基于寡核苷酸链的汞离子荧光生物传感器

基于G-四链体结构和卟啉类化合物N-甲基卟啉二丙酸IX(NMM)结合产生强烈的荧光,利用T-Hg(Ⅱ)-T错配对汞离子(Hg2+)的特异性识别,建立了一种简单、灵敏、高效的Hg2+检测新方法.在富含鸟嘌呤(G)寡核苷酸链中,引入了大量胸腺嘧啶(T).在没有Hg2+存在时,可以自发形成G-四链体结构,与NMM结合产生强烈的荧光;在Hg2+存在时,可与另一条富含T序列的互补链通过T-Hg(Ⅱ)-T特异性结合,形成双链DNA分子,从而导致G-四链体结构不能产生.优化后最佳实验条件为:缓冲溶液的pH=6.7,20 mmol/LKCl,2.5 μmol/L NMM,反应时间为2h.在优化条件下,体系的荧光强度变化值与Hg2+浓度呈现良好的线性关系,线性范围为50～ 1000 nmol/L,检出限为22.8 nmol/L(30).此生物荧光传感器对Hg2+具有良好的选择性.实际水样中Hg2+的加标回收率为106.1％ ～ 107.8％,可以满足实际水样品中Hg2+的检测要求.     

基于单链核酸-纳米金-汞模拟酶的汞离子检测方法研究

将汞离子(Hg2+)沉积到吸附单链核酸(ssDNA)的纳米金(AuNPs)表面后,可以提高纳米金的模拟过氧化物酶活性,基于此原理可实现Hg2+的高灵敏检测。研究发现ss DNA能够促进Au NPs-Hg2+的类似过氧化物酶活性,且随着ss DNA浓度的增加,该作用呈增强趋势。在优化反应条件下,将ss DNA-Au NPs-Hg2+模拟过氧化物酶用于Hg2+的检测,Hg2+的检测线性范围为10~1 000 nmol/L,检出限可达3.0 nmol/L。该检测方法具有简便快速、成本低、稳定性高等优点,有望用于环境、食品等样品中Hg2+的检测。     

聚胸腺嘧啶单链DNA-CuNCs荧光增强法用于汞离子的高灵敏检测

基于Hg~(2+)与DNA中胸腺嘧啶(T)结合的高度特异性和DNA铜纳米簇的荧光增强性质,构建了一种简便、灵敏检测汞离子的新方法.当Hg~(2+)存在时,聚T单链DNA(P1)通过T-Hg~(2+)-T特异性结合形成双链DNA,Cu~(2+)经抗坏血酸钠还原后生成的中间体Cu+与双链DNA螺旋结构间的氢键部分有强的结合力,促使Cu0附着聚集在双链DNA上形成铜纳米簇,导致体系荧光增强,从而实现对汞离子的高灵敏检测.体系荧光强度与Hg~(2+)浓度的对数值成正比,对Hg~(2+)检测的线性范围为1.0 nmol/L~10μmol/L,检出限达0.4 nmol/L,对湖水样品中Hg~(2+)检测的回收率达到97.2%~106.6%.与传统方法相比,该方法具有无需标记、检出限低及选择性好等优点,可用于环境水体中汞离子的测定.     

基于纳米金Core-satellites等离子体耦合增强效应的汞离子光纤传感器的研究

以DNA杂交双链为联接, 构建纳米金颗粒Core-satellites结构并激发等离子体耦合增强效应,利用Hg2+可与DNA中胸腺嘧啶T形成T-Hg2+-T特异性结构,研制了用于检测水中Hg2+的局域等离子体共振(LSPR)光纤传感器.待测溶液中的Hg2+能够引起富含T的DNA单链折叠,抑制DNA杂交反应,降低等离子体耦合强度,改变LSPR谐振波长.通过检测谐振波长红移变化,实现对Hg2+浓度的定量检测.本方法检测Hg2+的线性范围为5~150 nmol/L, 检出限为3.4 nmol/L (3σ). Zn2+、Mg2+、Pb2+等重金属离子对Hg2+检测无明显干扰作用.实际水样中Hg2+加样回收率为94.2%~105.4%,相对标准偏差<4.8%.     

基于金纳米粒子的动态光散射法检测溶液中的汞离子

发展了种基于汞离子(Hg2+)适配体(Aptamer)免标记金纳米粒子的动态光散射(DLS)法,用于灵敏、选择性的检测溶液中的Hg2+。Aptamer 5’-TTTCTTCTTTCTTCCCCCCTTGTTTGTTGTTT-3’与Hg2+的特异性结合使金纳米粒子失去保护,在含有100 mmol/L NaCl的缓冲溶液中发生聚集,金纳米粒子的平均水合粒径变大。在pH=7.43,110 nmol/L Aptamer,100 mmol/L NaCl,Hg2+与Probe DNA孵育时间为30 min的实验条件下,金纳米粒子水合粒径的变化值("D)与Hg2+的浓度成正比。检出Hg2+的线性范围为0.1 nmol/L~5μmol/L,检出限达0.1 nmol/L。湖水及矿泉水两种水样加标实验表明本方法能够用于实际水样中Hg2+的检测。     

基于G-四联体的纳米探针比色检测铅离子

基于纳米探针和G-四联体建立了简便快速检测铅离子的方法. 纳米探针采用金纳米粒子自组装修饰富G寡核苷酸制得, 在铅离子存在下, 纳米探针上的富G寡核苷酸形成G-四联体, 导致纳米探针凝聚变色. 在优化条件下, 比色检测铅离子的线性范围为48~480 nmol/L, 检出限为20 nmol/L; 大多数金属离子无明显干扰, 而有明显干扰的汞离子可采用与之特异结合的寡核苷酸有效消除. 将该法成功用于环境水样中铅离子的检测, 重现性(RSD<3.0%)与回收率(98.4%~101.5%)良好.     

基于银/铂纳米模拟酶表面修饰的铜离子比色检测方法研究

通过对银/铂纳米簇(Ag/Pt NCs)的表面修饰调控其催化活性,建立了一种高灵敏的比色法检测Cu2+.巯基丙酸能够抑制Ag/Pt NCs的催化活性,而巯基丙酸与Cu2+作用后,将导致上述抑制作用减弱.基于上述原理,通过测量Ag/Pt NCs 催化TMB-H2O2反应产生的显色信号,可以实现Cu2+的比色检测.本方法检测Cu2+的线性范围为10～100 nmol/L,检出限(3σ)为5.0 nmol/L.将本方法应用于实际水样中Cu2+的检测,结果表明,本方法具有操作简单、成本低、灵敏度高、特异性好等优点.     

水溶性汞离子(Ⅱ)荧光离子液体探针1-丁基-2-苯基硫脲吡啶溴化盐的合成及分析应用

设计、合成了1-丁基-2-苯基硫脲吡啶溴化盐（[C4ptpyr]Br）新型的水溶性Hg2+荧光探针,将其用于环境水样中Hg2+的检测。 结果表明,[C4ptpyr]Br对Hg2+识别专一性好,共存离子及pH值对测定影响小。 在pH=7的BR缓冲溶液中,检测线性范围为0.02～4 mg/L(r2=0.999 1),检出限为0.011 mg/L,回收率为95.2%～102.2%, RSD＜5%。 方法具有灵敏度和准确度高、分析速度快、操作简便等特点,可满足各类水中微量汞的测定要求。     

可视化辅助碳点荧光比色法检测水中痕量汞离子

利用巯基功能化碳点(M-CDs)构建用于检测水中Hg^2+的荧光探针。红外光谱证实M-CDs被巯基(-SH)成功修饰,透射电镜显示M-CDs的平均粒径约为4.88 nm。XRD晶型表征显示M-CDs具有类石墨烯结构。由于银硫醇盐的团聚作用,M-CDs溶液中加入Ag^+可快速形成M-CDs/Ag的棕色沉淀,并引起M-CDs的荧光猝灭。用PBS缓冲液(0.01 mol/L,pH 7.4)溶解沉淀物而形成检测Hg^2+的荧光传感器。在传感体系中加入Hg^2+后,M-CDs荧光明显恢复。在Hg^2+浓度为0.01~0.55 nmol/L范围内,检测体系荧光恢复强度与Hg^2+浓度成良好线性关系,检测限(LOD,3σ/k)4.2 pmol/L。该探针对Hg^2+表现出良好的选择性,同时可以通过可视化辅助判断探针的选择性。该传感器可用于对实际水样的检测,为Hg^2+污染监测提供技术依据。     

聚胸腺嘧啶单链DNA-铜纳米簇新型荧光探针检测水中硫离子

本文建立了一种快速灵敏检测水中硫离子的新方法。该方法利用聚胸腺嘧啶单链DNA保护的铜纳米簇为荧光探针。以聚胸腺嘧啶单链DNA为模板制备了具有荧光性质的铜纳米簇,当加入S2-后,铜纳米簇荧光显著猝灭。铜纳米簇荧光猝灭量与S2-浓度在0.125~8μmol/L范围内有良好的线性,检测限为22nmol/L。该方法对S2-有较好的选择性,实际样品检测结果显示回收率良好,说明该方法可以用于实际水样中S2-的检测。由于聚胸腺嘧啶单链DNA为模板制备的铜纳米簇制备过程简单快速,可在5min内完成,使得检测时间大大缩短。     

A novel fluorometric detection of Cu(2+) based on self-assembled bilayers

Fluorescent reagent sodium 1-naphthylamine diacetate (NADA) was assembled onto gold electrodes via its electrostatic interaction with cysteine (Cys) that was directly assembled on the gold electrode surface. Formation of the self-assembled bilayers was confirmed and primarily characterized by cyclic voltammetry and X-ray photoelectron spectra (XPS). The Cys modification of the gold electrode prevented direct adsorption of NADA onto the gold electrode and hence eliminated fluorescence quenching by gold. Strong fluorescence was observed from the NADA self-assembled bilayers at gold surface and was highly efficiently quenched by Cu²⁺ that allowed for an extremely highly sensitive detection of Cu²⁺ with a detection limit of 0.2 ppt and quantitative detection range of 0.5–9 ppt. The fluorescence from NADA/Cys/Au can be easily regenerated and therefore the present report showed a reusable method for immobilizing reagent in fabricating fluorescent chemosensors.     

O-羧甲基壳聚糖纳米微粒制备及对Ni~(2+)吸附研究

将壳聚糖与氯乙酸反应,通过控制反应条件制备了取代度为0.71的O-羧甲基壳聚糖,将改性后的O-羧甲基壳聚糖与多聚磷酸钠反应,制备了粒径分布在370-710nm的O-羧甲基壳聚糖纳米微粒,透射电镜观察表明该微粒呈球状,平均粒径为450nm.在此基础上研究了O-羧甲基壳聚糖纳米微粒对工业电镀镍废水Ni~(2+)吸附性能,考察了溶液pH、Ni~(2+)起始浓度、平衡吸附时间、粒径等因素的影响,结果表明:O-羧甲基壳聚糖微粒最佳吸附条件是Ni~(2+)溶液pH为8.0、Ni~(2+)溶液起始浓度为33.28mg/ml、平衡吸附时间为0.5h、粒径较小的O-羧甲基壳聚糖纳米微粒对Ni~(2+)的吸附量要大于粒径较大的吸附量.     

磺化硫杂杯[4]芳烃修饰纳米金的制备及对水溶液中Cr3+的比色检测

在不需外加还原剂的条件下一步原位合成了磺化硫杂杯[4]芳烃修饰的纳米金,并将其作为比色探针对金属离子进行检测。研究表明,磺化硫杂杯[4]芳烃修饰的纳米金能够选择性的识别CrP3+P,其检测限可达到1μM。     

Fe~(3+)掺杂的TiO_2纳米复合粒子的合成及表征

利用酸催化的溶胶-凝胶法合成了一系列不同Fe~(3+)掺杂量的TiO_2纳米复合 料子。用XRD,TEM,UV-vis等技术进行了表征。结果表明：在所研究的掺杂量范围 内(x_B = 0.0005 ～0.1000),未发现有铁氧化物的晶相生成;Fe~(3+)的掺杂可以 实现TiO_2由锐钛矿(anatase)结构向金红石(rutile)结构的低温转化,随着Fe~ (3+)掺杂量的增大,对光的吸收发生红移,吸收强度增大。掺杂适量的Fe~(3+)可 以使TiO_2纳米微粒的光催化活性得以提高。     

Synthesis and characterization of gold nanoparticles stabilized by palladium(II) phosphine thiol

This work is focused on the synthesis of innovative hybrids made by linking gold nanoparticles to protected organometallic Pd(II) thiolate. The organometallic protected Pd(II) thiolate, i.e. trans-thioacetate-ethynylphenyl-bis(tributylphosphine)palladium(II) has been synthesized, in situ deprotected and linked to Au nanoparticles. In this way new hybrid, with a direct link between Pd(II) and Au nanoparticles through a single S bridge, has been isolated. The combination of the organometallic Pd(II) thiol with gold nanoparticles allows the enhancement and tailoring of electronic and optical properties of the new organic-inorganic nano-compound. Single-crystal gold nanoparticles, uniform in shape and size were obtained by applying a modified two-phase method (improved Brust-Schiffrin reaction). In addition, the chemical environment of the Au nanoparticles was investigated and a covalent bonding between Au nanoparticles and the organometallic thiols was observed.     

Visual determination of Cu(2+) through copper-catalysed in situ formation of Ag nanoparticles

A new strategy was explored for the visual determination of Cu(2+) using copper-catalysed in situ formation of Ag nanoparticles. In this method, only common reagents were used and the pre-synthesis and modification of nanoparticles are avoided. Ag(+) can form a milk-white suspension (AgBr) with Br(-) in an aqueous solution composed of AgNO(3), cetyltrimethylammonium bromide, ascorbic acid, bovine serum albumin, and NaNO(3). The reaction will be stopped by addition of Cu(2+), accompanied by a colour change from milk-white to orange or brilliant yellow. Cu(+) (the reduction product of Cu(2+)) consumes the dissolved O(2) and prevents the O(2) from oxidizing the newly reduced Ag atoms (by ascorbic acid) back to Ag(+), facilitating the further aggregation of Ag atoms to become Ag nanoparticles. The visible colour change was shown to be specific towards Cu(2+) over most other metal ions. The limit of detection was 0.75 μM Cu(2+) by the naked eye and 0.25 μM by spectrometer. Quantitation of Cu(2+) was achieved in a linear range from 0.25 to 2.0 μM. This method was validated by measuring real water and serum samples, giving results agreeing well with the data reported and measured by inductively coupled plasma mass spectrometry. The recovery was 95.6-106% for untreated tap water and 96.0-100% for resin-pre-treated water and serum samples.     

Au/CeO2/SiO2催化CO低温氧化反应过程中CeO2的作用（英文）

采用具有分等级孔道结构的SiO2(HMS)为载体,通过润湿浸渍引入少量CeO2,经焙烧得到CeO2/HMS复合载体,然后采用沉积沉淀法负载上Au纳米粒子,得到Au/CeO2/HMS三元复合催化剂.通过X射线衍射、程序升温还原和原位红外光谱等手段表征了催化剂的结构.结果表明,CeO2的存在可控制Au颗粒的沉积并稳定载体上的纳米Au颗粒.Au/CeO2/HMS上CO低温氧化反应完全转化温度为60oC.高度分散的Au0可以活化CO,CeO2颗粒则可以提供反应需要的氧.稳定性测试结果显示,反应48h催化剂活性维持不变.     

Deposit of UV- or γ-synthesized gold nanoparticles on TiO2 powder using lipid-based multilamellar vesicles

This article describes a general method for the deposition of gold nanoparticles onto solid support based on the use of multilamellar vesicles (MLVs). Gold nanoparticles (nps) synthesized within lipid-based MLVs by UV- or γ-irradiation were deposited onto TiO₂ powder support. The organic phase from MLVs was removed by calcination leading to high dispersion of naked Au nanoparticles. The resulting particles were investigated using spectrometry, electron microscopy and XPS. The gold nanoparticles were stable and well-separated on the titania surface. It was found that the metal nanoparticles produced by radiolysis have smaller average size and narrower size distribution than those synthesized by photochemical route. After calcinations, the particles tended to enlarge to reach c.a. 18 nm. The gold loading on the titania support could be controlled by changing the gold salt concentration and the MLV-to-TiO₂ weight ratio; values of Au-to-Ti ratio up to 44 % could be obtained.     

Preparation of functionally Pegylated gold nanoparticles with narrow distribution through autoreduction of auric cation by alpha-biotinyl-PEG-block-[poly(2- (N,N-dimethylamino)ethyl methacrylate)

PEGylated gold nanoparticles with biotin moieties installed at the distal end of the PEG tethered chains were prepared by the autoreduction of HAuCl4 catalyzed by alpha-biotinyl-PEG-block-poly[2-(N,N-dimethylamino)ethyl methacrylate] (biotinyl-PEG/PAMA) in aqueous medium at room temperature. The size of the gold nanoparticles was controllable in a range of 6-13 nm by changing the initial Au3+/polymer ratio, while retaining their narrow size distribution. The dispersion stability of the nanoparticles in aqueous medium was extremely high even under the condition of salt concentration as high as I = 2.0. Biotinyl-PEG/PAMA-anchored gold nanoparticles underwent specific aggregation in the presence of streptavidin, revealing their promising utility as colloidal sensing systems applicable under biological condition.     

Determination of Nanomolar Levels of Mercury(II) by Exploiting the Silver Stain Enhancement of the Aggregation of Aptamer-Functionalized Gold Nanoparticles

An ultrasensitive method for the determination of mercury(II) ions was developed based on mercury(II)-induced strong and selective binding of thymine-thymine mismatches between aptamers on gold nanoparticles and a signal amplification effect caused by a silver stain. The gold nanoparticles were first coated with a single-stranded DNA aptamer rich in thymine. In the presence of mercury(II), the functionalized gold nanoparticles aggregated due to the formation of thymine-Hg(II)-thymine complexes resulting in a largely reduced surface area of the gold nanoparticles when exposed to silver ions during staining. Therefore, fewer silver ions were reduced, and the average grey values, as measured by a scanner, were lower. The average grey values were linearly related to the logarithm of mercury(II) concentration from 1 to 500 nM. In addition, there were no significant interferences by common metal ions due to the high specificity of the interaction between mercury(II) and the aptamer. The method offers high sensitivity, good selectivity, and the absence of large equipment that makes it suitable for field analysis.