SERS‐ and Electrochemically Active 3D Plasmonic Liquid Marbles for Molecular‐Level Spectroelectrochemical Investigation of Microliter Reactions

Liquid marbles are emergent microreactors owing to their isolated environment and the flexibility of materials used. Plasmonic liquid marbles (PLMs) are demonstrated as the smallest spectroelectrochemical microliter‐scale reactor for concurrent spectro‐ and electrochemical analyses. The three‐dimensional Ag shell of PLMs are exploited as a bifunctional surface‐enhanced Raman scattering (SERS) platform and working electrode for redox process modulation. The combination of SERS and electrochemistry (EC) capabilities enables in situ molecular read‐out of transient electrochemical species, and elucidate the potential‐dependent and multi‐step reaction dynamics. The 3D configuration of our PLM‐based EC‐SERS system exhibits 2‐fold and 10‐fold superior electrochemical and SERS performance than conventional 2D platforms. The rich molecular‐level electrochemical insights and excellent EC‐SERS capabilities offered by our 3D spectroelectrochemical system are pertinent in charge transfer processes.     

Plasmonic Liquid Marbles: A Miniature Substrate‐less SERS Platform for Quantitative and Multiplex Ultratrace Molecular Detection

Inspired by aphids, liquid marbles have been studied extensively and have found application as isolated microreactors, as micropumps, and in sensing. However, current liquid‐marble‐based sensing methodologies are limited to qualitative colorimetry‐based detection. Herein we describe the fabrication of a plasmonic liquid marble as a substrate‐less analytical platform which, when coupled with ultrasensitive SERS, enables simultaneous multiplex quantification and the identification of ultratrace analytes across separate phases. Our plasmonic liquid marble demonstrates excellent mechanical stability and is suitable for the quantitative examination of ultratrace analytes, with detection limits as low as 0.3 fmol, which corresponds to an analytical enhancement factor of 5×10⁸. The results of our simultaneous detection scheme based on plasmonic liquid marbles and an aqueous–solid–organic interface quantitatively tally with those found for the individual detection of methylene blue and coumarin.     

苯胺与邻-氨基苯磺酸电化学共聚的原位紫外-可见光谱研究

运用原位紫外-可见吸收光谱法和红外光谱法分别研究了苯胺(AN)和邻-氨基苯磺酸(ABSA)在0.1mol/L HCIO4溶液中的单独聚合及共聚过程.结果表明,在AN和ABSA的共聚过程中,ABSA首先被氧化生成其阳离子自由基,然后ABSA阳离子自由基与继而生成的AN阳离子自由基和溶液中的AN及ABSA单体发生交互反应,...     

红外伏吸法研究抗坏血酸在水溶液和离子液体1-乙基-3-甲基咪唑四氟硼酸盐中的电化学行为

采用电化学及红外伏吸法研究了抗坏血酸(AA)在水溶液和离子液体1-乙基-3-甲基咪唑(EMIMBF4)中的电化学行为.AA在EMIMBF4中与在水溶液中一样,不可逆氧化成脱氢抗坏血酸(DHAA).现场红外光谱结果表明,DHAA在水中迅速发生水解反应,而在EMIMBF4中则较稳定.在EMIMBF4中,AA的羰基峰出现在1739 cm-1处,DHAA的羰基峰出现在1785 cm-1处,它们相比于游离态的羰基发生了红移.原因可能是AA和DHAA与EMIMBF4间易形成氢键,或者是AA自身形成了氢键,DHAA以二聚体的形态存在.     

硝酸银及其产物银对六角相液晶流变性影响

用偏光显微镜测定了硝酸银及其产物银对NP－10／水六角相区的影响，用动态 （应力和频率扫描）和稳态（蠕变－恢复）方法研究了硝酸银的加入和银的生成对 该体系粘弹性的影响。无机前驱物硝酸银和银的生成能使六角相区略缩，动态流变 实验表明，无机物引入纯六角相液晶体系中会使其抗剪切的能力降低，对相区两侧 影响与振荡所采用的频率有关。生成的银原子会在胶束表面聚集，增加了胶束内部 不同EO链之间的交联，造成松弛时间变长，粘弹性指数降低，稳态实验所得到的结 果与动态实验一致，并将粘性和弹性定量化。用弹簧－粘壶模型和液晶的空间构型 及作用力解释了实验结果。     

液相色谱-串联质谱法检测干血点样本中25-羟基维生素D2和25-羟基维生素D3

建立了一种高通量液相色谱-串联质谱技术检测干血点(DBS)样本中25-羟基维生素D2[25(OH)D2]和25-羟基维生素D3[25(OH)D3]的方法.以DBS为样本,以4-苯基-1,2,4-三唑啉-3,5-二酮(PTAD)为试剂进行分析物衍生化,所需样本量仅约相当于6μL全血当量的DBS样本;使用甲醇直接超声提取分析物,避开了通常情况下DBS样本前处理中的全血复溶和蛋白质沉淀等繁琐步骤;整个前处理过程使用自动化液体处理平台实现自动化操作和高检测通量;以25(OH)D2-D6和25(OH)D3-D3为同位素内标,消除基质效应的影响.前处理后的样本进行LC-MS/MS分析,使用C18柱进行分离,流动相为甲醇(含5 mmol/L甲酸铵)-水(含5 mmol/L甲酸铵)(75:25,V/V),洗脱时间为4 min,使用多反应监测模式(MRM)定量.结果表明:25(OH)D2和25(OH)D3的检出限为0.12 ng/mL(S/N=3),定量限为0.94 ng/mL(S/N=10).25(OH)D2和25(OH)D3在0.94~120.00 ng/mL范围内线性关系良好,日内相对标准偏差(RSD)分别为1.4%~8.6%和3.7%~15.5%,日间RSD分别为4.0%~5.3%和3.8%~14.9%,平均回收率分别为91.7%±7.9%~108.5%±6.5%和94.8%±6.8%~101.3%±2.9%.DBS样本在不同温度(-20℃,22℃,37℃)下储存不同时间(0,1,2,3,5,7,14天)后的稳定性实验显示样本总体RSD°15%.以25(OH)D参考物质NIST SRM 972a中的Level 3制备标准DBS样本,25(OH)D2和25(OH)D3的回收率分别为110.3%和103.0%.     

Determination of Vitamin D3 Metabolites Using High‐Performance Liquid Chromatography or Immunoaffinity Chromatography

Our investigation of the analysis of vitamin D₃ metabolites has been reviewed. The development of high‐performance liquid chromatographic methods for the quantitative determination of 25‐hydroxyvitamin D₃ 3‐sulfate and 25‐hydroxyvitamin D₃, which are the major circulating metabolites of vitamin D₃ in human serum/plasma, has been described. The developed methods were applied to the determination of the correlation between the concentration of the sulfate and its genin in healthy subjects and patients with chronic renal failure. The development of immunoaffinity chromatography immobilizing the highly specific anti‐1,25‐dihydroxyvitamin D₃ antibody for the pretreatment of radioreceptor assay of 1,25‐dihydroxyvitamin D₃, which is the active metabolite of vitamin D₃, is also described.     

反相高效液相色谱法测定补钙保健品中的维生素D_3

用氯仿作提取剂直接提取补钙保健品中的维生素Ｄ３，提取液经浓缩后进行高效液相色谱分析，并对皂化和直接提取的样品中维生素Ｄ３的含量进行了比较。采用μ－ＢｏｎｄａｐａｋＣ１８作分离柱，甲醇－水（８７１３）作流动相，检测波长为２６４ｎｍ，回收率为９５．６３％。     

活性维生素D3类似物的合成及构效关系研究

1α,25-二羟基维生素D₃(1α,25-(OH)₂-D₃,125D)是维生素D中最具生理活性的代谢产物,但因高钙血症副反应而限制其临床应用。从对构效关系的研究出发,迄今已合成三千多种类似物。本文综述了近年来对某些A环修饰(C2位修饰、C3位修饰、芳香A环类似物、A环开环类似物)、侧链修饰、CD环修饰、seco-B环修饰和非开环甾体的活性维生素 D₃ 类似物的设计、合成以及构效关系的研究,旨在为新型较佳活性维生素D₃类似物的合成及临床开发提供参考。     

Mechanisms and Kinetics of Reactions of the O (1D,3p) + CF3Cl System

In the stratosphere, CF3Cl (CFC 13) can either photodecompose or react directly with atomic oxygen to generate ozone-depleting agents such as Cl and ClO in the gas phase[1-3]. Since the 1970s, attention has been focused on the effects of these compounds on the destruction of ozone in the stratosphere and on global warming[4,5].     

基于内嵌钴/氮掺杂多孔碳三维石墨烯笼的抗团聚高效氧还原电催化剂

氧还原反应是决定燃料电池、金属-空气电池等多种新型清洁能源存储与转化技术之性能与应用的关键反应. 铂及其合金是目前催化活性最好的氧还原反应催化剂,但其高昂的成本限制了规模化应用. 在小尺寸效应作用下,微纳米结构催化剂颗粒在电极制备与电化学反应过程中的团聚限制了催化剂本征催化活性的充分发挥. 本文基于喷雾热解技术,发展了一种基于内嵌钴/氮掺杂多孔碳三维石墨烯笼的高活性、抗团聚非贵金属氧还原反应催化剂. 此结构中,金属有机骨架化合物ZIF-67衍生的钴/氮掺杂多孔碳纳米结构是催化氧还原反应的活性中心,包覆其外的三维石墨烯笼不仅可在钴/氮掺杂碳纳米结构之间构建连续的三维载流子传导网络,且可高效抑制其在催化剂制备与电化学反应过程中的团聚与活性损失. 在碱性电解液中,此类非贵金属催化剂表现出可与铂基催化剂媲美的氧还原反应活性和优异的稳定性.     

A novel strategy for fabrication,activation and cleaning of fully 3D printed flexible planar electrochemical platforms

In recent years, 3D printing of carbon-based conductive filaments has received growing attention for assembling electrodes to be used in a wide variety of electroanalytical devices and applications. Despite the large amount of work present in literature concerning the development of three-dimensional (3D) conductive structures, its potential as dry deposition method for assembling two-dimensional (2D) electrodes to be used in planar configuration is still largely unexplored. In fact, the possibility to rapidly change the geometry of the electrochemical circuits, associated with the reduction of waste and the absence of solvents, which are instead important components of ink and paste formulations, makes this strategy a valid green and efficient alternative to other deposition approaches such as screen-printing technology. We report here a rapid and solvent-free method for assembling fully 3D printed flexible planar electroanalytical platforms (3DEPs) to be used with microliters of liquid. At the same time, a novel protocol for the surface pre-treatment of 3D printed electrodes based on ultrasonication in aqueous NaOH solution followed by electrochemical activation using the same medium, is presented. In addition, the same procedure has proved to be efficient for cleaning the electrode surface after electrochemical passivation, thus confirming the validity of both time-efficient and environmentally-friendly assembling and activation/cleaning procedures developed which allow efficient and reusable electrodes to be produced. Finally, 3DEPs were tested by a proof-of-concept quantification of a commonly used food dye (Brilliant Blue, E-133) in commercial solutions used for homemade food coloring.     

Synthesis of highly ordered AgNPs-coated silica photonic crystal beads for sensitive and reproducible 3D SERS substrates

3 D highly ordered silver nanoparticles(AgNPs) coated silica photonic crystal beads(Ag/SPCBs) were prepared and exploited as a novel surface enhanced Raman scattering(SERS) substrate.The monodisperse and size-controlled SPCBs were prepared via self-assembly of silica nanoparticles process using a simple microfluidic device.Then the Ag/SPCBs were easily obtained by in situ growth of AgNPs onto the NH₂-modified SPCBs.Field emitting scanning electron microscopy(SEM) and energy dispersive X-ray spectrometry(EDX) were used to characterize the Ag/SPCBs.The effect of silica nanoparticle size and AgNO₃ concentration on the SERS performance of the resultant Ag/SPCBs substrate were discussed in detail.The results indicate that the Ag/SPCBs have highest SERS signals when silica nanoparticle size is250 nm and AgNO₃ concentration is 0.8 mg/mL.Using malachite green(MG) as model analyte,the Ag/SPCBs substrate displayed a high sensitivity and a wide linear range for MG.The well-designed Ag/SPCBs show high uniformity and excellent reproducibility,and can be used as an effective SERS substrate for sensitive assay application.     

Preparation and characterization of polymer layer systems for validation of 3D Micro X-ray fluorescence spectroscopy

For the validation of the quantification of the newly-developed method of 3D Micro X-ray fluorescence spectroscopy (3D Micro-XRF) samples with a low average Z matrix and minor high Z elements are best suited. In a light matrix the interferences by matrix effects are minimized so that organic polymers are appropriate as basis for analytes which are more easily detected by X-ray fluorescence spectroscopy.     

A Simple Strategy for Easily Assembling 3D Printed Miniaturized Cells Suitable for Simultaneous Electrochemical and Spectrophotometric Analyses

A rapid and user‐friendly approach is here presented for assembling smart and versatile platforms for simultaneous electrochemical and spectrophotometric measurements. They consist of an optically transparent pencil‐drawn electrochemical cell, including reference, counter and working carbon electrodes, assembled on flexible PVC supports, exploiting a commercial desktop digitally controlled plotter/cutter. This cell is installed on a U shaped 3D printed polylactic frame where a second transparent window consisting of an unmodified PVC layer was also applied. After optimization of the fabrication procedure, the electrochemical and optical characterization of the assembled miniaturized platforms was performed by using aqueous electrolytes and potassium hexacyanoferrate(II) as redox probe. These devices were then tested by a proof‐of‐concept direct and simultaneous electrochemical and spectrophotometric quantification of a commonly used food dye (Brilliant Blue, E‐133) in soft‐drinks and candies. Spectrophotometric and electrochemical determinations can be performed at the same time, providing simultaneous information and enabling a concomitant comparison and validation of the results obtained.     

3D aluminum/silver hierarchical nanostructure with large areas of dense hot spots for surface‐enhanced raman scattering

Plasmonic nanomaterials possessing large‐volume, high‐density hot spots with high field enhancement are highly desirable for ultrasensitive surface‐enhanced Raman scattering (SERS) sensing. However, many as‐prepared plasmonic nanomaterials are limited in available dense hot spots and in sample size, which greatly hinder their wide applications in SERS devices. Here, we develop a two‐step physical deposition protocol and successfully fabricate 3D hierarchical nanostructures with highly dense hot spots across a large scale (6 × 6 cm²). The nanopatterned aluminum film was first prepared by thermal evaporation process, which can provide 3D quasi‐periodic cloud‐like nanostructure arrays suitable for noble metal deposition; then a large number of silver nanoparticles with controllable shape and size were decorated onto the alumina layer surfaces by laser molecular beam epitaxy, which can realize large‐area accessible dense hot spots. The optimized 3D‐structured SERS substrate exhibits high‐quality detection performance with excellent reproducibility (13.1 and 17.1%), whose LOD of rhodamine 6G molecules was 10^?9 M. Furthermore, the as‐prepared 3D aluminum/silver SERS substrate was applied in detection of melamine with the concentration down to 10^?7 M and direct detection of melamine in infant formula solution with the concentration as low 10 mg/L. Such method to realize large‐area hierarchical nanostructures can greatly simplify the fabrication procedure for 3D SERS platforms, and should be of technological significance in mass production of SERS‐based sensors.     

Preparation of Ag/C fiber with nanostructure through in situ thermally induced redox reaction between PVA and AgNO3 and its catalysis for 4‐nitrophenol reduction

A novel synthesized Ag/C fibrous catalyst based on in situ thermally induced redox reaction of PVA/AgNO₃ composite fibers was proposed. Utilizing the plasticization and complexation of AgNO₃ solution, the melt spinning of PVA/AgNO₃ composites was accomplished. Through the in situ thermally induced redox reaction on PVA/AgNO₃ composite fibers combined with carbonization of PVA and reduction of Ag+, the synthesized Ag/C fibrous catalyst was prepared with nanosilver particles with average diameter of 130 nm immobilized on the loose microstructural carbon layers. The synthesized Ag/C fibrous catalyst exhibited excellent catalytic activity and reused for at least five cycles for the reduction of 4‐nitrophenol, which may hold great promise in effective and eco‐friendly waste water treatment.     

Disposable Amperometric Biosensor Based on Poly‐L‐lysine and Fe3O4 NPs‐chitosan Composite for the Detection of Tyramine in Cheese

An amperometric tyramine biosensor based on poly‐L‐lysine (PLL) and Fe₃O₄ nanoparticles (Fe₃O₄NP) modified screen printed carbon electrode (SPCE) was developed. PLL was formed on the SPCE by the electropolymerization of L‐lysine. Subsequently, Fe₃O₄NP suspension prepared in chitosan (CH) solution was casted onto the PLL/SPCE. Tyrosinase (Ty) enzyme was immobilized onto the modified Fe₃O₄?CH/PLL/SPCE and the electrode was coated with Nafion to fabricate the Ty/Fe₃O₄?CH/PLL/SPCE. Different techniques including scanning electron microscopy, chronoamperometry (i–t curve), cyclic voltammetry and electrochemical impedance spectroscopy were utilized to study the fabrication processes, electrochemical characteristics and performance parameters of the biosensor. The analytical performance of the tyramine biosensor was evaluated with respect to linear range, sensitivity, limit of detection, repeatability and reproducibility. The response of the biosensor to tyramine was linear between 4.9×10^?7–6.3×10^?5 M with a detection limit of 7.5×10^?8 M and sensitivity of 71.36 μA mM^?1 (595 μA mM^?1 cm^?2). The application of the developed biosensor for the determination of tyramine was successfully tested in cheese sample and mean analytical recovery of added tyramine in cheese extract was calculated as 101.2±2.1 %. The presented tyramine biosensor is a promising approach for tyramine analysis in real samples due to its high sensitivity, rapid response and easy fabrication.