基于金银合金薄膜的波长检测型表面等离子体共振传感器

从实验和理论两方面详细研究了金银合金膜表面等离子体共振(SPR)传感器在可见光波段的敏感特性.实验方面,通过在玻璃基底上溅射50 nm厚的金银合金薄膜制备了一种新型的SPR传感芯片,并且自行搭建了基于Kretschmann结构的波长检测型SPR传感器测试平台.利用不同浓度的氯化钠(NaCl)水溶液和浓度为10μmol·L-1的牛血清蛋白(BSA)水溶液分别作为折射率样品和分子吸附样品,研究了传感器的折射率灵敏度和吸附灵敏度,并与金膜和银膜SPR传感器进行了对比研究.结果表明,对于折射率灵敏度的测试,金银合金膜SPR传感器大幅高于金膜SPR传感器,略低于银膜SPR传感器;而对于吸附敏感的研究,金银合金膜SPR传感器的灵敏度与银膜SPR传感器相近,是金膜SPR传感器的3倍.理论方面,利用菲涅尔公式和等效折射率计算公式仿真计算了这三种薄膜结构的SPR传感器的灵敏度和精确度,结果指出金银合金膜SPR传感器的灵敏度与银膜SPR传感器接近,是常规金膜SPR传感器的2.31倍,而半高峰宽仅为金膜和银膜SPR传感器的1.36倍.在稳定性方面,金银合金膜SPR传感器与金膜SPR传感器均具有良好的化学稳定性,而银膜SPR传感器较易氧化,使用寿命低,不常被采用.综上,金银合金膜在改善传感器灵敏度的同时,不会降低精度,是一种高灵敏、低成本、良好稳定性的SPR传感器敏感材料.     

基于金银合金薄膜的波长检测型表面等离子体共振传感器

从实验和理论两方面详细研究了金银合金膜表面等离子体共振（SPR）传感器在可见光波段的敏感特性. 实验方面,通过在玻璃基底上溅射50 nm厚的金银合金薄膜制备了一种新型的SPR传感芯片,并且自行搭建了基于Kretschmann 结构的波长检测型SPR传感器测试平台. 利用不同浓度的氯化钠（NaCl）水溶液和浓度为10 μmol·L^-1的牛血清蛋白（BSA）水溶液分别作为折射率样品和分子吸附样品,研究了传感器的折射率灵敏度和吸附灵敏度,并与金膜和银膜SPR传感器进行了对比研究. 结果表明,对于折射率灵敏度的测试,金银合金膜SPR传感器大幅高于金膜SPR传感器,略低于银膜SPR传感器;而对于吸附敏感的研究,金银合金膜SPR传感器的灵敏度与银膜SPR传感器相近,是金膜SPR传感器的3倍. 理论方面,利用菲涅尔公式和等效折射率计算公式仿真计算了这三种薄膜结构的SPR传感器的灵敏度和精确度,结果指出金银合金膜SPR传感器的灵敏度与银膜SPR传感器接近,是常规金膜SPR传感器的2.31倍,而半高峰宽仅为金膜和银膜SPR传感器的1.36 倍. 在稳定性方面,金银合金膜SPR传感器与金膜SPR传感器均具有良好的化学稳定性,而银膜SPR传感器较易氧化,使用寿命低,不常被采用. 综上,金银合金膜在改善传感器灵敏度的同时,不会降低精度,是一种高灵敏、低成本、良好稳定性的SPR传感器敏感材料.     

表面等离子体共振传感技术和生物分析仪

表面等离子体共振(surface plasmon resonance,SPR)传感技术是生物化学分析领域常用的分析手段和研究工具,与其相关的研究不计其数,发展日新月异。本研究小组从事SPR传感技术研究近十年,从初期的理论研究、仿真计算、传感器设计以及全自动SPR生物分析仪开发与应用研究,到目前的传感器性能提高、应用拓展,时刻关注着该项技术的最新动态。本文系统综述了SPR传感技术和生物分析仪的原理、结构以及主要功能模块,SPR传感器的调制类型、耦合方式以及SPR成像传感器;介绍了结合局域表面等离子体共振(local surface plasmon resonance,LSPR)技术、改进金属膜系设计、优化数据处理算法等提高SPR生物分析仪性能的方法;阐述了SPR传感技术和生物分析仪的最新进展,包括SPR技术和微流控芯片、电化学技术、表面增强拉曼散射技术(SERS)的联用;列举了SPR生物分析仪在临床诊断、药物筛选、生物分子研究、食品安全和环境监测等领域的应用实例;最后,分析了SPR生物分析仪面临的主要问题以及未来的发展趋势。     

表面等离子体共振免疫传感器在蛋白质检测中的应用及其研究进展

表面等离子体共振(SPR)技术是20世纪90年代发展起来的一种新型技术,应用SPR原理可检测生物传感芯片上配位体与分析物之间的相互作用情况,在生命科学、医疗检测、药物筛选、食品检测及环境监测等领域具有广泛的应用需求.SPR技术可与免疫传感器结合,利用抗原抗体的特异性反应可用于各种蛋白质抗原的检测.本文重点总结了SPR免疫传感器在食品及医疗领域蛋白质检测的应用,综述了近年来SPR免疫传感技术在这该领域的研究热点及进展.     

光纤SPR传感器的结构、膜材与应用进展

光纤表面等离子共振(Fiber optic surface plasmon resonance,FO-SPR)传感器由于体积小、易携带、抗电磁干扰等优点在生物、化学、医学及食品领域均具有广阔的应用前景。该文综述了光纤SPR传感器的结构、膜材料及其应用进展。其中终端反射式和在线传输式是光纤SPR传感器最重要的两种结构;最常用的膜材料包括金膜、银膜、复合膜和金属纳米颗粒。基于光纤SPR的实时检测、抗干扰能力强、可多通道检测等特点展望了其未来发展与应用前景。     

基于色相算法的表面等离子体共振成像传感器对苯并芘的敏感特性

报道了一种用于原位探测水中苯并芘的彩色表面等离子体共振成像(SPRI)传感器,该传感器既能提供直观的图像信息,又能借助色相算法定量分析待测物质的浓度及其吸附/脱附过程。首先利用自制的波长-图像同步检测型SPR传感器测试了裸金薄膜芯片在不同入射角下的共振波长和共振图像,然后利用色相算法建立了SPR共振波长与图像色相的依赖关系,基于该依赖关系获得了SPR传感器最佳色相灵敏度对应的起始共振波长约为650 nm;另一方面,制备了聚四氟乙烯涂覆的SPR传感芯片,基于聚四氟乙烯膜对水中苯并芘的可逆富集作用实现了苯并芘的原位快速探测。实验取得以下4个结果:(1)在20-100 nmol?L-1浓度范围内彩色SPR图像的平均色相值随着苯并芘浓度的升高线性减小;(2)对100 nmol?L-1的苯并芘的响应和恢复时间分别约为7和5 s;(3)由于聚四氟乙烯膜的厚度大于SPR消逝场穿透深度,检测结果不受溶液折射率影响;(4)在聚四氟乙烯敏感膜厚度较小且不均匀的情况下,传感器容许获取敏感膜的不同厚度区域对苯并芘的色相灵敏度。实验结果有力地证明了这种彩色SPR图像传感器在生化物质检测中具有良好的应用前景。     

表面等离子体子共振生物传感器用于乙肝表面抗原的测定

运用自行研制的表面等离子体子共振（SPR）生物传感器，采用自组装成膜技 术并以戊二醛作偶联剂，在传感片表面修饰HBsAg单克隆抗体，将其用于乙肝表面 抗原（HBsAg)的检测。实验结果表明SPR生物传感器对HBsAg的检出限为0.06ng/mL 。与传统的酶联免疫吸附试验（ELISA）相比，SPR生物传感器的检出灵敏度明显高 于ELISA法。用该SPR生物传感器对HBsAg质控血清与纯化的HBsAg溶液进行比较检测 ，结果表明该SPR生物传感器对HBsAg具有好的特异选择性。     

微流控芯片在表面等离子体共振生物传感器中的应用

作为众所周知的生物传感器技术,表面等离子体共振（SurfacePlasmonResonance,SPR）正在被越来越普遍地用于实现各种生物化学检测方法,特别是用途广泛的固相表面生物检测（Sol—id—PhaseBioassay）。SPR对样品进行非标记检测,能够用于测量生物化学反应全过程的反应动力学。为了提高SPR的检测效率,通常将微流控技术（Microfluidics）与SPR相结合,即在SPR生物传感器中使用微流控芯片（MicrofluidicChip）作为反应装置。基于微型化带来的优势,使用微流控芯片作为反应装置可以有效地缩短生物化学检测方法的反应时间,并减少样品消耗。微流控芯片还可以平行排布相同的结构单元,提高SPR生物传感器的检测通量。因此,使用微流控芯片作为反应装置是SPR生物传感器,特别是商品化的SPR生物传感器的发展趋势。     

反射式光纤银膜SPR传感器的湿法构建及应用

采用银镜反应湿法制备了反射式光纤表面等离子体共振(Surface plasmon resonance,SPR)传感器,并结合多巴胺自聚合功能对光纤表面银膜进行快速生物功能化修饰,实现了抗体抗原相互结合的在线监测。通过自行搭建SPR仪器,考察了传感区长度的影响,跟踪测定了传感器各个修饰步骤后SPR信号的变化。测试结果表明,该法制备的光纤SPR传感器具有很高的灵敏度。随着传感区长度的增加,基于SPR峰位的检测灵敏度随之增大,而基于SPR峰强的检测灵敏度无明显变化。当传感区长度为1.5 cm时,基于SPR峰位对蔗糖溶液折射率的检测灵敏度为4 166 nm/RIU,而基于SPR峰强的检测灵敏度为99%/RIU。进一步利用该传感器监测了Ig G的连接过程、Ig G抗体-抗原的相互结合过程,结果显示其可应用于生物传感检测领域。     

基于金属纳米粒子增敏的SPR生物传感器检测吲哚乙酸

本实验建立了表面等离子体共振(SPR)生物传感器检测3-吲哚乙酸(IAA)的方法。制备了两种SPR生物传感器检测IAA:传统模式的SPR生物传感器1和Au/Ag合金纳米粒子增敏的SPR生物传感器2。结果发现:传感器1在IAA浓度范围为175~350μg/L时,浓度与其波数位移值呈线性关系,检出限为25μg/L(S/N=3);传感器2在IAA浓度范围为17.5~250μg/L时,浓度与其波数位移值呈线性关系,检出限为2.2μg/L(S/N=3)。说明基于Au/Ag合金纳米粒子的传感器2比传感器1有较高的灵敏度和较低的检出限。加标回收实验测得加标回收率范围为96%~100.2%,平均值为98.4%。本实验制备的SPR生物传感器具有较好的精密度、稳定性、重现性和特异性。     

Present and future of surface plasmon resonance biosensors

Surface plasmon resonance (SPR) biosensors are optical sensors exploiting special electromagnetic waves—surface plasmon-polaritons—to probe interactions between an analyte in solution and a biomolecular recognition element immobilized on the SPR sensor surface. Major application areas include detection of biological analytes and analysis of biomolecular interactions where SPR biosensors provide benefits of label-free real-time analytical technology. This paper reviews fundamentals of SPR affinity biosensors and discusses recent advances in development and applications of SPR biosensors.     

Single-crystal sapphire-fiber optic sensors based on surface plasmon resonance spectroscopy for in situ monitoring

Single-crystal sapphire-fiber optic sensors based on surface plasmon resonance (SPR) for refractive index (RI) measurements of aqueous and hydrothermal water solutions are described. Accurate measurement of RIs is essential to efficient operation and control of broad range of engineering processes. Some of these processes are carried out with harsh environments, such as high-temperature, high pressure, and chemical corrosion. These extreme physical conditions are proving a limiting factor in application of the conventional silica-based optical sensors. Single-crystal sapphire is an ideal material for sensor applications, where reliable performance is required in the extreme environment conditions. With regard to the liquid species detection, most applications of SPR sensors are designed to function near the refractive index of water (1.3330 RI). The RI changes of aqueous solution can be easily monitored by silica-fiber (RI, 1.4601 at 550 nm) based SPR sensor. However, the sapphire waveguide has a prohibitively high RI (1.7708 at 546 nm) for unmodified monitoring of the RI changes of aqueous solutions. For that purpose, a practical SPR probe geometry has been applied to the ability to tune the SPR coupling wavelength/angle pair with sapphire-fiber based SPR probe.     

Fiber-optic surface plasmon resonance for vapor phase analyses

Fiber-optic sensors based on surface plasmon resonance (SPR) for direct refractive index (RI) measurements of samples with the RI between 1.00 and 1.30 are described. Most applications of SPR sensors are designed to function near the refractive index of water (1.3330 RI). The RI changes of aqueous solution (RI, ca. 1.34) can easily be monitored by silica-fiber (RI, 1.4601 at 550 nm) based SPR sensor. With regard to gas species detection, the fiber-optic SPR sensor must be modified for sensitivity to changes in refractive index near 1.0008 (i.e., RI of air). However, the silica waveguide has a prohibitively high RI for unmodified monitoring of the RI changes of gas. The silica-fiber based SPR probe design presented here is based upon the modification of the probe geometry to the ability to tune the SPR coupling wavelength/angle pair. In this study, the tapered silica-based fiber SPR sensors are shown to directly determine the RI changes of gas species and the density change of dry air.     

Analysis of immunoarrays using a gold grating-based dual mode surface plasmon-coupled emission (SPCE) sensor chip

We have developed a novel dual mode immunoassay platform that combines the advantages of real-time, label free measurement of surface plasmon resonance (SPR) and the highly directional surface plasmon-coupled emission (SPCE) using a gold grating-based sensor chip. Since only fluorophore-labeled analyte molecules that are close to the metal surface of the sensor chip will couple to the surface plasmon, SPCE detection is highly surface-specific leading to background suppression and increased sensitivity. Theoretical calculations were done to find SPR and SPCE angles for a sensor chip optimized for Alexa Fluor 647. We have confirmed the SPR and SPCE responses on the dual mode sensor chip using Alexa Fluor 647 labeled anti-mouse IgG. Signal fluctuation of the dual mode sensor chip reader was below 1.2% and 0.8% for SPR and SPCE, respectively. The SPR response in this configuration showed a minimum detection level of 1 μg ml(-1), and the SPCE response showed a minimum detection level of 1 ng ml(-1) for the same sample. A range of human IgG concentrations in human serum was also analyzed with the dual mode sensor chip. The SPCE measurement is more sensitive than the SPR real-time measurement, and substantially extends the dynamic range of the assay platform, as well as enabling independent measurements of co-localized analytes on the same sensor chip region of interest. Since this assay platform is capable of measuring more than 1000 spatially encoded regions of interest on a 1 cm(2) sensor chip, it has the potential for high-content analyses of biological samples with both research and clinical applications.     

Investigation of a fiber optic surface plasmon spectroscopy in conjunction with conductivity as an in situ method for simultaneously monitoring changes in dissolved organic carbon and salinity in coastal waters

A combination surface plasmon resonance (SPR) and conductivity sensor array was developed and implemented to demonstrate the ability to differentiate among changes in dissolved organic carbon (DOC) and salinity in coastal water. The array is capable of achieving sufficient spatial and temporal data density to better understand the cycling and fate of terrestrial DOC in coastal areas. DOC is the second largest source of bioreactive carbon in the environment and plays a key role in mediating microbial activity and generation of atmospheric CO(2). In the coastal areas, the salinity is also an important property in many applications, such as leak detection for landfill liners, saltwater intrusion to drinking water, marine environment monitoring, and seasonal climate prediction. Conductivity sensors are the industry standard for determining salinity in ocean systems. However, both conductivity and refractive index sensors, such as SPR spectroscopy based sensors, respond to salinity and DOC levels. To demonstrate the capability of the SPR sensor and a conductivity sensor to collect complimentary data useful in discrimination of salinity and DOC in coastal zone water, conductivity, SPR, and temperature data were collected during passage from the Juan de Fuca ridge area returning to the University of Washington docks.     

A Surface Plasmon Resonance Sensor Platform Coupled with Gold Nanoparticle Probes for Unpurified Nucleic Acids Detection

In this work, a surface plasmon resonance sensor system was designed and implemented for determination of nucleic acids in unpurified samples. First, through blocking non-specific interaction sites on the sensor surface to reduce non-specific adsorption from unpurified sample matrix, it was determined that at the optimal BSA concentration of 100 µg/ml the non-specific interaction can be reduced by 50%, although improvement for direct detection of nucleic acids in unpurified sample is required. Second, bearing nonspecific adsorption onto gold films, nucleic acids adsorbed on sensor surface in unpurified sample matrix were detected through a secondary hybridization approach. Using DNA-lined AuNPs shows the new SPR sensor can be applied for the determination of target ssDNA with a detection range of 0.1–10 µM for targets in purified and 1–10 µM in unpurified samples, respectively. Results imply that the new SPR sensor system is promising for specific and convenient analysis of nucleic acids directly in unpurified samples. Development of the new SPR sensor technique can have applications in fast field diagnostics and monitoring.     

Surface plasmon resonance sensors for real-time detection of cyclic citrullinated peptide antibodies

Surface plasmon resonance (SPR) sensors have been used for detection of various biomolecules because of their simplicity, high specificity and sensitivity, real-time detection, low cost, and no requirement of labeling. Recently, molecularly imprinted polymers that are easy to prepare, less expensive, stable, have talent for molecular recognition and also are used for creation selective binding sites for target molecule on the SPR sensors. Here, we show that preparation of cyclic citrullinated peptide antibody (anti-CCP) imprinted SPR sensor to detect CCP antibodies. For this purpose, anti-CCP/AAm pre-complex was synthesized by interacting acrylamide (AAm) monomer with anti-CCP. Then, anti-CCP imprinted (anti-CCP/PAAm) SPR sensor was obtained by reacting with anti-CCP/AAm pre-complex in the presence of the crosslinker, and initiator/activator pair. Besides this, non-imprinted (PAAm) SPR sensor was also prepared without using anti-CCP template. The SPR sensors were characterized and then adsorption-desorption studies were performed with pH 7.0 phosphate buffer (10 mM) and acetic acid (10%) with Tween 20 (1%) in pH 7.0 phosphate buffer. Selectivitiy of sensors was investigated by using immunoglobulin M (IgM) and bovine serum albumin (BSA). To determine the adsorption model of interactions between anti-CCP solutions and anti-CCP/PAAm SPR sensor, different adsorption models were performed. The calculated maximum reflection, detection limit, association and dissociation constants were 1.079 RU/mL, 0.177 RU/mL, 0.589 RU/mL and 1.697 mL/RU, respectively. Repeatability experiments of anti-CCP/PAAm SPR sensor was performed four times with adsorption-desorption-regeneration cycles without any performance losing. Results showed that anti-CCP/PAAm SPR sensor had high selectivity and sensitivity for detection of CCP antibodies.     

A surface plasmon resonance immunosensor for detecting a dioxin precursor using a gold binding polypeptide

A surface plasmon resonance (SPR) based biosensor was developed for monitoring 2,4-dichlorophenol, a known dioxin precursor, using an indirect competitive immunoassay. The SPR sensor was fabricated by immobilizing a gold-thin layer on the surface of an SPR sensor chip with an anti-(2,4-dichlorophenol) antibody using a gold binding polypeptide (GBP) and protein G. The SPR response based on the antigen-antibody reaction in a flow system was measured by injecting a 2,4-dichlorophenol sample solution into the flow system in which the SPR sensor was located. In a direct immunoassay system using the modified sensor chip, no significant SPR angle shift less than 0.001° was observed when a 25 ppm of 2,4-dichlorophenol solution was injected. In order to improve the sensitivity of the SPR sensor, an indirect competitive immunoassay method was used in conjunction with the SPR sensor system using 2,4-dichlorophenol conjugated with bovine serum albumin (BSA). In the competitive assay, a 350 ppm 2,4-dichlorophenol-BSA conjugate solution containing 2,4-dichlorophenol at various concentrations (10-250 ppb) were injected into the SPR sensor system. The sensitivity of this indirect immunoassay was found to be extremely sensitive, compared to the direct one, and a detection limit of 20 ppb was estimated. Verification that the use of GBP for immobilizing the antibody on the sensor chip enhanced the sensitivity to 2,4-dichlorophenol was obtained by comparing the procedure with another modification, in which BSA was used instead of GBP for immobilizing the antibody on the sensor chip. The affinity constant of 2,4-dichlorophenol and its conjugate to the antibody were estimated form the SPR response.