金纳米微粒作探针共振瑞利散射光谱法测定卡那霉素

在一种含柠檬酸盐的溶液中, 柠檬酸根阴离子自组装于带正电荷的金纳米微粒表面, 使金纳米微粒成为一种被柠檬酸根包裹的带负电荷的超分子化合物. 在pH 4.4～6.8的弱酸性介质中, 它可与质子化的卡那霉素(KANA)阳离子借静电引力、疏水作用力结合, 形成粒径更大的聚集体(平均粒径从12增至20 nm), 这种聚集体的形成在引起金纳米的等离子体吸收带明显红移(Δλ＝102 nm)的同时, 共振瑞利散射(RRS)显著增强并且倍频散射(FDS)和二级散射(SOS)等共振非线性散射也有较大的增强, 最大散射峰分别位于280 nm (RRS), 310 nm (FDS)和480 nm (SOS)处. 在适当条件下, 散射强度(ΔI)与卡那霉素的浓度成正比, 其中RRS法灵敏度最高, 因此金纳米微粒可作为测定卡那霉素的高灵敏RRS探针, 它对卡那霉素的检出限为10.52 ng•mL^－1, 方法有较好的选择性, 可用于血液中卡那霉素的测定, 文中还讨论了有关反应机理和RRS增强的原因.     

金纳米微粒共振光散射光谱探针测定维生素B_4-水溶性腺嘌呤的研究

建立了一种以金纳米微粒为探针共振光散射(RLS)法测定维生素B4的新方法.在弱酸性介质中(pH 4.2),金纳米微粒在635 nm有一最大共振散射峰.加入微量维生素B4后,金纳米微粒与维生素B4通过静电引力结合.形成了粒径较大的聚集体,导致RLS强度显著增强.研究了体系的共振光散射光谱特征和反应适宜条件,探讨了共振光散射增强的机理.结果表明,维生素B4质量浓度在0.1～5.0μg/mL 时与散射强度(△I)呈线性关系,检出限(3σ)为12.0 ng/mL,相对标准偏差(RSD)为2.2%.该方法已用于片剂中维生素B4的测定.     

金纳米微粒作探针共振瑞利散射光谱法测定盐酸异丙嗪

在pH 1.8～3.0的酸性介质中,质子化的盐酸异丙嗪(PMZ)可与带负电荷的金纳米微粒依靠静电和疏水作用相互结合,导致共振瑞利散射(RRS)强度显著增强,其最大散射峰位于368 nm,并在284,440,498 nm处有明显的散射峰,在选定的测量波长下,盐酸异丙嗪在0.04～0.10μg/mL的浓度范围内与RRS强度成正比,该法具有高的灵敏度,其检出限为1.34 ng/mL。考察了体系的RRS光谱特征,研究了适宜的反应条件、影响因素,研究了共存物质的影响,据此建立了金纳米微粒作探针RRS法测定盐酸异丙嗪的新方法。     

金纳米微粒作探针共振瑞利散射法测定某些蒽环类抗癌药物

在近中性至弱碱性介质中, 金纳米微粒与表柔比星(EPI)、柔红霉素(DNR)和米托蒽醌(MXT)等蒽环类抗癌药物借静电引力、疏水作用力结合, 形成粒径更大的聚集体, 导致共振瑞利散射(RRS)的显著增强并产生新的RRS光谱, 三种结合产物的最大RRS峰均位于313 nm附近, 并在510～610 nm之间有一宽的散射带. 其散射强度(ΔI)与3种抗癌药物的浓度成正比, 对EPI, DNR和MXT的线性范围分别为0.009～0.50, 0.010～0.70 和0.030～1.20 μg•mL^－1, 它们的检出限(3σ)分别为2.7, 3.1和9.0 ng•mL^－1. 研究了反应产物的吸收、荧光和RRS光谱特征, 适宜的反应条件及分析化学性质, 发展了一种用RRS技术灵敏、简便、快速测定蒽环类抗癌药物的新方法.     

纳米金探针瑞利共振散射法测定针剂中盐酸普鲁卡因

采用葡萄糖还原氯金酸的方法制得粒径约15nm的纳米金,在pH3.54酸性介质中它可以与盐酸普鲁卡因作用形成体积更大的纳米金聚集体。这种聚集体的形成可以使纳米金的瑞利共振散射强度急剧增强,其最大散射峰位于354nm左右。在适当的条件下,相对散射强度(ΔI)与盐酸普鲁卡因的浓度成正比。采用标准加入法,对针剂中的普鲁卡因进行测定,得到满意结果。线性范围0～40μg/L(r=0.9996);对含盐酸普鲁卡因30μg/L的溶液平行测定的相对标准偏差为2.51%(n=11);检出限(3σ)为16ng/L;测定限(10σ)为54ng/L。     

硫化镉纳米微粒作探针共振瑞利散射测定某些蒽环类抗癌药物

在pH=5.0—9.0的水溶液中, 硫化镉纳米微粒[(CdS)n]与蒽环类抗生素米托蒽醌(MXT)、 表柔比星(EPI)和柔红霉素(DNR)凭借静电引力及疏水作用力结合, 形成粒径更大的聚集体, 导致共振瑞利散射(RRS)的增强并产生新的RRS光谱, 最大的RRS峰位于292 nm(MXT体系)、 285 nm(DNR体系)和315 nm(EPI体系). 与此同时还观察到二级散射(SOS)和倍频散射(FDS)强度明显提高. 其最大SOS峰位于540 nm(MXT体系)和560 nm(EPI及DNR体系), 而最大的FDS峰分别位于335 nm(MXT体系)、 320 nm(EPI体系)和330 nm(DNR体系). 在一定条件下, 3种散射强度(ΔI)均与药物的浓度成正比, 反应具有高灵敏度, 对于3种药物的检出限在3.6—9.1 ng/mL之间. 其中(CdS)n-MXT体系灵敏度最高, 对MXT的检出限分别为4.1 ng/mL(RRS)、 3.8 ng/mL(SOS)和3.6 ng/mL(FDS). 据此发展了一种用纳米硫化镉作探针, 灵敏、 简便并快速测定蒽环类抗癌药物的共振瑞利散射新方法.     

金纳米微粒与盐酸氯丙嗪相互作用的共振Rayleigh散射光谱研究及其分析应用

在pH 1.8~3.3的酸性介质中,金纳米微粒本身有一定的共振瑞利散射(RRS)强度,但盐酸氯丙嗪本身的RRS强度十分微弱,当二者共存时,溶液的RRS强度显著增强并出现新的RRS光谱,在280~368 nm之间产生强烈的散射带,其最大散射波长位于368 nm,并在284、440、498 nm处有明显的散射峰。在一定条件下,盐酸氯丙嗪在0~0.08 mg/L范围内与ΔIRRS强度成正比,方法具有较高的灵敏度,对盐酸氯丙嗪的检出限(3σ)达到1.75μg/L。本文考察了反应体系的RRS光谱特征,研究了适宜的反应条件、影响因素及分析化学性质,研究了共存物质的影响,表明方法具有较好的选择性,据此发展了一种用金纳米微粒作RRS探针测定盐酸氯丙嗪的新方法。     

CdS纳米材料共振瑞利散射测定氧氟沙星的研究

在表面活性剂十二烷基磺酸钠SDS存在下,硫化镉能与氧氟沙星借静电引力及疏水作用力结合,形成粒径较大的聚集体.这种聚集体的形成导致硫化镉共振散射RRS强度显著增强,最大散射峰位于365nm.在适当条件下,散射强度△Ⅰ与氧氟沙星浓度成正比,据此提出了硫化镉-氧氟沙星-SDS体系测定氧氟沙星的新方法.方法的线性范围为4.0×...     

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.     

金纳米粒子作探针共振瑞利散射光谱法测定牛奶中三聚氰胺

在PBS缓冲体系中, 金纳米粒子与三聚氰胺形成粒径较大的聚集体, 导致共振瑞利散射(RRS)强度显著增强, 在一定条件下, 散射强度(ΔIRRS)与三聚氰胺浓度成正比, 由此建立了以金纳米粒子作光谱探针检测鲜牛奶中三聚氰胺的新方法. 在优化的实验条件下, 当三聚氰胺的浓度为3.3×10^－8～4.7×10^－7 mol/L时, 其线性关系为: ΔI _{RRS＝106.98C－28.279, R²＝0.9971, 检出限为2.7×10^－8 mol/L. 本方法金纳米粒子无需修饰, 在体系中仅加入一定量的单链寡聚核苷酸(T10), 实验表明该方法具有简便、快速、灵敏度高及选择性好等特点.}     

A Highly Sensitive Resonance Rayleigh Scattering Method for the Determination of Vitamin B1 with Gold Nanoparticles Probe

In weakly acidic buffer medium, vitamin B₁ (VB₁) interacts with gold nanoparticles to form a binding product, which resulted in a significant enhancement of resonance Rayleigh scattering (RRS) intensity and the appearance of a new RRS spectrum. The maximum RRS peak was at 368 nm, and there are three smaller scattering peaks that were at 284 nm, 440 nm and 495 nm, respectively. The enhanced RRS intensity (ΔI) was directly proportional to the concentration of VB₁ in the range of 0–2.8 × 10⁻⁷ mol L⁻¹. The method had high sensitivity and its detection limit (3σ) was 0.9 ng mL⁻¹. The optimum conditions and the influencing factors have been investigated. The method had good selectivity, which could be observed from the influence of coexisting substances. A sensitive, simple and fast RRS method for the determination of VB₁ with gold nanoparticle probe has been developed. In addition, the reasons for RRS enhancement were discussed.     

Resonance Rayleigh scattering spectra for studying the interaction of aminoglycoside antibiotics with pontamine sky blue and their analytical applications

In a weakly acid medium, some aminoglycoside antibiotics, such as kanamycin (KANA), gentamicin (GEN), tobramycin (TOB), and neomycin (NEO), or acid bisazo dye pontamine sky blue (PSB) can only produce very weak resonance Rayleigh scattering (RRS) signals. However, when the two agents react with each other to form the ion association complexes, the RRS intensity can be enhanced greatly and a new RRS spectrum and a significant enhancement of the RRS intensity in the wavelength range 350-600 nm can be observed. The maximum scattering peak is at 580 nm. There is a linear relationship between the RRS intensity and the antibiotic concentration in the range 0.01-6.0 microg mL(-1) at 580 nm. This RRS method has therefore been developed for the determination of trace levels of aminoglycoside antibiotics. The detection limits (3 sigma) of the four antibiotics, whose order of sensitivity is KANA>NEO>TOB>GEN, are 5.8-6.9 ng mL(-1). This method has a good selectivity and has been successfully applied to the quick determination of antibiotics not only for injections and ear drops, but clinic serum samples as well. In addition, quantum chemistry-based analysis of the reaction mechanism, the factors influencing the RRS spectra, and the reasons for the enhancement of RRS are discussed.     

A study on the sizes and concentrations of gold nanoparticles by spectra of absorption, resonance Rayleigh scattering and resonance non-linear scattering

Liquid phase gold nanoparticles with different diameters and colors can be prepared using sodium citrate reduction method by controlling the amounts of sodium citrate. The mean diameters of gold nanoparticles are measured by transmission electron microscope (TEM). Gold nanoparticles with different sizes have specific absorption spectra. When the diameters of nanoparticles is between 12 and 41 nm, the maximum absorption peaks locate at 520-530 nm and there are red shifts gradually with the increase of diameters of gold nanoparticles. And when the size of gold nanoparticle is constant, the absorbance is proportional to the concentration of gold. Obvious resonance Rayleigh scattering (RRS) and the resonance non-linear scattering such as second-order scattering (SOS) and frequency-doubling scattering (FDS) appear at the same time as well, and the maximum scattering peaks are located at 286 nm (RRS), 480 nm (SOS) and 310 nm (FDS), respectively. When the concentration of gold is constant, absorbance and the intensities of RRS, SOS and FDS (I(RRS), I(SOS) and I(FDS)) have linear relationships with the diameters of gold nanoparticles. When the diameter of gold nanoparticle is constant, the absorbance and I(RRS), I(SOS), I(FDS) are directly proportional to the concentrations of gold nanoparticles. Therefore, it is very useful for studying the liquid phase gold nanoparticles by investigating the absorption, RRS, SOS and FDS spectra.     

十二烷基苯磺酸钠-硫酸耐而蓝体系的共振瑞利散射光谱及其分析应用

提出了共振瑞利散射法(RRS)测定十二烷基苯磺酸钠(SDBS)的新方法。在pH为1.98～3.29的B-R缓冲溶液中,硫酸耐而蓝与SDBS结合生成离子缔合物,使溶液共振瑞利散射(RRS)增强,其最大散射峰位于760 nm,另在533 nm、400 nm有两个较弱的散射峰。SDBS的浓度在0.04～1.6 mg/L范围内,与RRS强度有良好的线性关系,对SDBS的检出限(3σ)达0.018 mg/L。研究了适宜的反应条件和影响因素,表明该方法灵敏、稳定。用于环境水样中阴离子表面活性剂含量的测定,回收率为95.9%～106.7%。     

Resonance Rayleigh scattering measurement of aminoglycoside antibiotics with Evans Blue.

In a weak acid medium, some aminoglycoside antibiotics, such as kanamycin (KANA), gentamicin (GEN), tobramycin (TOB) and neomycin (NEO), or acid bisazo dye Evans Blue (EB) can only produce very weak resonance Rayleigh scattering (RRS) signals. However, when two agents react with each other to form ion-association complexes, the RRS intensity can be greatly enhanced and a new RRS spectrum with a significant enhancement of the RRS intensity in the wavelength range from 350 nm to 600 nm can be observed. The maximum scattering peak is at 570 nm. There is a linear relationship between the RRS intensity and the antibiotic concentration in the range of 0.01-6.0 microg mL(-1) at 570 nm. This RRS method for the determination of aminoglycoside antibiotics at trace-amount levels has been developed. The detection limits (3sigma) of the four antibiotics, whose order of sensitivity from high to low ranks as KANA > NEO > TOB > GEN, are 5.2-6.9 ng mL(-1). This method has good selectivity and has been successfully applied to the quick determination of antibiotics not only for injections and ear drops, but for clinic serum samples as well. In addition, the reaction mechanism by using a quantum chemistry method and the influencing factors of the RRS spectra and the enhancement reasons of RRS have been discussed.     

Resonance Rayleigh-scattering method for the determination of vitamin B1 with methyl orange.

In a pH 2.3-3.0 acid medium, the resonance Rayleigh scattering (RRS) intensity is greatly enhanced when vitamin B, reacts with Methyl Orange to form an ion-association complex. The maximum RRS peak appears at 588 nm, another higher peak is at 403 nm and there are two smaller RRS peaks at 800 nm and 288 nm. The RRS intensity is directly proportional to the concentration of vitamin B, in the range of 0-400 ng ml(-1). The method has high sensitivity and the detection limit (3sigma) for vitamin B1 is 7.2 ng ml(-1). The effects of coexisting substances on the determination of vitamin B, were investigated, and the results show that this method has good selectivity and can be applied to the direct determination of vitamin B1 in composite vitamin B tablets and multivitamin tablet samples.     

Resonance Rayleigh scattering method for direct determination of polyacrylamide in water samples using basic phenothiazine dyes

Binding polyacrylamide (PAM) with some basic phenothiazine dyes such as methylene blue (MB), toluidine blue (TB) or Azure B (AB) etc. can result in a significant enhancement of resonance Rayleigh scattering (RRS). The maximum RRS wavelengths (λ_max) appear at 348, 340 and 342 nm for MB, TB, and AB systems, respectively. Accordingly, a new RRS method for the direct determination of PAM at nanogram levels has been established. The optimum conditions of these reactions, the influencing factors have been investigated. The RRS intensity is directly proportional to the concentration of PAM in the range of 0.040–5.0 μg/mL for three systems. The methods exhibit high sensitivities, and the detection limits are 15.9 ng/mL for MB system, 44.0 ng/mL for TB system, and 59.8 ng/mL for AB system. The selectivity of the method is investigated by using MB system owing to the highest sensitivity. Concentrations of PAM in tap water, synthetic water and practical waste water samples are determined satisfactorily. The reaction mechanism and RRS enhancement reasons are discussed.     

曲利本红与氨基糖苷类抗生素相互作用的共振瑞利散射光谱及其分析应用

在弱酸条件下，酸性双偶氮染料曲利本红（TR）或硫酸卡那霉（KANA）、硫酸 新霉素（NEO）、硫酸庆大霉素（GEN）和硫酸妥布霉素（TOB）等氨基糖苷类抗生 素的各自共振瑞利散射（RRS）十分微弱，但两者相互作用形成离子缔合物时能使 RRS急剧提高并产生新的RRS光谱，在400～535nm之间有一个强的散射带，最大散射 峰位于400nm处，在0.013～6.0μg·mL~(-1)范围内RRS强度与抗生素浓度成正比， 可用于氨基糖苷类抗生素的测定，对不同抗生素的检出限（3σ）在12.9～17.6ng ·mL~(-1)之间，其灵敏度的顺序是KANA＞NEO＞TOB＞GEN,方法有较好的选择性， 可用于市售抗生素注射液或滴耳液中药物含量和临床血药浓度的快速测定，中还用 量子化学方法对反应机理进行探讨，并讨论了的RRS光谱特性的影响因素和RRS增强 的原因。