核酸适体修饰纳米金共振散射光谱探针快速检测痕量Pb~(2+)

以柠檬酸三钠做稳定剂,用硼氢化钠还原氯金酸制备了粒径为5nm的纳米金.用铅离子核酸适体aptamer保护纳米金获得了检测铅离子的适体纳米金(aptamer-NG)共振散射光谱探针.在pH7.0的Na2HPO4-NaH2PO4缓冲溶液中及30mmol·L-1NaCl存在下,aptamer-NG稳定而不聚集.Pb2+可与该探针中的aptamer形成非常稳定的G-四分体结构,并释放出纳米金.在NaCl作用下纳米金聚集形成较大的微粒,导致552nm处共振散射峰强度增大.Pb2+浓度在0.07～42nmol·L-1范围内与552nm处共振散射强度增大值ΔI成线性关系,其回归方程为ΔI=12.0c+9.2,线性相关系数为0.9965,方法检出限为0.03nmol·L-1Pb2+.该方法用于水样中铅离子检测,结果与石墨炉原子吸收光谱法结果一致.     

核酸适体修饰纳米金共振散射光谱探针快速检测痕量Pb2＋

以柠檬酸三钠做稳定剂, 用硼氢化钠还原氯金酸制备了粒径为5 nm的纳米金. 用铅离子核酸适体aptamer保护纳米金获得了检测铅离子的适体纳米金(aptamer-NG)共振散射光谱探针. 在pH 7.0的Na₂HPO₄-NaH₂PO₄缓冲溶液中及30 mmol•L^－1 NaCl存在下, aptamer-NG稳定而不聚集. Pb^2＋可与该探针中的aptamer形成非常稳定的G-四分体结构, 并释放出纳米金. 在NaCl作用下纳米金聚集形成较大的微粒, 导致552 nm处共振散射峰强度增大. Pb^2＋浓度在0.07～42 nmol•L^－1范围内与552 nm处共振散射强度增大值ΔI成线性关系, 其回归方程为ΔI＝12.0c＋9.2, 线性相关系数为0.9965, 方法检出限为0.03 nmol•L^－1 Pb^2＋. 该方法用于水样中铅离子检测, 结果与石墨炉原子吸收光谱法结果一致.     

非标记纳米银探针催化共振散射光谱检测痕量ATP

在pH 7.8 Tris-HCl缓冲液中, 三磷酸腺苷(adenosine triphosphate, ATP)的核酸适体(Apt 1)与其互补链(Apt 2)结合生成双链DNA (double-strand DNA, dsDNA). 此dsDNA不能稳定纳米银(AgNP), NaCl可致AgNP聚集, 在500 nm波长处产生一个较强的共振散射峰. 加入ATP后, ATP与dsDNA中的Apt 1结合形成较稳定的发夹结构结合物并释放出可稳定AgNP的Apt 2. 随着ATP浓度(16.5～1650 nmol/L)增加, 生成的Apt 2增加, 被Apt 2稳定的AgNP即AgNP-Apt 2结合物增加, 聚集的AgNP减少, 500 nm处的共振散射值线性减小. 该适配体反应中的AgNP-Apt 2对葡萄糖-铜(II)微粒反应具有较强的催化作用, 其产物氧化亚铜微粒在610 nm处有一较强共振散射峰. 随着ATP浓度增大, 反应液中AgNP-Apt 2增多, 催化作用增强, 610 nm处的共振散射峰增强. ATP浓度在4.95～165 nmol/L范围内与共振散射增大值ΔI_{610 nm}呈线性关系, 检出限为1.8 nmol/L ATP. 据此建立了灵敏度高、选择性好、简便快速检测ATP的共振散射光谱新方法.     

鲱鱼精DNA修饰纳米金催化Fehling反应——共振散射光谱法检测痕量Hg~(2+)

用鲱鱼精DNA(hsDNA)修饰10nm的纳米金制备了Hg2+的hsDNA修饰纳米金共振散射光谱探针(AuhsDNA).在pH7.0Tris-HCl缓冲溶液中及0.017mol/LNaCl存在下,Hg2+与AuhsDNA形成稳定的Hg2+-DNA结合物,引起AuhsDNA中的纳米金析出并聚集形成纳米金簇.该溶液用150nm滤膜过滤后,滤液中过量的AuhsDNA可催化Fehling试剂-葡萄糖反应生成氧化亚铜微粒,该微粒在580nm处有一个较强的共振散射峰.随着汞离子浓度增大,形成的纳米金簇越多,滤液中AuhsDNA越少,生成的氧化亚铜微粒减少,580nm处氧化亚铜微粒的共振散射光强度线性降低,其共振散射光强度降低值ΔI580nm与汞离子浓度在1～833nmol/L范围内成线性,回归方程、相关系数、检出限分别为ΔI580nm2+Hg=0.37C+0.9,0.9990,0.3nmol/LHg2+.该法用于废水中Hg2+的检测.     

适体修饰纳米金催化-共振散射光谱测定凝血酶

用核酸适体修饰纳米金制备了识别凝血酶(TB)的适体修饰纳米金(AptAu)共振散射光谱探针. 在pH 7.40 的Na₂HPO₄-NaH₂PO₄缓冲溶液中及NaCl, KCl存在下, AptAu探针中的适配体特异识别凝血酶, 生成稳定的G-四分体和大粒径的纳米金聚集体. 经微孔滤膜过滤后, 纳米金聚集体被分离, 以滤液中未反应的AptAu作催化晶种, 在20.0 μg/mL HAuCl₄-5.01 mmol/L HCl-1.83 mg/mL CTMAB-50.1 μg/mL VC条件下, 催化维生素C (VC)还原HAuCl₄生成较大粒径的金颗粒, 体系在600 nm处有一共振散射峰. 随着凝血酶浓度的增大, 滤液中AptAu浓度降低, 催化作用减弱, 600 nm处的共振散射峰降低, 其降低值ΔI_{600 nm}与凝血酶浓度在6.40×10^－3～0.150 U/mL范围内存在良好线性关系, 回归方程为ΔI＝1.26×10³C＋1.50, 相关系数为0.999, 检出限为1.30×10^－3 U/mL. 该法用于定量分析人血浆中凝血酶, 结果满意.     

痕量甲胎蛋白的免疫纳米金催化-氧化亚铜微粒共振散射光谱分析

用粒径15 nm 的纳米金标记单克隆羊抗人甲胎蛋白(GAFP), 制备了甲胎蛋白(AFP)的免疫纳米金探针(AuGAFP). 纳米金及AuGAFP均对葡萄糖还原铜(Ⅱ)生成Cu₂O微粒这一慢反应具有较强的催化作用, Cu₂O微粒在620 nm处产生1个较强的共振散射峰. 将AFP-AuGAFP免疫反应与离心分离技术结合, 建立了超痕量AFP的免疫纳米金催化-Cu₂O微粒共振散射光谱新方法. 随着AFP浓度的增大, AFP-AuGAFP免疫复合物微粒增多, 离心液中AuGAFP浓度降低, 620 nm处的共振散射光强度I_{620 nm}线性降低, 其降低值ΔI_RS与AFP质量浓度ρ(AFP)在0.10～16.0 ng/mL范围内呈现良好的线性关系, 其回归方程为ΔI_RS=4.27ρ(AFP)+1.28, 检出限为0.05 ng/mL. 本方法所用试剂易得, 反应易控制, 灵敏度高, 选择性好, 用于定量分析人血清中的AFP, 结果令人满意.     

免疫金铂纳米合金催化共振散射光谱法测定痕量人绒毛膜促性腺激素

以NaBH₄为还原剂, 制备了金与铂物质的量比为49∶1的金铂纳米合金(GP). 用兔抗人绒毛膜促性腺激素抗体(RhCG)修饰AuPt获得了免疫纳米合金探针(GP-RhCG). 在pH 5.8磷酸氢二钠-柠檬酸缓冲溶液及KCl存在的条件下, GP-RhCG探针发生非特异性聚集, 在590 nm处有一个较强的共振散射峰. 当有人绒毛膜促性腺激素(hCG)存在时, 聚集的GP-RhCG探针与hCG发生特异性结合, 生成分散性较好的GP-RhCG-hCG免疫复合物, 导致590 nm处共振散射峰强度降低. 其共振散射峰强度降低值ΔI_{590 nm}与hCG浓度在6.67～86.7 ng/mL范围内呈现良好线性关系. 免疫反应液中形成的GP-RhCG-hCG免疫复合物对葡萄糖-铜(II)体系具有较强的催化作用, 其产物在610 nm处有一较强共振散射峰. 随着hCG浓度增大, 形成的GP-RhCG-hCG复合物越多, 其催化作用增强, 610 nm处的共振散射峰增强. 其共振散射峰增大值ΔI_{610 nm}与hCG浓度在3.33～133 ng/mL范围内呈线性关系.     

鲱鱼精DNA修饰纳米金催化Fehling反应——共振散射光谱法检测痕量Hg2＋

用鲱鱼精DNA (hsDNA)修饰10 nm的纳米金制备了Hg^2＋的hsDNA修饰纳米金共振散射光谱探针(AuhsDNA). 在pH 7.0 Tris-HCl缓冲溶液中及0.017 mol/L NaCl存在下, Hg^2＋与AuhsDNA形成稳定的Hg^2＋-DNA结合物, 引起AuhsDNA中的纳米金析出并聚集形成纳米金簇. 该溶液用150 nm滤膜过滤后, 滤液中过量的AuhsDNA可催化Fehling试剂-葡萄糖反应生成氧化亚铜微粒, 该微粒在580 nm处有一个较强的共振散射峰. 随着汞离子浓度增大, 形成的纳米金簇越多, 滤液中AuhsDNA越少, 生成的氧化亚铜微粒减少, 580 nm处氧化亚铜微粒的共振散射光强度线性降低, 其共振散射光强度降低值?I₅₈₀ nm与汞离子浓度在1～833 nmol/L范围内成线性, 回归方程、相关系数、检出限分别为 ?I_{580 nm}＋0.9, 0.9990, 0.3 nmol/L Hg^2＋. 该法用于废水中Hg^2＋的检测.     

金纳米微粒作探针共振瑞利散射光谱法测定亚甲蓝

在pH为6.5~9.5的中性或弱碱性介质中, 金纳米微粒可与亚甲蓝(MB)阳离子靠静电引力及疏水作用力结合, 形成粒径较大的聚集体(平均粒径从12 nm增至20 nm), 这种聚集体的形成导致共振瑞利散射(RRS)强度显著增强, 最大散射峰位于371 nm. 在适当条件下, 散射强度(ΔI)与亚甲蓝浓度成正比. 该法具有高灵敏度, 将金纳米微粒作为测定亚甲蓝的高灵敏RRS探针, 对亚甲蓝的检出限为21.17 ng/mL, 该法简便， 快速， 且有较好的选择性, 可用于血液中亚甲蓝的测定.     

高灵敏选择性检测凝血酶的适体纳米银共振散射光谱探针

采用四氢硼钠制备了较稳定的纳米银,并用凝血酶(TB)适体修饰纳米银制各了识别凝血酶的适体纳米银探针.在pH 7.0的Tris-HCl缓冲溶液及KCl存在下,适体纳米银探针与凝血酶特异结合生成G-四分体和纳米银聚集体,导致体系在480 nm处的共振散射峰增强.随着凝血酶浓度的增大,生成的纳米银聚集体越多,共振散射强度线性...     

A Highly Sensitive Resonance Scattering Spectral Assay for Hg2+ Based on the Aptamer-Modified AuRu Nanoparticle-NaClO3-NaI-Cationic Surfactant Catalytic Reaction

Gold ruthenium (AuRu) nanoparticles were modified by single strand DNA (ssDNA) to prepare an aptamer AuRu nanoprobe (AuRussDNA) for Hg²⁺. The nanoprobe reacted with Hg²⁺ to form double-stranded T-Hg²⁺-T mismatches, and the released AuRu nanoparticles aggregated to big particles, which induced an increase in the resonance scattering (RS) signal at 592 nm. The RS signal was linear to the concentration of Hg²⁺ in the range of 0.0067–3.3 nmol L^?1. Using the AuRussDNA in filtration solution as a catalyst, a new catalytic RS assay was proposed for detection of trace Hg²⁺. This method was applied for the determination of Hg²⁺ in real samples.     

由长链醇选择性氧化制备香料(英文)

The activity and the selectivity of Ru and Pt based carbon catalysts in the selective oxidation of long-chain aliphatic alcohols (C8, C10, C12) have been investigated. Ru/AC and Pt/AC always showed good initial activity, however deactivation phenomena rapidly depressed the catalytic per-formance of the catalysts. These phenomena can be limited by modification of Ru/AC and Pt/AC with Au improving the durability of the catalyst. Ru/AC and AuRu/AC showed good selectivity to the corresponding aldehyde (95%) making these catalysts promising for fragrances manufacturing. The advantage in using Au modified catalyst lies on the easier regeneration procedure com-pared to the one necessary for Ru/AC. Pt /AC and AuPt/AC showed a lower selectivity to aldehyde promoting the formation of the acid and the ester formation respectively. The addition of water in the solvent system speeds up the reaction rate but drastically decreased the selectivity to aldehyde especially in the case of Pt based catalysts.     

Solid-state electrochemiluminescence protein biosensor with aptamer substitution strategy

One solid-state electrochemiluminescence(ECL) protein biosensor based on the competing reaction and substitute reaction between protein-to-DNA aptamer and DNA-to-DNA aptamer was proposed.Additionally,the biosensor was based on ECL photo-quenching effect of ferrocene(Fc) to tris(2,2'-bipyridyl)ruthenium(II)(Ru(bpy)32+).It was built up by modification of Au nanoparticles(AuNPs) and Ru(bpy)3 2+ on one Au electrode firstly,and then self-assembly of one special double-stranded DNA(dsDNA) onto the electrode.This ...     

Resonance Scattering Detection of Trace Hg2+ Using Aptamer‐modified AuPd Nanoalloy Probe as Catalyst

The 5 nm AuPd nanoalloy in mole ratio of Au:Pd=32:1 was prepared, using sodium citrate as the stabilizing agent and NaBH₄ as the reductant. The AuPd nanoalloy was modified by the aptamer to prepare an aptamer‐ AuPd (AptAuPd) probe for resonance scattering (RS) detection of 5.0–1250 nmol/L Hg²⁺. The AptAuPd‐Hg²⁺ aptamer reaction solution was filtrated by membrane, and the AptAuPd in the filtrate exhibited strong catalytic effect on the slow NiP particle reaction between NiCl₂ and NaH₂PO₂, and the NiP particles showed a RS peak at 508 nm. The RS intensity decreased when Hg²⁺ concentration increased. The decreased RS intensity was linear to Hg²⁺ concentration in the range of 0.5–1250 nmol/L. The RS assays were used to determine Hg²⁺ in real samples, with good results.     

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.     

A solid-state electrochemiluminescence sensing platform for detection of adenosine based on ferrocene-labeled structure-switching signaling aptamer

A solid-state electrochemiluminescence sensing platform based on ferrocene-labeled structure-switching signaling aptamer (Fc-aptamer) for highly sensitive detection of small molecules is developed successfully using adenosine as a model analyte. Such special sensing platform included two main parts, an electrochemiluminescence (ECL) substrate and an ECL intensity switch. The ECL substrate was made by modifying the complex of Au nanoparticle and Ruthenium (II) tris-(bipyridine) (Ru(bpy)₃²⁺-AuNPs) onto Au electrode. An anti-adenosine aptamer labeled by ferrocene acted as the ECL intensity switch. A short complementary ssDNA for the aptamer was applied to hybridizing with the aptamer, yielding a double-stranded complex of the aptamer and the ssDNA on the electrode surface. The introduction of adenosine triggered structure switching of the aptamer. As a result, the ssDNA was forced to dissociate from the sensing platform. Such structural change of the aptamer resulted in an obvious ECL intensity decrease due to the increased quenching effect of Fc to the ECL substrate. The analytic results were sensitive and specific.     

Rhodamine-derived Schiff base for the selective determination of mercuric ions in water media

A new rhodamine-derived Schiff base (RS) was synthesized and its sensing property to metal ions was investigated by UV/vis and fluorescence spectroscopies. Addition of Hg2+ ions to the aqueous solution of RS gave a visual color change as well as significantly fluorescent enhancement, while other ions including Pb2+, Cd2+, Cr3+, Zn2+, Cu2+, Fe2+, Co3+, Ni2+, Ca2+, Mg2+, K+ and Na+ ions did not induce any distinct color/spectral changes, which constituted a Hg2+-selective fluorescent OFF-ON chemosensor. The Hg2+-induced ring-opening of spirolactam of rhodamine in RS resulted in the dual chromo- and fluorogenic observation.     

Multifunctional nanoprobe for cancer cell targeting and simultaneous fluorescence/magnetic resonance imaging

Multifunctional nanoprobes with distinctive magnetic and fluorescent properties are highly useful in accurate and early cancer diagnosis. In this study, nanoparticles of Fe₃O₄ core with fluorescent SiO₂ shell (MFS) are synthesized by a facile improved Stöber method. These nanoparticles owning a significant core-shell structure exhibit good dispersion, stable fluorescence, low cytotoxicity and excellent biocompatibility. TLS11a aptamer (Apt1), a specific membrane protein for human liver cancer cells which could be internalized into cells, is conjugated to the MFS nanoparticles through the formation of amide bond working as a target-specific moiety. The attached TLS11a aptamers on nanoparticles are very stable and can't be hydrolyzed by DNA hydrolytic enzyme in vivo. Both fluorescence and magnetic resonance imaging show significant uptake of aptamer conjugated nanoprobe by HepG2 cells compared to 4T1, SGC-7901 and MCF-7 cells. In addition, with the increasing concentration of the nanoprobe, T₂-weighted MRI images of the as-treated HepG2 cells are significantly negatively enhanced, indicating that a high magnetic field gradient is generated by MFS-Apt1 which has been specifically captured by HepG2 cells. The relaxivity of nanoprobe is calculated to be 11.5 mg⁻¹s⁻¹. The MR imaging of tumor-bearing nude mouse is also confirmed. The proposed multifunctional nanoprobe with the size of sub-100 nm has the potential to provide real-time imaging in early liver cancer cell diagnosis.     

羧甲基二硫代氨基甲酸酯功能化聚氯乙烯树脂的合成及对Ag~+的吸附与选择性能

以聚氯乙烯为大分子骨架,经三乙烯四胺胺化,再与二硫化碳和乙醇钠反应,得到的二硫代氨基羧酸盐改性聚氯乙烯树脂(PV-NS)进一步与氯乙酸钠反应,合成了一种同时舍N,S,O的羧甲基二硫代氨基甲酸酯改性聚氯乙烯树脂(PV-NSO).合成树脂的功能基结构经红外和元素分析确认.对合成树脂的吸附性能研究表明,合成树脂对Ag+、Hg2+、Au<'3+>、Pb2+离子的吸附容量在实验条件下分别达2.058mmol/g、1.514mmol/g,1.125mmol/g和0.415mmol/g,而对Cu2+、Cd2+、Zn2+、Ni2+、Mg2+等离子的吸附容量很小,甚至不吸附.树脂的选择性吸附表明,树脂对Ag+的吸附选择性较好,在有Hg2+、Pb2+、Cd2+、Zn2+、Cu2+或Mg2+共存时,树脂对Ag+的选择性吸附系数分别达4.74、17.33,12.98、∞、7.60和74.14.合成树脂在极性溶剂中的溶胀性能均比在非极性溶剂中好.     

G-quadruplex formation of thrombin-binding aptamer detected by electrospray ionization mass spectrometry

Electrospray ionization mass spectrometry detected the formation of the G-quadruplex structure of the thrombin-binding aptamer, d(GGTTGGTGTGGTTGG), and established its specific interaction with metal ions. One piece of evidence that the bonding in the gas phase is via the G-quadruplex form is the enhanced binding, with respect to other metal ions, of the aptamer with Sr2+, Pb2+, Ba2+, and K+, which are of similar size. Another is the lack of specific binding with controls in which the G's are replaced with A's. The most convincing evidence is the extent of H/D exchange of the gas-phase aptamer as compared to that bound to K+ and Sr2+. The latter two complexes exchange six and nine fewer H's, indicating a significant increase in protection upon binding to the metals. Mass spectrometry will be an important tool in understanding G-quadruplexes, which are particularly important in DNA telomers.