稀土及其配合物在生物医药上的研究进展

稀土属于化学周期表中镧系元素,具有独特生物活性,能与具有特定生理活性的配体形成稀土配合物。简要归纳了稀土配合物的种类及特点,并阐述了稀土及其配合物在细菌,真菌,癌细胞,正常细胞和病毒方面的生物效应,指出稀土及其配合物在生物医药领域方面有很大的应用前景。     

稀土离子与Ca~(2 )在生物体内的相互作用机制及应用

稀土元素在生物领域内的研究,可以分为两个方面：稀土的生物效应和稀土在其它研究中的应用．稀土元素的生物效应,主要集中在动物和医学领域．由于稀土元素的离子半径及化学性质和钙离子很相似,因此在研究稀土的生物效应时,对稀土离子与钙离子的关系颇为重视．稀土作为一种特殊的研究工具,在许多生物学研究领域中,克服了一些因其它方法的局限而不能得到的结果或简化了其中的过程．     

稀土元素铕在生物技术领域的研究进展

介绍了稀土元素铕在生物技术领域当前的研究进展情况。铕配合物应用于荧光分析较广泛,铕离子化合物及其配合物应用于细胞代谢调控方面的研究也成为近年来的热点,可以预见铕在医药及农业生产领域有广阔的应用前景。     

稀土离子与Ca2+在生物体内的相互作用机制及应用

稀土元素在生物领域内的研究,可以分为两个方面：稀土的生物效应和稀土在其它研究中的应用。稀土元素的生物效应,集中在动物和医学领域。     

稀土离子与Ca~(2 )在生物体内的相互作用机制及应用

１概述稀土元素能与许多分子形成配合物,其中许多配合物在生物学和医学上具有重要的意义。可与稀土元素形成配合物的生物大分子有蛋白质、核酸,还包括构成它们的结构单元（氨基酸、核苷酸和糖类等）。稀土对生物所具有的生物效应已有许多报道。它能参与或干扰生物体内细胞的物质代谢和生物合成的许多过程。随着科学技术的不断发展,人们对稀土的生物效应的研究也逐渐深入到分子水平。钙在许多生理过程中有决定性作用,如防止膜的损伤和泄漏,增强细胞壁的结构和连接,特别是钙和磷脂的联结,可保护膜的完整性,调节联结膜的功能。钙是细胞…     

铽(Ⅲ)离子及其复合物:从发光特性到传感应用

稀土元素也称镧系元素,因其独特的发光性质和配位性质,其发光复合物被广泛研究于生物技术领域。其中稀土铽(Ⅲ)离子复合物因具有优异的光谱特性,关于其研究呈现出快速的发展趋势。主要从其发光特性的角度出发,探讨了其发光机理,并对铽(Ⅲ)离子与不同有机化合物结合形成的发光铽配合物以及铽(Ⅲ)离子及其配合物与不同纳米材料形成的复合物进行了分类综述。此外,还详细地阐述了铽离子及其复合物在荧光探针、生物传感器、药物递送、细胞成像、癌症治疗等相关领域的应用。最后,对其今后发展趋势和潜在的研究价值进行了展望。     

稀土卟啉近红外发光配合物在生命科学领域中的应用研究进展

稀土近红外发光材料具有独特的光物理性质,如发光谱带窄、较大的Stock位移、荧光寿命长可达毫秒级等,在医学诊断和成像、免疫分析等热门领域具有重大的应用前景。但由于跃迁选择定则,稀土离子本身的吸收系数较小,需要用特定的生色团对其进行敏化,以增强其发光性能。在众多生色团中,卟啉化合物由于其激发态能级与近红外发光的稀土离子能级较为匹配,可以较好的敏化稀土离子,获得较高的近红外发光效率,因此,近年来受到了极大的关注。本文总结了近年来近红外发光卟啉稀土配合物在生命科学领域中的应用研究进展,并对其发展前景进行了展望。     

稀土元素在药用植物细胞和组织培养中的应用

介绍了稀土元素对药用植物细胞、组织的生长及次生代谢产物合成的作用,探讨了稀土的作用机理。大量的实验证明,稀土在药用植物细胞和组织培养中具有广泛的应用前景。     

稀土元素在药用植物细胞和组织培养中的应用

介绍了稀土元素对药用植物细胞、组织的生长及次生代谢产物合成的作用,探讨了稀土的作用机理.大量的实验证明,稀土在药用植物细胞和组织培养中具有广泛的应用前景.     

混合稀土及化学药物添加剂与抗生素联合应用的抗菌效果测定

采用试管液体法在测定混合稀土及2种化学药物添加剂喹乙酸、阿散酸单独抗菌活性的基础上将它们与常用抗生素金霉素、土霉素进行组合联用,测定其联用后的抗菌效果。结果表明,混合稀土、阿散酸与金霉素、土霉素联合应用后呈相加作用或无拮抗作用。喹乙酸与金霉素、土霉素联合作用后有较好的协同抗菌作用。试验结果对于畜牧业生产中将化学药物添加剂与抗生素配合使用具有一定参考价值。     

稀土元素对农田生态系统的影响研究进展

稀土矿的开采和冶炼、稀土农用等导致农田土壤稀土元素含量不断积累,对农田生态系统结构和功能稳定产生严重的影响。综述了近20年来国内外农田生态系统稀土元素的主要来源、分配和输出,土壤和植物中稀土元素的测定方法,稀土元素对农田生态系统中植物、微生物、动物以及人类健康影响的研究进展。探讨了农田生态系统稀土元素的毒性评价和稀土污染土壤的修复措施。最后提出开展稀土元素对农田生态系统影响研究还需要加强的一些问题。     

Effects of La3+ on growth,transformation, and gene expression of Escherichia coli

Rare earth elements have been emitted into the environment largely as fertilizer components. This has caused much fear about whether they would influence our environment, especially on the metabolism and genetics of microorganisms. In this article, the trivalent ion of a rare earth element, lanthanum, was studied for the effects on growth, transformation, and gene expression of Escherichia coli. The results showed that La³⁺ at concentrations from 50 to 150 μg/mL stimulated the endogenic metabolism and ectogenic metabolism, but had few effects on gene expression. La³⁺ at lower concentrations from 0.5 to 30 μg/mL inhibit intensively E. coli-absorbing external DNA, decreasing the transformation efficiency. It is also supported by observations using transmission electron microscopy. Our results are significant in understanding the function of rare earth elements to microorganisms and assessing the risk of application of rare earth compounds.     

Accumulation of rare earth elements in maize plants (Zea mays L.) after application of mixtures of rare earth elements and lanthanum

Rare earth elements are applied in China to improve crop production, and the distribution patterns of individual rare earth elements in native plants have widely been reported. But our knowledge is still limited about the dose-dependent accumulation of individual rare earth elements in agricultural crops after application of rare earth elements. Effects of lanthanum and mixtures of rare earth elements were studied in pot experiments on the accumulation of individual rare earth elements in maize plants. All plant samples were divided into plant tops and roots. On addition of mixtures of rare earth elements and lanthanum to the soil, a significant dose-dependent accumulation of individual rare earth element(s) was found in the roots and in the plant tops. Application of mixtures of rare earth elements at >10 mg kg^–1 soil, resulted in a significant increase in contents of light rare earth elements in the roots, and at a dose of 50 mg kg^–1 soil, a similar phenomenon was found in the plant tops. When mixtures of rare earth elements were replaced by lanthanum alone, at a dose higher than 10 mg La kg^–1 soil, a significant increase in La content occurred in the roots and in the plant tops. The content ratio of La to Ce in maize plants appeared to increase as the application doses of rare earth element(s) increased. At a highest dose (50 mg kg^–1soil), the transport of the absorbed La from the roots to the plant tops might be substantially reduced after treatment with lanthanum alone, compared with mixtures of rare earth elements. Increasing the application doses of rare earth element(s) appeared to cause a positive Gd and negative Ce anomaly in the roots and in the plant tops, and the anomaly was more obvious in the plant tops than in the roots. The results indicated that the Gd and Ce anomaly in corns might be considered as important parameters for the safety assessment of agricultural application of rare earth elements.     

镧在草-菇-土系统中的循环与生物富集效应

利用稀土镧肥种植牧草南非马唐,采用含镧牧草栽培杏鲍菇和以菇渣作为有机肥种植牧草进行连续性试验,研究镧在草-菇-土系统中的分配与生物富集情况。结果表明：施镧处理的南非马唐和杏鲍菇各器官的镧元素含量均高于不施镧处理,其中镧在牧草南非马唐中的分布为根>叶>茎,镧在杏鲍菇中的分布为菌盖>菌柄;外源镧进入土壤以后,南非马唐不同器官的镧元素生物富集系数均随着镧施入量的增加而增大,其中以根的镧生物富集系数最大,介于0.443—0.580之间。除高剂量（M4）处理外,叶和茎的镧生物富集系数不同处理间无显著差异,但根出现明显变化;含镧牧草栽培杏鲍菇和菇渣种植南非马唐后,不同器官的镧含量无显著增加,说明镧残留在草-菇-土系统中迁移转化效率降低。     

光转换膜在农业上的应用概述

介绍了含稀土光转换剂的光转换膜作用原理及其在农业上的应用情况,论述了目前农用光转换膜应用研究中存在的问题及发展方向。     

稀土对蚯蚓体内氨基酸含量的影响

采用滤纸接触染毒法,分别进行了氯化稀土、氯化镧与土居动物蚯蚓接触染毒不同时间和不同浓度的试验。研究其对蚯蚓体内氨基酸含量的影响变化。结果表明。Re、La对蚯蚓体内的氨基酸含量影响较显著,在低浓度时总体表现为促进蚯蚓体内氨基酸的形成,而在高浓度状态下则使蚯蚓体内氨基酸含量下降,产生抑制作用,两种稀土在400mg·L^-1浓度时,蚯蚓体内氨基酸含量除脯氨酸外开始上升,随着作用时间延长,氨基酸含量逐渐下降,在100～1200mg·L^-1浓度范围,两种稀土均引起蚯蚓体内脯氨酸含量的下降,产生抑制作用。     

Element-coded affinity tags for peptides and proteins

Isotope-coded affinity tags (ICAT) represent an important new tool for the analysis of complex mixtures of proteins in living systems [Aebersold, R., and Mann, M. (2003) Nature, 422, 198-207]. We envisage an alternative protein-labeling technique based on tagging with different element-coded metal chelates, which affords affinity chromatography, quantification, and identification of a tagged peptide from a complex mixture. As proof of concept, a synthetic peptide was modified at a cysteine side chain with either a carboxymethyl group or acetamidobenzyl-1,4,7,10-tetraazacyclododecane-N,N',N' ',N' "-tetraacetic acid (AcBD) chelates of terbium or yttrium. A mixture of the three modified peptides in a mole ratio of 100:1.0:0.83 carboxymethyl:AcBD-Tb:AcBD-Y was trypsinized, purified on a new affinity column that binds rare-earth DOTA chelates, and analyzed by LC-MS/MS. Chelate-tagged tryptic peptides eluted cleanly from the affinity column; the tagged peptides chromatographically coeluted during LC-MS analysis, were present in the expected ratio as indicated by MS ion intensity, and were sequence-identified by tandem mass spectrometry. DOTA-rare earth chelates have exceptional properties for use as affinity tags. They are highly polar and water-soluble. Many of the rare earth elements are naturally monoisotopic, providing a variety of simple choices for preparing mass tags. Further, the rare earths are heavy elements, whose mass defects give the masses of tagged peptides exact values not normally shared by molecules that contain only light elements.     

稀土多元复合肥和三种稀土元素的遗传毒性研究

采用蚕豆根尖细胞微核技术,研究市售稀土多元复合肥和稀土元素镧、铈、铒的化合物对蚕豆根尖细胞的遗传毒性和细胞毒性。结果表明,稀土复合肥和三种稀土元素均可诱发微核效应,在一定浓度下可损伤细胞,影响根尖的正常生长,其中稀土复合肥的微核效应表现出明显的剂量-效应关系。稀土复合肥和稀土元素镧、铈、铒的化合物对蚕豆根尖细胞具有一定的遗传毒性作用和细胞毒性作用,在施用稀土微肥和使用稀土制品时应引起重视。 Abstract：This paper presents the study of genetic toxicity and cell toxicity that is give n by rare earth multi-element compound fertilizer and a chemical compound of rar e earth elements-La3＋、Ce4＋、Er3＋ in root tip cells of Vicia faba.The technique used is micronucleus in root tip cells of Vicia faba.The experiment statistical result shows that both the rare earth compound fertilizer and the three kinds of rare earth elements can cause micronucleus ef fect and under certain concentration,they can hurt cells, affect root tip gro wth .The micronucleus effect of the rare earth compound fertilizer shows a clear relation of dosage-effect. The conclusion is that rare earth compound fertilize r and the chemical compound of rare earth elements La3＋、Ce4＋、E r3＋cause certain genetic toxicity and cell toxicity effect to root tip cells of Vicia faba.Therefore a close attention should be paid when the rar e earth multi-fertilizer and other things made by rare earth are used.