辐射(PAR)三种辐射条件下,以探讨阳光uV辐射和盐胁迫对钝顶螺旋藻的耦合效应。结果表明,阳光uv辐射显著抑制钝顶螺旋藻的光化学效率,且随着盐浓度的提高,其受抑制程度加剧。D1蛋白含量在高水平PAR和uV辐射下都明显降低,而高盐浓度(0.8mol·L^-1NaCl)导致其含量进一步下降。此外,阳光uv辐射与盐胁迫的耦合作用使得藻丝发生明显断裂。 相似文献
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