SPE及纳米金涂层毛细管电泳检测血浆中土霉素与多西环素

建立了混合型固相萃取及季铵化纤维素负载的纳米金涂层毛细管电泳法快速检测血浆中土霉素和多西环素的方法。采用季铵化纤维素负载的纳米金复合材料(QC-Au NPs)对毛细管内壁进行动态涂层,以抑制管壁对分析物的吸附,并对缓冲液p H值进行优化。结果表明,该涂层能改善峰形和分离度,提高分离效率,其中土霉素的柱效提高了17.9倍。在涂层毛细管中,土霉素和多西环素的吸附被抑制,并在4 min内出峰。在10~200μg/m L范围内,土霉素和多西环素的峰面积与浓度的线性关系良好,相关系数(r)分别为0.997 6和0.995 2。血浆中土霉素和多西环素的加标回收率为88%~107%,相对标准偏差(RSD)为1.4%~7.7%。该方法快速、简便,准确度和精密度高,适用于血浆中土霉素和多西环素的快速检测。     

流动注射抑制化学发光法测定盐酸多西环素和土霉素

在酸性条件下,Ce(Ⅳ)-罗丹明6G发光体系有较强的化学发光,盐酸多西环素及土霉素的存在能抑制其发光。且化学发光信号的减小值(ΔI)与盐酸多西环素及土霉素的浓度在一定的范围内有较好的线性关系。据此结合流动注射技术,建立了快速测定盐酸多西环素及土霉素的流动注射化学发光分析新方法。优化了影响化学发光的各种因素。结果表明在优化的条件下,盐酸多西环素及土霉素的线性范围分别是1.0×10-7~1.0×10-4g/mL,1.0×10-6~1.0×10-4g/mL,测定的检出限为5.0×10-8g/mL及2.7×10-7g/mL,对1.0×10-6g/mL的盐酸多西环素及1.0×10-5g/mL的盐酸土霉素分别进行了9次平行测定,其相对标准偏差分别为1.4%、1.6%。方法已用于盐酸多西环素及土霉素片剂的测定。     

以金纳米粒子为探针比色法检测顺铂

报道了一种以金纳米粒子表面等离子吸收带变化为基础, 通过DNA与cis-Pt相互作用来检测溶液中cis-Pt浓度的新型比色法.     

基于氢键作用的金纳米粒子比色法检测尿酸

尿酸含量高可使人产生痛风等疾病,尿酸的测定是临床检测重要的生化指标之一。金纳米粒子比色法检测尿酸实验联系实际生活,将科研前沿和教学内容有机结合起来,可以激发学生的学习兴趣,加深学生对经典理论的理解,增加学生对科研前沿的了解。本实验利用金纳米粒子吸光系数高的特点,通过尿酸与三聚氰胺反应后,抑制三聚氰胺诱导的金纳米粒子聚集,从而达到检测尿酸的目的。随着溶液中尿酸浓度的增加,溶液颜色由蓝变红,差别明显,视觉效果好,容易分辨。     

基于碘刻蚀金纳米棒的比色法测定多巴胺

基于金纳米棒(AuNRs)具有可调节的表面等离子共振(SPR)光学特性,以及多巴胺(DA)还原KIO3生成的I2刻蚀AuNRs,并使其光谱蓝移的原理,发展了一种以波长变化为响应信号的比色分析法,用于多巴胺(DA)的高灵敏测定.KIO3不能刻蚀AuNRs,但在DA存在下,IO3-还原生成的I2能刻蚀AuNRs,使其纵向局...     

金纳米棒非聚集比色法测定多巴胺

基于在金纳米棒(AuNRs)-Ag⁺-多巴胺(DA)体系中,DA快速将Ag⁺还原为Ag,Ag包裹在AuNRs表面形成核壳状纳米棒(Au@AgNRs),改变了AuNRs周围的电介质环境,导致其纵横比减小、纵向等离子体共振吸收波长带(LPAB)蓝移,同时伴随着溶液的颜色发生显著的变化, 藉此开发了一种快速测定DA的比色法. 方法已成功应用于血清中DA的测定,其结果与荧光法相吻合. 此外,探讨了比色法测定DA的机理.     

基于金纳米粒子探针比色法检测乙基谷硫磷

基于乙基谷硫磷在酸性条件下可以诱导金纳米粒子（AuNPs）发生聚集,建立了以AuNPs为探针、结合比色和分光光度法检测乙基谷硫磷的方法。通过改变氯金酸和还原剂柠檬酸钠的比例,制备了不同粒径的AuNPs。酸性溶液中乙基谷硫磷分子中-P=S键发生质子化,形成的-SH与Au形成S-Au键,使AuNPs发生聚集,溶液颜色由红色转变为蓝色。考察了乙酸-乙酸钠缓冲溶液的pH和浓度以及乙基谷硫磷与AuNPs的作用时间对AuNPs聚集程度的影响。在优化条件下,吸光度比值（A694 nm/A524 nm）与乙基谷硫磷浓度在0.392～0.603μmol/L范围内具有良好的线性关系,检出限为0.0782μmol/L。     

谷胱甘肽修饰的金纳米粒子探针比色法检测神经元素3

采用柠檬酸钠还原法合成了粒径为13 nm的金纳米粒子,并在其表面修饰上谷胱甘肽(GSHAuNPs)。在一定的盐浓度范围内,谷胱甘肽能保护金纳米粒子免受盐诱导的聚集。当神经元素3(Neurogenin3,ngn3)多肽片段存在时,在一定的盐浓度下,ngn3片段能够诱导GSH-AuNPs发生聚集,使金纳米粒子溶液由红色变成蓝色。以谷胱甘肽修饰的金纳米粒子为探针,建立了快速检测ngn3片段的比色方法。通过优化得到的最适实验条件为:ngn3与GSH-AuNPs的平衡反应时间10 min,缓冲液pH=6.0,NaCl浓度100 mmol/L。在优化条件下,检测ngn3的线性范围为20~300μg/L,检出限(LOD)为8μg/L。结果表明,本方法具有良好的选择性,可用于实际样品的检测。     

基于适配体的纳米金比色法快速检测雌二醇研究

单链核酸适配体可以通过静电作用吸附到纳米金表面,保护纳米金免于高盐浓度引起的纳米金凝聚溶液变蓝现象;当加入靶标后,适配体与靶标结合,并从纳米金上解离,纳米金在高盐浓度下发生凝聚,溶液颜色由红变蓝。利用该原理,建立了一种基于适配体的雌二醇纳米金比色快速检测法。首先将雌二醇的适配体与纳米金室温孵育5 min,然后加入不同浓度的雌二醇,再室温孵育5 min,最后加入2 mol/L的NaCl,5min后观察纳米金溶液颜色,并用紫外可见分光光度计分别测定520 nm和620 nm的吸光度值。结果表明,随着雌二醇浓度增高,纳米金溶液的颜色由红变蓝,OD620/OD520比值逐渐增加,最低可以检测到10 ng/mL的雌二醇。利用其他非特异靶标对该方法进行测试表明,结构类似物如雌三醇、雌酮、睾酮等在一定浓度下也会引起纳米金溶液变蓝,而其他类雌激素物质如己烯雌酚、双酚A和溶剂甲醇等非特异靶标即使高浓度下也不会引起纳米金溶液变蓝,表明该方法具有非常好的特异性。该研究为环境内分泌干扰物中雌二醇的快速检测提供了一种新思路。     

Simple and sensitive colorimetric detection of cysteine based on ssDNA-stabilized gold nanoparticles

In this paper, we demonstrate a simple and sensitive colorimetric detection of cysteine based on the cysteine-mediated color change of ssDNA-stabilized gold nanoparticles (AuNPs). Cysteine is capable of absorbing onto AuNPs surfaces via the strong interaction between its thiol group and gold. ssDNA molecules which stabilize AuNPs against salt-induced aggregation are removed away by cysteine encapsulation on the AuNPs surfaces, resulting in a characteristic color change of AuNPs from red to blue as soon as salt is added. The ratio of absorptions at 640 to 525 nm (A ₆₄₀/A ₅₂₅) is linear dependent on the cysteine concentration in the range from 0.1 to 5 μM. Furthermore, amino acids other than cysteine cannot mediate the color change under the identical conditions due to the absence of thiol groups, suggesting the selectivity of the proposed method toward cysteine. The employment of complicated protocols and sophisticated processes such as the preparation of modified AuNPs are successfully avoided in design to realize the simple and low-cost cysteine detection; and the high sensitivity and low cost of the method is favorable for practical applications. Figure In the presence of cysteine, cysteine binds to the AuNPs surface via Au-S bond, spontaneously driving ssDNA molecules away from the nanoparticles, which leads to the AuNPs aggregation under the condition of NaCl introduction, and the corresponding color change from red to blue. However, the presence of other amino acids results in no color change due to the absence of thiol groups. Electronic supplementary material  The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

Highly sensitive colorimetric detection of NH3 based on Au@Ag@AgCl core-shell nanoparticles

As an important component of the atmosphere, ammonia (NH₃) plays a very important role in maintaining the balance of environment. However, it is also one of the most toxic gases that can cause damage to the human respiratory system and mucous membranes even at low concentrations. As such, development of highly sensitive and selective NH₃ sensors is of high significance for environmental monitoring and health maintenance. Herein, we have synthesized Au@Ag@AgCl core-shell nanoparticles (NPs) by oxidative etching and precipitating Au@Ag core-shell NPs using FeCl₃ and further used them as optical probes for the colorimetric detection of NH₃. The sensing mechanism is based on the fact that the etching of NH₃ on AgCl and Ag shell leads to the variations of ingredients and core-to-shell ratio of the Au@Ag@AgCl NPs, thereby inducing noticeable spectral and color changes. By replacing the outmost layer of Ag with AgCl, not only is the stability of the sensor against oxygen significantly enhanced, but also is the sensitivity of the method improved. The method exhibits good linear relationship for the detection of NH₃ from 0 to 5000 μmol/L with the limit of detection of 6.4 μmol/L. This method was successfully applied to the detection of simulated air polluted by NH₃, indicating its practical applicability for environmental monitoring. This method shows great potential for on-site NH₃ detection particularly in remote area, where a simple, fast, low-cost, and easy-to-handle method is highly desirable.     

Highly selective and sensitive visualizable detection of Hg2+ based on anti-aggregation of gold nanoparticles

For the widely used gold nanoparticles (AuNPs)-based colorimetric probes, AuNPs generally change from dispersion to aggregation state accompanying with corresponding color turning from red to blue. Although colorimetric probes based on the anti-aggregation of AuNPs show exceptional selectivity and sensitivity, few examples have been reported in literature. A facile but highly sensitive and selective colorimetric probe based on the anti-aggregation of AuNPs transferred from the deactivation of aggregation agent 4,4′-dipyridyl by Hg²⁺ was developed in this work. This reported probe is suitable for real-time detection of Hg²⁺ in water with a detection limit of 3.0 ppb for Hg²⁺, and exhibits a selectivity toward Hg²⁺ by two orders of magnitude over other metal ions. The dynamic range of this probe can be conveniently tuned by adjusting the amount of 4,4′-dipyridyl used.     

Sensitive and selective detection of glutathione based on resonance light scattering using sensitive gold nanoparticles as colorimetric probes

In this paper, we reported the development of a highly sensitive and selective resonance light scattering (RLS) technique for glutathione using gold nanoparticle probes. The assay relies upon the distance-dependent optical properties of gold nanoparticles, the self-assembly of glutathione on gold nanoparticles, and the interaction of a 2 : 1 glutathione-Cu(2+) complex. In the presence of Cu(2+), glutathione could rapidly induce the aggregation of gold nanoparticles, thereby resulting in greatly enhanced RLS intensity and red-to-blue (or purple) color change. The concentration of glutathione can be determined by the naked eye or a fluorescence spectrometer. Under the optical conditions, the detection of glutathione can be finished within 20 min, and the detection limit of 10 nM can be reached. The concentration range of the probe is 40-280 nM. The proposed method holds a specific selectivity toward glutathione and it is applied to the detection of glutathione in human serum with satisfactory results. In addition, the assay shows great potential application for disease-associated biomarkers, and it will meet the great demand for amino acid determination in fields such as food processing, biochemistry, pharmaceutical, and clinical analysis.     

基于多巴胺-量子点的比色免疫分析法对甲胎蛋白的高灵敏检测

基于抗原抗体识别特异性,以多巴胺-Mn/ZnS量子点(DA-QDs)为反应媒介,紫外可见分光光度计为检测手段,采用柠檬酸钠还原法制备金纳米颗粒(AuNPs),其表面用辣根过氧化物酶(HRP)和羊抗小鼠免疫球蛋白G (IgG)修饰获得功能化二抗(IgG-AuNPs-HRP)作为信号放大标签,构建一种简便高灵敏的检测方法....     

Naked-eye sensitive detection of nuclease activity using positively-charged gold nanoparticles as colorimetric probes

Positively-charged gold nanoparticles can effectively differentiate long DNA and fragmented DNA, thus providing a simple and visual approach to colorimetric detection of nuclease activity.     

A facile and sensitive colorimetric detection for RNase A activity based on target regulated protection effect on plasmonic gold nanoparticles aggregation

In this work, a facile and sensitive colorimetric detection method was firstly reported for RNase A activity detection based on target regulated protection effect of chimeric DNA probe on the salt-induced aggregation of plasmonic gold nanoparticles.Compared with previous works of RNase A activity detection, this colorimetric assay integrated the advantages of sensitive, low cost, facile operation, rapid response and low biological toxicity.     

Simple, rapid, homogeneous oligonucleotides colorimetric detection based on non-aggregated gold nanoparticles

A simple, rapid colorimetry for DNA detection based on non-aggregated gold nanoparticles and magnetic beads has been developed with high selectivity and sensitivity.     

Highly sensitive electrochemical stripping detection of hepatitis B surface antigen based on copper-enhanced gold nanoparticle tags and magnetic nanoparticles

On the basis of copper-enhanced gold nanoparticle tags as an amplification approach, we introduced, in this paper, magnetic nanoparticles for further improving performance of electrochemical immunoassay by anodic stripping voltammetry (ASV) at a glassy-carbon electrode. Due to the use of antibody-immobilized magnetic nanoparticles, the immunoreaction between antibody and antigen takes place in a homogeneous bulk solution phase. Compared with traditional solid interface reaction, the proposed strategy can provide some advantages such as easy of separation, shorter analytical time, wider linear range, and lower detection limit. It was also successfully applied to HBsAg determination in a linear range of 0.1-1500 ng mL⁻¹ with a detection limit of 87 pg mL⁻¹. The proposed analytical strategy holds good selectivity, sensitivity and repeatability and also great promise for the extended application in the fields of clinical diagnosis, bio-affinity assay and environmental monitoring.