管式磁微粒化学发光免疫分析法测定玉米样品中的黄曲霉毒素B1

开发了一种管式磁微粒化学发光免疫分析法测定玉米样品中黄曲霉毒素B1的方法,该方法使待测玉米样品中的黄曲霉毒素B1、辣根过氧化物酶标记的黄曲霉毒素B1与异硫氰酸荧光素(FITC)标记的黄曲霉毒素B1单克隆抗体在均相体系中发生竞争性免疫反应,再加入用抗FITC抗体包被的磁微粒作分离剂,抗原抗体复合物结合在磁微粒上,在磁场中经分离、洗涤后加发光底物,检测发光强度,测定玉米样品中黄曲霉毒素B1的含量.此方法标准曲线线性范围为0.05～5ng/mL,检测限为0.02ng/mL,批内相对标准偏差小于9%,批间相对标准偏差小于15%,具有良好的稳定性和重现性.     

量子点标记荧光免疫分析测定雌三醇

采用包被雌三醇完全抗原竞争免疫分析模式,以量子点标记羊抗兔抗体为荧光探针,建立了一种测定雌三醇的量子点标记的荧光免疫分析新方法.方法测定雌三醇的线性范围为0.01～10 000μg/L;检出限为0.007 5μg/L.此法用于尿液样品的分析,并利用高效液相色谱法进行对照,测定结果一致。     

组装型金磁微粒的制备及其在免疫学检测中的应用

以化学共沉淀和柠檬酸还原法分别合成纳米级Fe₃O₄和Au粒子, 将经3-巯丙基三乙氧基硅烷修饰形成的Fe3O4聚集体与纳米金粒子相互作用, 制备得到组装型Fe₃O₄/Au磁性复合微粒(简称金磁微粒), 并对其形成过程、形貌特征、磁学性质等进行表征. 此外, 对金磁微粒作为新型免疫学检测载体的特性包括抗体固定化、质量控制及其在免疫学检测中的应用开展研究. 结果表明: 组装型金磁微粒形状不规则、表面粗糙, 平均粒径约为2~3 μm; 具有超顺磁性, 比饱和磁化强度达41 A·m²/kg; 1 mg金磁微粒最多可固定人IgG的量为330 μg, 以含有500 ng人IgG的金磁微粒为一个检测单位, 与辣根过氧化物酶标记羊抗人IgG的每批5个重复特异性反应测定结果的相对标准偏差均小于6%, 5批特异性反应测定结果的批间相对标准偏差小于7%(以每批5次测定结果的平均值计算), 符合免疫学检测载体的质量要求; 将抗乙肝表面抗原单克隆抗体和抗白介素-8单克隆抗体分别固定于金磁微粒表面, 采用双抗体夹心法对乙肝表面抗原和白介素-8分别进行定性和定量检测, 结果表明金磁微粒是一种较好的免疫学检测载体.     

碲化镉纳米晶标记抗荧蒽抗体及其荧光免疫分析

以水热法合成的碲化镉(CdTe)纳米晶标记抗荧蒽抗体后,标记复合物的荧光强度增强,其分散性和稳定性良好。将此标记物用于直接竞争荧光免疫分析,测定了环境水样中荧蒽的含量。结果表明,在0.1～1000μg/L范围内有良好的线性关系;抑制率IC50为12.4μg/L,检出限IC20为13.1ng/L。对水样进行加标回收实验,回收率在95.1%～111%之间;相对标准偏差小于9%。本方法准确可靠,结果满意,能够满足环境中微量环境激素类污染物的检测需要。     

CE法测定CD45-FITC荧光抗体溶液中的游离FITC

建立了测定CD45-FITC荧光抗体样品溶液中游离FITC浓度的毛细管电泳(CE)方法。熔融石英毛细管45 cm(有效长度30 cm)×75μm i.d.;0.05 mol·L-1磷酸氢二钠-磷酸二氢钠缓冲液(含5g·L-1PEG4000,p H=7.14);分离电压+12 k V;进样压力0.5 psi(3.45 k Pa),进样时间3.0 s;分离温度25℃;UV-Vis检测器检测波长200 nm。该方法能有效测定CD45-FITC荧光抗体样品溶液中游离的FITC含量,线性回归方程相关系数r=0.9900,检测限LOQ=0.20μg·m L-1。样品加标回收率为105.49%,相对标准偏差小于5.36%。该方法快速、灵敏、重现性好,能用于CD45-FITC荧光抗体样品溶液中游离FITC的快速测定。     

磁敏传感器竞争免疫法检测牛奶中的氯霉素残留量

利用直接竞争免疫原理和巨磁致电阻效应,建立了磁敏生物传感器检测氯霉素的方法。制备氯霉素半抗原芯片,依次加入待测样品、生物素化抗体、链霉亲和素磁颗粒偶联物,使之发生竞争免疫反应,再利用传感器检测芯片上结合的磁颗粒数目。通过对检测条件的优化,建立了氯霉素浓度与磁颗粒数目的标准工作曲线。本方法的检测范围为0.05～100.0μg/L;检出限为50 ng/L;用于牛奶检测,回收率为95.97%～99.36%;批内相对标准偏差为0.8%～3.9%,批间相对标准偏差为1.1%～1.7%;与ELISA方法的一致相关系数达到0.98。本方法可在30 min内快速完成定量检测,为快速多靶标磁敏竞争免疫检测体系的建立提供了可行性。     

毛细管电泳-激光诱导荧光检测肌腱和肌腱细胞中的羟脯氨酸

建立毛细管电泳-激光诱导荧光检测(CE-LIF)分析羟脯氨酸的方法。肌腱和肌腱细胞中的胶原蛋白碱水解生成氨基酸,经异硫氰酸荧光素(FITC)衍生,采用LIF-CE分离测定胶原蛋白特异性氨基酸-羟脯氨酸。羟脯氨酸在0.5μg/L~8×103μg/L浓度范围内线性关系良好;检出限为0.5μg/L。相对迁移率和相对峰高的相对标准偏差(RSD)分别为5.0%和6.1%。测定了60份肌腱和9份细胞样品,加标回收率为95%~110%。将所建立的毛细管电泳方法与高效液相色谱法(HPLC)进行比较,两者测定结果相对误差为-1.9%~2.0%。本法仅需一次荧光标记,操作简单、快速灵敏,12min内完成一个分析周期,适于测定肌腱和细胞样品。     

人血清中雌三醇的磁性微粒子放射免疫分析法研究

在传统的放射免疫分析的基础上,以磁性微粒子为二抗分离剂和固相一抗为结合反应剂,建立了两种快速、超灵敏、简便的血清及其它样品中雌三醇含量的分析方法。雌三醇测定的曲线范围0.3~30μg/L;磁性微粒子二抗分离法批内和批间相对标准偏差分别为4.3%和8.7%;回收率为104%~114%;健全性为0.9989。磁性微粒子固相一抗法批内和批间相对标准偏差分别为4.4%和7.6%;回收率为96%~115%;健全性为0.9986。两种方法相比,磁性微粒子固相一抗法具有更为简便、快捷的优点。两种磁性微粒子的放射免疫分析不仅缩短了反应时间,其准确性和精密度也均满足临床及环境研究中的检验要求,且灵敏度较现有方法提高了一个数量级。     

基于金磁微粒与酶标噬菌体抗体的磁分离免疫分析法

基于金磁微粒(Gold-magnetic particle)兼有纳米金颗粒与磁微粒特性的优势,以相思子毒素(Abrin)为目标物,将蛋白A(SPA)包被金磁微粒偶联多抗作为功能化捕获探针,酶标噬菌体抗体作为特异信号检测探针,建立了一种检测相思子毒素的磁分离免疫分析法。该方法的线性范围为0.008~250μg/L,相关系数(r)为0.991 0,检出限为0.008μg/L,定量下限为0.008μg/L。该方法将蛋白A-金磁微粒功能化探针与酶标噬菌体抗体探针的优势结合,提高了检测灵敏度、特异性和抗干扰能力,适用于各种环境样品中微量相思子毒素样品的分析。     

亲水作用色谱-串联质谱测定尿液中尼古丁和可替宁

建立了测定人尿液中尼古丁和可替宁含量的亲水作用色谱-串联质谱(HILIC-MS/MS)方法。尿样加入尼古丁-d4和可替宁-d3同位素内标后,用水稀释10倍,经过滤后的滤液由超高效液相色谱-串联质谱(UPLC-MS/MS)进行分离分析。采用ACQUITY UPLC~BEH HILIC色谱柱(50 mm×3.0 mm,1.7μm),以甲醇和体积分数为0.1%的氨水为流动相,流速为0.2 mL/min,在电喷雾电离源正离子模式下测定尿液中尼古丁和可替宁的含量,用标准曲线法定量。尼古丁和可替宁在1.0~1 000μg/L范围内线性关系良好,相关系数分别为0.994 9和0.995 8;检出限分别为0.082μg/L和0.077μg/L;定量限分别为0.27μg/L和0.26μg/L;加标回收率分别为90.4%~103.5%和93.0%~104.6%;相对标准偏差分别为4.80%~6.21%和4.22%~7.15%。应用所建立的方法测定了200份尿样,结果表明,吸烟人群尿中尼古丁含量为26.68~854.30μg/L,可替宁含量为36.66~1 191.18μg/L(n=86,M_(nicotine)=76.00μg/L,M_(nicotine)=83.52μg/L,M为中位数);非吸烟人群尿中尼古丁含量为5.08~69.66μg/L,可替宁含量为3.16~28.21μg/L(n=114,Mnicotine=7.53μg/L,M_(nicotine)=3.79μg/L)。该方法快速灵敏,操作简单,适用于尿样中尼古丁和可替宁的批量测定,能满足烟草暴露评价的需要。     

Microchip electrophoresis coupled with on-line magnetic separation and chemiluminescence detection for multiplexed immunoassay

A facile and universal strategy for multiplexed immunoassay is proposed. The strategy is based on microchip electrophoresis (MCE) coupled with on-line magnetic separation and chemiluminescence (CL) detection. The system consisted of a microchip, an electromagnet, and a photomultiplier. The realization of multiplexed immunoassay protocol involves sampling magnetic nanoparticles (MNPs) labeled antibodies, N-(4-aminobutyl)-N-ethyl-isoluminol (ABEI) labeled antigens and free antigens in the precolumn reactor, on-line immunoreaction, capturing the MNPs-immunocomplexes, and the separation of unconjugated ABEI-labeled antigens. After on-line magnetic separation, the free ABEI-labeled antigens were transported into the separation channel, and mixed with hydrogen peroxide (H(2) O(2) ) in the presence of horseradish peroxidase in the postcolumn reactor, and producing CL emission. Using this arrangement, multiple analytes could be measured simultaneously by performing the technical operations for a single assay. As a proof-of-concept, the multiplexed immunoassay was evaluated for the simultaneous determination of five model analytes (i.e. hydrocortisone, corticosterone, digoxin, testosterone, and estriol). The results exhibited excellent precision and sensitivity, the relative standard deviations for nine times detection were lower than 4.7% for all the five components, and the detection limits of five analytes were in the range of 3.6-4.9 nM. The MCE system was validated using two human serum-based control samples containing five analytes.     

Novel method for evaluation of chemicals based on ligand-dependent recruitment of GFP labeled coactivator to estrogen receptor displayed on bacterial magnetic particles

We established a novel method to evaluate endocrine disrupting chemicals (EDCs) by assembling the estrogen receptor-ligand binding domain (ERLBD) and GFP labeled coactivator on magnetic nanoparticles. EDC can promote or inhibit coactivator recruitment to the ligand-ERLBD complex. ERLBD was displayed on the surface of nano-sized bacterial magnetic particles (BacMPs) produced by the magnetic bacterium, Magnetospirillum magneticum AMB-1. Our method resulted in 38 molecules of ERLBD molecules on a BacMPs with diameter of 75 nm. Furthermore, ligand-dependent recruitment assays of GFP labeled coactivator to ERLBD-BacMPs was performed by measuring the fluorescence intensity. 17β-estradiol (E2), estriol, diethylstilbestrol, zeralenone (full agonist), octylphenol (partial agonist) and ICI 182,780 (antagonist) were evaluated by this method. Full agonists tested showed increased fluorescence with increasing agonist concentration. Octylphenol had lower fluorescence intensity than E2. ICI 182,780 did not produce any fluorescence. The method developed in this study can evaluate the estrogenic potential of chemicals by discriminating whether they are an ER full agonist, partial agonist, or antagonist. Finally, this method is amenable adaptation into a high throughput format by using automated magnetic separation.     

Assay for urinary estriol during the menstrual cycle based on extraction by a graphitized carbon black cartridge followed by high-performance liquid chromatography

Summary A high-performance liquid chromatography (HPLC) assay for estriol in nonpregnancy urine is described. After Enzymic hydrolysis, the estriol is extracted from urine by the sorbent trap technique utilizing graphitized carbon black (Carbopack B). After some washing steps, estriol is desorbed by a suitable solvent system. After solvent removal, the sample is injected into an HPLC column for estriol quantification. Analytical recovery of estriol was 96.1%. The precision of the method was 2.6 and 4.9% respectively at 145 and 10.6ng/ml of urine. The limit of sensitivity was set at 0.8 ng/ml of urine. The mean contents of estriol in the follicular and luteal phases were respectively 11.3 and 38.8 ng/ml of urine.Dedicated to Prof. Dr. A. Liberti on the occasion of his 70th birthday.     

Preparation of multi-walled carbon nanotubes functionalized magnetic particles by sol-gel technology and its application in extraction of estrogens

Magnetic silica particles coated with hydroxy-terminated multi-walled carbon nanotubes (MWCNTs-OH) were prepared by sol-gel technology, characterized and used for the convenient, rapid and efficient extraction of several estrogens (including diethylstilbestrol, estrone and estriol) in water followed by sweeping micellar electrokinetic chromatography analysis with UV detection. The results demonstrated that sol-gel technology was a feasible, simple and effective technique for the preparation of MWCNTs-OH functionalized magnetic silica particles. The factors affecting the extraction efficiency of estrogens (the pre-activation of magnetic particles, adsorption time, desorption time and the amount of elution solvent) were carefully investigated. The extraction efficiencies for diethylstilbestrol, estrone and estriol were 95.9%, 93.9%, and 52.4%, respectively, under the optimum conditions. The method detection limits for the three estrogens were less than 0.2 ng mL⁻¹. The developed method was applied for the analysis of tap water, mineral water, Pearl River water and honey.     

Analysis of estrogens in water by magnetic octadecylsilane particles extraction and sweeping micellar electrokinetic chromatography

A method based on magnetic separation was developed for the extraction of several estrogens (including diethylstilbestrol, estrone and estriol) in water followed by sweeping micellar electrokinetic chromatography (MEKC) analysis with UV detection. Novel magnetic octadecylsilane (ODS) particles were prepared using a silanization method with octadecyl trimethoxysilane as the surface modification reagent of magnetic Fe₃O₄ particles. Octadecyl trimethoxysilane was covalently immobilized on the magnetic iron oxide particles. The particles were used as the sorbents in the magnetic separation for the extraction of trace amounts of estrogens from water. The extraction condition and efficiency of the particles for the estrogens were investigated. Combining the magnetic ODS particles extraction and sweeping MEKC with UV detection, the estrogens at concentrations as low as ng/mL in water can be detected without interference from other substances in the sample matrix.     

Automated direct high-performance liquid chromatographic assay for estetrol, estriol, cortisone and cortisol in serum and amniotic fluid.

An automated direct assay for the simultaneous determination of unconjugated estetrol, estriol, cortisone and cortisol in serum and amniotic fluid, using high-performance liquid chromatography with electrochemical detection and ultraviolet detection, has been developed. The analysis time is ca. 1 h. This system offers good reproducibility with low coefficients of variation (estetrol, 2.3%; estriol, 2.3%; cortisone, 2.6%; cortisol, 1.9%). Detection limits are low enough for routine determinations (estetrol and estriol, 150 pg; cortisone and cortisol, 5 ng). Comparison of the values measured by the present method and by radioimmunoassay revealed significant correlations for estetrol (r = 0.787, p less than 0.01), estriol (r = 0.957, p less than 0.01), cortisone (r = 0.956, p less than 0.01) and cortisol (r = 0.865, p less than 0.01). This system proved to be valuable in monitoring feto-placental function.     

表面活性剂存在下雌激素的直接电化学分析

雌二醇（E2）、雌三醇（E3）和雌酮（E1）是人体内3种重要的雌激素,它们在妇女的生殖生育方面发挥重要的作用。人体雌激素缺乏或过乘会导致诸多疾病。雌激素的检测方法已有不少报道,如气相色谱－质谱（GC－MS）、液相色谱（LC）以及化学发光免疫法等。E2,E1和E3的结构相似,且均具有疏水性及非电活性,用电化学直接测定十分困难,一般只能间接测定。本文报道了一种新的电化学分析方法。该方法对三种雌激素有十分灵敏的伏安响应,可用于微量测定。     

Flow Injection Chemiluminescence for the Determination of Estriol via a Noncompetitive Enzyme Immunoassay

A novel approach to the detection of estriol using a flow injection system coupled to enhanced chemiluminescent immunoassay was developed based on noncompetitive immunoassay formats. A conjugated estriol-ovalbumin immobilized immunoaffinity column was inserted into the flow system to trap the unbound horseradish peroxidase (HRP)-labeled antibody after an off-line incubation of estriol and HRP-labeled anti-estriol antibody. The trapped enzyme conjugate was detected by the injection of chemiluminescent substrates to produce enhanced chemiluminescence. The linear range for the determination of estriol is 10.0 to 400 ng · mL⁻¹ with a correlation coefficient of 0.996 and a detection limit of 5.0 ng · mL⁻¹. The total time for sampling and chemiluminescent detection of one sample is 400 seconds after 30 min of pre-incubation. The results for pregnancy serum samples obtained by this method are in good agreement with those obtained using ELISA.     

Preparative continuous separation of biological particles by means of free-flow magnetophoresis in a free-flow electrophoresis chamber.

For sorting, cells or cellular components can specifically be labeled by antibody-coated magnetic beads. We have developed a device for continuous magnetic sorting based on the flow-chamber of a free-flow electrophoresis system. Magnetically labeled particles are injected into a given continuously flowing chamber buffer and pass an inhomogeneous magnetic field, configurated perpendicular to the flow direction. According to its magnetic moment, the magnetic material is deviated into the direction of the magnetic forces, while nonmagnetic material passes the field without interaction. The magnetic forces can be changed with the electrical current of the solenoids producing the magnetic field. As in the free-flow electrophoresis system, the particle fractions are collected in different vials. On-line control of the experiments can be performed by an optical scanning system. Experiments with model particles achieved a sorting purity of more than 99% at a rate of up to 5 X 10(8) particles per hour. In experiments with blood cells, a high enrichment of either B-or-T-lymphocytes was obtained. In contrast to free-flow electrophoresis, there is no limitation, in principle, regarding the type of chamber buffer to be used. This allows an optimal adaptation of the buffer conditions to the requirements of vital sorting. The preliminary results so far confirm this conclusion.     

Concentration-Dependent Sedimentation of Stable Magnetic Dispersions

The concentration dependence of the sedimentation coefficient has been studied theoretically for a stable magnetic colloidal system under the influence of an external homogeneous magnetic field. The physical model of the magnetic colloid given by Donselaar et al. (1997, Langmuir 13, 6018) was adopted. It was found that the magnetic interaction accelerated the sedimentation of the particles. The stronger the external magnetic field is, the quicker the sedimentation of the particles. For sterically stabilized particles frequently used in experiments to simulate hard spheres, the combined influence of the magnetic attraction and van der Waals attraction on the sedimentation is also analyzed. Copyright 1999 Academic Press.