温度对铽（III）-转铁蛋白溶液构象的影响

在pH 7.4，0.01 mol/L N-2-羟乙基哌嗪-N’-2-乙磺酸（Hepes）条件下，铽 （III）与N，N’-二（2-羟苄基）乙二胺-N，N’-二乙酸（HBED）结合并发生交换 相互作用使铽（III）荧光增强10~4倍，通过监测铽（III）545 nm荧光强度的变化 测定了Tb-HBED配合物的条件稳定常数是lgK = 14.30 ± 0.49；Tb-HBED配合物中 配体、铽（III）荧光强度均随着温度的升高而降低。在pH 7.4，0.01 mol/L Hepes条件下，Tb_N-apoTf-Tb_C配合物中蛋白质的荧光强度随着温度的升高而降 低，而能量受体铽（III）的荧光强度随着温度的升高而增强，主要源于铽（III） 与螺旋5色氨酸残基间的无辐射能量转移；当温度由0 ℃上升到55 ℃时，平均能量 转移效率AE值增加了29%，给体、受体间距离R有约4.2%的减小，温度变化引起 Tb_N-apoTf-Tb_C配合物大的构象变化；铽（III）与人血清脱铁转铁蛋白的结合使 蛋白质的变性温度降低。同样条件下，Tb_N-apoOTf-Tb_C配合物与Tb_N-apoTf- Tb_C配合物有所不同，虽然能量给体的荧光强度随着温度的增加而减小，但铽（ III）荧光强度没有明显的增强；铽（III）对蛋白质的变性温度几乎没有影响。     

温度对铽(Ⅲ)-转铁蛋白溶液构象的影响

在pH 7.4,0.01 mol/L N-2-羟乙基哌嗪-N′-2-乙磺酸(Hepes)条件下,铽(Ⅲ)与N,N′-二(2-羟苄基)乙二胺-N,N′-二乙酸(HBED)结合并发生交换相互作用使铽(Ⅲ)荧光增强104倍,通过监测铽(Ⅲ)545 nm荧光强度的变化测定了Tb-HBED配合物的条件稳定常数是lgK=14.30±0.49;Tb-HBED配合物中配体、铽(Ⅲ)荧光强度均随着温度的升高而降低.在pH 7.4,0.01 mol/L Hepes条件下,TbN-apoTf-Tbc配合物中蛋白质的荧光强度随着温度的升高而降低,而能量受体铽(Ⅲ)的荧光强度随着温度的升高而增强,主要源于铽(Ⅲ)与螺旋5色氨酸残基间的无辐射能量转移;当温度由0℃上升到55℃时,平均能量转移效率AE值增加了29%,给体、受体间距离R有约4.2%的减小,温度变化引起TbN-apoTf-Tbc配合物大的构象变化;铽(Ⅲ)与人血清脱铁转铁蛋白的结合使蛋白质的变性温度降低.同样条件下,TbN-apoOTf-Tbc配合物与TbN-apoTf-Tbc配合物有所不同,虽然能量给体的荧光强度随着温度的增加而减小,但铽(Ⅲ)荧光强度没有明显的增强;铽(Ⅲ)对蛋白质的变性温度几乎没有影响.     

酒石酸脱除单铽转铁蛋白中铽（III）的荧光动力学研究

0.01 mol/L Hepes, pH7.4，室温条件下，以酒石酸为脱除剂，监测铽（III） 与脱铁蛋白结合的两种配合物C端单铽转铁蛋白和N端单铽转铁蛋白随酒石酸浓度变 化的脱除动力学，根据其动力学行为，我们推测存在两种平行的脱除途径：一次途 径和饱和途径，其中C端单铽转铁蛋白的铽（III）脱除呈现饱和与一次相结合途径 ，N端单铽转铁蛋白为简单的一次途径。NaCl的加入可促进两种单铽（III）的脱除 ，且C端铽转铁蛋白较N端单铽转铁蛋白更易受NaCl的影响。     

酒石酸脱除单铽转铁蛋白中铽（III）的荧光动力学研究

0.01 mol/L Hepes, pH7.4,室温条件下,以酒石酸为脱除剂,监测铽（III） 与脱铁蛋白结合的两种配合物C端单铽转铁蛋白和N端单铽转铁蛋白随酒石酸浓度变 化的脱除动力学,根据其动力学行为,我们推测存在两种平行的脱除途径：一次途 径和饱和途径,其中C端单铽转铁蛋白的铽（III）脱除呈现饱和与一次相结合途径 ,N端单铽转铁蛋白为简单的一次途径。NaCl的加入可促进两种单铽（III）的脱除 ,且C端铽转铁蛋白较N端单铽转铁蛋白更易受NaCl的影响。     

Yb(Ⅲ)、Gd(Ⅲ)与EHPG配合物的光谱研究

在0.01mol·L^-1 N-2-羟乙基哌嗪-N′-2-乙磺酸(Hepes),pH 7.4和室温条件下,应用荧光光谱和紫外差光谱研究了Yb(Ⅲ),Gd(Ⅲ)与N-N′-乙烯-二[2-(2-羟基苯基)甘氨酸](EHPG)的配合反应。结果表明,随着稀土离子Yb(Ⅲ)或Gd(Ⅲ)的不断滴加,EHPG在310nm处的最大荧光峰强度逐渐降低,而其紫外差光谱在238和292nm处的吸收峰逐渐增强,当稀土离子Yb(Ⅲ)或Gd(Ⅲ)达到一定量时,310nm处的荧光强度、238和292nm处的吸收峰强     

铽配合物Tb(2-MBA)_3·2H_2O和Tb(2-MBA)_3 phen的荧光性能研究

以2-甲基苯甲酸(2-MBA)为第一配体、1,10-邻菲罗啉(phen)为第二配体,制备了三元铽配合物Tb(2-MBA)3phen和二元铽配合物Tb(2-MBA)3·2H2O,并利用元素分析、红外光谱、紫外光谱、荧光光谱和荧光寿命对二者的结构与性能进行分析表征。研究结果表明:三元铽配合物Tb(2-MBA)3phen的荧光发射强度要强于二元铽配合物Tb(2-MBA)3·2H2O,而二者的荧光寿命恰好相反,三元铽配合物Tb(2-MBA)3phen的荧光寿命短于二元铽配合物Tb(2-MBA)3·2H2O。热重分析表明Tb(2-MBA)3·2H2O的热分解温度要远高于Tb(2-MBA)3phen。     

含N,N-二(2-苯并咪唑甲基)亚胺单核镍(Ⅱ)配合物与DNA相互作用的研究

用荧光光谱法和紫外-可见吸收光谱法研究了含N,N-二(2-苯并咪唑甲基)亚胺单核镍(Ⅱ)配合物与小牛胸腺DNA(ct-DNA)作用的机理。结果表明,随着ct-DNA浓度的增加,配合物表现较强的荧光增强作用,且在不同的温度下荧光增强常数Ks随温度的升高而降低,表明配合物与ct-DNA的作用机理是静态增强过程。根据双对数方程计算出了不同温度下的结合常数K和结合位点数n。稳态荧光猝灭及溴化乙锭(EB)竞争取代实验研究表明配合物与ct-DNA可能以嵌插方式结合。吸收光谱表明配合物增加了DNA双螺旋结构的稳定性。     

双核双配体稀土配合物Tb1-xEux(TTA)3Phen的合成及光学性能研究

合成了系列铕铽双核稀土有机稀土配合物Tb1-xEux（TTA）3Phen，通过差热．热重分析、XRD、红外光谱、紫外光谱和荧光光谱等测试手段研究了配合物的组成、结构和发光性质。由紫外可见光谱可以看出，稀土有机配合物的吸收峰主要来自有机配体HTrA和1，10-Phen；差热-热重分析证明，稀土有机配合物热稳定性较好。荧光光谱和电致发光表明，铽对铕配合物的发光有协同作用。在该系列配合物中，不仅有机配体可以将吸收的能量传递给发光的铕离子使其发光，而且铽离子也可将其吸收的能量通过分子内能量传递给铕离子，增强铕的发光强度。同时就双核稀土有机配合物光致发光和电致发光的特性及掺杂体系的能量传递过程进行了讨论。     

Eu~(3+)和Tb~(3+)冠醚配合物的合成、荧光性质及与DNA作用研究

合成了含联萘骨架的酰胺型开链冠醚配体及稀土苦味酸盐配合物RE(pic)3L[L=N,N-乙基,苯基-N’,N’-二苯基-1,1’-联萘-2,2’-二(氧杂乙酰胺),RE=Eu3+,Tb3+],通过元素分析、IR、TG-DTA和摩尔电导率对配合物进行组成和结构推测。荧光光谱表明:Eu3+配合物的荧光强度远大于Tb3+配合物,说明配体L的三重态能级与Eu3+的激发态能级匹配较好。通过光谱法和粘度法研究了配合物与DNA的作用方式为插入作用,求出了Eu3+,Tb3+配合物与DNA的结合常数分别为4.072×104L.mol-1,8.780×103L.mol-1,证明配合物与DNA的作用大小是Eu3+(pic)3LTb3+(pic)3L.     

芳香酰胺型开环冠醚稀土配合物及其荧光性质研究

合成了新的以水杨酰苄胺为功能端基的开环冠醚1,7-二(2'-苯甲酰苄胺)-1,4,7-三氧杂庚烷(L)有机配体及其硝酸铕和硝酸铽的配合物.利用元素分析、电导、红外光谱对配合物进行了表征,结果表明两个配合物均符合23(RE(NO3)3L)的化学计量比.此外还初步研究了铕、铽配合物在室温下的固体荧光性质,结果表明虽然配体保持了苯羰基共轭结构对铕、铽离子的敏化发光性质,两个配合物均能表现出一定强度的特征荧光,但是配体向Tb(Ⅲ)的能量传输效率明显要强于Eu(Ⅲ).     

Sensitization of lanthanides by nonnatural amino acids

The sensitization of Eu(III) and Tb(III) by ethylenediaminetetraaceticacid (EDTA)-derivatized tryptophan (Trp), 7-azatryptophan (7AW) and 5-hydroxytryptophan (5HW) has been examined. These Trp analogs were utilized in the present study because they can be incorporated into proteins in place of native Trp residues and because they absorb strongly beyond 305 nm (where Trp absorbance goes to zero), allowing selective excitation of such species in the presence of other Trp-containing proteins. All three indole derivatives were able to sensitize Tb(III) luminescence, with the relative sensitization being in the order Trp > 5HW > 7AW. On the other hand, only the 7AW-EDTA complex was able to sensitize Eu(III) luminescence, likely owing to a better spectral overlap between 7AW emission and Eu(III) absorbance. The sensitized emission of Tb(III) and Eu(II) displayed the expected long emission lifetimes at 545 nm [for Tb(III)] and 617 nm [for Eu(III)], indicating that long-lifetime lanthanide emission could be produced using nonnatural amino-acid donors. Thus, 7AW- and 5HW-sensitized lanthanide emissions should prove to be useful in biophysical studies, such as the use of fluorescence energy transfer to probe biomolecular interactions in vivo.     

Study on interaction between Tb(III) and poly(N-isopropylacrylamide)-g-poly(N-isopropylacrylamide-co-styrene) core-shell nanoparticles

Based on the synthesis of poly(N-isopropylacrylamide-co-styrene) P(NIPAM-co-St) and poly(N-isopropylacrylamide) (PNIPAM) grafted P(NIPAM-co-St) core-shell nanoparticle, a new kind of thermoresponsive and fluorescent complex of Tb(III) and PNIPAM-g-P(NIPAM-co-St) (PNNS) was successfully prepared. The PNNS-Tb(III) complex was characterized with the different techniques. It was found that when PNNS with the core-shell structure interact with Tb(III), Tb(III) mainly bonded to O of the carbonyl groups of PNNS, forming the novel PNNS-Tb(III) complex. After forming the complex, the emission fluorescence intensity of Tb(III) in the complex is significantly enhanced. Especially, the maximum emission intensity of the PNNS-Tb(III) complex at 545 nm is enhanced about 223 times comparing to that of the pure Tb(III) because the effective intramolecular energy transfer from PNNS to Tb(III). The intramolecular energy transfer efficiency from PNNS to Tb(III) reaches 50%. The fluorescence intensity is related the weight ratio of Tb(III) and PNNS in the PNNS-Tb(III) complex. When the weight ratio of Tb(III) and the PNNS is 12 wt%, the enhancement of the emission fluorescence intensity at 545 nm is highest. This novel fluorescence characterization of the PNNS-Tb(III) complex may be useful in the fluorescence systems and the biomedical field.     

Binding Constants for Terbium(Ⅲ) with Chicken Apoovotransferrin

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GdAlO_3∶Tb,RE中Tb,RE的能量传递研究

采用柠檬酸盐硝酸盐燃烧法制备了GdAlO3∶Tb,RE荧光粉体.在紫外激发下(254nm),GdAlO3∶Tb发射绿色荧光(5D4→7F5,544nm),Dy共掺杂对绿色发光有增强作用,Ce共掺杂对GdAlO3∶Tb绿色发光有降低作用.激发谱和能谱研究表明:Dy能级嵌入Tb主发射能级5D4(绿色发光能级)、5D3(蓝色发光能级)能级之间,Ce能级嵌入Tb主发射能级5D4、5D3能级上方.这种能级嵌入方式,使得稀土离子之间存在声子支持的共振能量传递,但Tb→Dy→Tb能量传递使Tb绿色发射(5D4→7FJ(J=3,4,5,6))增强,蓝色发射(5D3→7FJ(J=3,4,5,6))减弱;而Ce→Tb能量传递使Tb蓝色发射增强,绿色发射减弱.     

Tb(III)与PNIPAM接枝核壳纳米微球相互作用的研究

利用透射电镜、X射线光电子能谱、动态激光光散射和荧光光谱技术对Tb(III)与聚N-异丙基丙烯酰胺(PNIPAM)接枝核壳纳米微球PNIPAM-g-P(NIPAM-co-St) (PNNS)的相互作用进行了研究. 结果表明: Tb(III)和热敏性的核壳纳米微球PNNS有显著的相互作用. 其一, Tb(III)可与PNNS中酰胺基团上的氧原子配位形成微球配合物Tb(III)-PNNS; 其二, Tb(III)-PNNS微球配合物兼具热敏性; 其三, 该配合物在545 nm处的荧光强度较Tb(III)增大了233倍, Tb(III)与PNNS分子间能量传递达到50%, 当Tb(III) 质量分数为12%时荧光强度最大.     

紫外激发Sr1-x-yMgP2O7:xCe3+,yTb3+荧光粉的发光特性及能量传递

采用高温固相法合成了Sr1-x-yMgP2O7:xCe3+,yTb3+荧光粉.研究了荧光粉的晶体结构、发光特性、荧光寿命、能量传递机理和荧光粉的热稳定性.研究结果表明:在SrMgP2O7基质中,Ce3+的发射峰值为398nm,Tb3+的主发射峰值为545nm,它们分别属于5d-4f跃迁和5D4→7F5跃迁.Ce3+和Tb3+共掺时,Ce3+和Tb3+通过电偶极子-电偶极子相互作用发生能量传递,能量传递的临界距离为0.614nm.通过计算得到单掺杂Ce3+、Tb3+时热猝灭过程的激活能分别为0.122和0.111eV,Tb3+离子的发光热稳定性比Ce3+离子的好.     

Study on interaction between Tb(III) and poly(N-isopropylacrylamide)

A new kind of the thermo-sensitive and fluorescent complex of poly(N-isopropylacrylamide) (PNIPAM) and Tb(III) was synthesized by free radical polymerization, in which PNIPAM was used as a polymer ligand. The complex was characterized by using X-ray photoelectron spectroscopy (XPS), ultraviolet-visual (UV), Fourier transform infrared (FT-IR) and fluorescence spectroscopy. The results from the experiments indicated that there is a strong interaction between PNIPAM and Tb(III), leading to a decrease in the electron density of nitrogen and oxygen atoms and an increase in the electron density of Tb(III) in the PNIPAM containing Tb(III) by contrast with PNIPAM and Tb(III), respectively, meanwhile, exhibiting that the Tb(III) is mainly bonded to oxygen atoms in the polymer chain of PNIPAM and formed the complex of PNIPAM-Tb(III). After forming the PNIPAM-Tb(III) complex, the emission fluorescence intensity of Tb(III) in the PNIPAM-Tb(III) complex is significantly enhanced because the effective intramolecular energy transfer from PNIPAM to Tb(III). Especially, the emission intensity of the fluorescence peak at 547 nm can be increased as high as 145 times comparing with that of the pure Tb(III). The intramolecular energy transfer efficiency for fluorescence peak at 547 nm can reach as high as 68%. The fluorescence intensity is related the weight ratio of Tb(III) and PNIPAM in the PNIPAM-Tb(III) complex. When the weight ratio is 1.4%, the maximum fluorescence enhancement can be obtained. Nevertheless, the lower critical solution temperature of PNIPAM containing a low content of Tb(III) has not obviously changed after the formation of the complex of PNIPAM-Tb(III) by the interaction between PNIPAM and Tb(III). This novel thermosensitive and fluorescence characterization of the PNIPAM-Tb(III) complex may be useful in the fluorescence systems and the biomedical field.     

Cooperative energy transfer frequency upconversion in Tb3+/Yb3+-codoped oxyfluoride glasses

In this report, we investigate the cooperative energy transfer frequency upconversion in Tb3+/Yb3+-codoped SiO2-Al(2)O(3)-Na2O-ZnF(2) oxyfluoride glasses under 980 nm diode laser excitation. The influence of both Tb3+ and Yb3+ concentration on the emission bands were investigated. With a lower Tb3+ concentration, the emission bands around 381, 416 and 438 nm, and 489, 545, 587 and 623 nm associated with (5)D(3), (5)G(6)-->(7)F(J) (J=6, 5, 4) and (5)D(4)-->(7)F(J) (J=6, 5, 4, 3) transitions were observed. However, only (5)D(4)-->(7)F(J) (J=6, 5, 4, 3) transitions appear in a higher Tb3+ concentration. The integrated upconversion luminescence intensity was examined when the temperature of sample was varied from 40 to 450 K. The dependence of the upconversion emission intensity upon the excitation power was also examined, and the upconversion mechanisms were discussed.     

Aromatic polyaminocarboxylate ligands for energy transfer luminescence measurements of lanthanide ions in aqueous solutions

The promising ligand candidates for the energy transfer luminescence measurements of lanthanide (Ln) chelates on aqueous matrices are first proposed. The ligands are; 2[(2-amino-5-methyl-phenoxy)methyl]-6-methoxy-8-aminoquinoline-N,N,N',N'-tetraacetate (Quin 2), 1,2-bis(2-amino-phenoxy)ethane-N,N,N',N'-tetraacetate (BAPTA), and 1,2-bis(2-amino-5-fluoro-phenoxy)ethane-N,N,N',N'-tetraacetate (F-BAPTA). The Ln-chelates of these aromatic polyaminocarboxylates show the sensitized emission which results from efficient ligand-centered light absorption, and the interesting selectivity is seen; BAPTA and F-BAPTA form the luminescent chelates only with Tb(III) and Dy(III) ions, whereas the emission from Sm(III) and Eu(III) ions is greatly sensitized with Quin 2. The sufficient emission intensity can be obtained even in slightly alkaline aqueous solutions without any addition of surfactants or organic solvents. These octadentate ligands are fairly capable of shielding central Ln ions from quenching by surrounding water molecules. The luminescence enhancement factors are 1600 for Tb(III) ion with BAPTA (em.544 nm) and 1380 for Eu(III) ion with Quin 2 (em. 615 nm), respectively, being relative to their aqueous chloride solutions.     

A study on silver nanoparticles-sensitized fluorescence and second-order scattering of the complexes of Tb(III) with ciprofloxacin and its applications

Fluorescence of terbium(III) is sensitized when excited in the presence of ciprofloxacin (CPLX) in the aqueous solution because a Tb(III)-CPLX complex is formed and the maximum fluorescence peak locates at 545 nm. The second-order scattering (SOS) peak at 545 nm also appears for the Tb(III)-CPLX complexes with the excitation wavelength of 272 nm. The intensity at 545 nm obviously increases when the silver nanoparticles are added to the Tb(III)-CPLX system, and the relative intensity is proportional to the concentration of CPLX. Based on this phenomenon, a new method for the determination of CPLX has been developed by using a common spectrofluorometer to measure the intensity of fluorescence and SOS. The intensity is enhanced most by silver nanoparticles at pH 6.0. The calibration graph for CPLX is linear in the range of 3.0 x 10(-9) to 1.0 x 10(-5) mol l(-1). The detection limit is 8.5 x 10(-10) mol l(-1). The method was applied satisfactorily to the determination of CPLX in tablets and capsules. The results show that silver nanoparticles with certain size and concentration can enhance the fluorescence and SOS intensity of the system.