Optical nanosensor design with uniform pore geometry and large particle morphology

Appropriate design of nanosensors for optically selective, sensitive sensing systems is needed for naked-eye detection of pollutants for environmental cleanup of toxic heavy-metal ions. Mesostructured materials with two- or three-dimensional (2D or 3D) geometries and large particle morphologies show promise as probe carriers, and can therefore be used to reproducibly fabricate uniformly packed nanosensors. This is the first report on the effects of significant key properties of the mesostructured carriers, such as morphology, geometry, and pore shape, on the functionality of optical nanosensor designs. Such mesostructured sensors with superior physical characteristics can be used as components in sensing systems with excellent stability and sensitivity, and with rapid detection response. The nanosensor design can enhance the selectivity even at low concentrations of the pollutant target ions (nanomolar level). Among the nanosensors developed here, the large pore-surface grains of highly ordered 3D monoliths (HOM) exhibited a high adsorption capability of the Pyrogallol Red probe and high accessibility to analyte ion transport, leading to possible naked-eye detection of Sb(III) ions at concentrations as low as 10(-9) mol dm(-3) and at a wide detection range of 0.5 ppb to 3 ppm. A key finding in our study was that our mesostructured nanosensor designs retained highly efficient sensitivity without a significant increase in kinetic hindrance, despite the slight decrease of the specific activity of the electron acceptor/donor strength of the probe functional group after several regeneration/reuse cycles. The results, in general, indicate that large-scale reversibility of optical nanosensors is feasible in such metal-ion sensing systems.     

Recent progress in detection of chemical and biological toxins in Water using plasmonic nanosensors

The supply of safe drinking water is one of the prominent challenges of the world. Water is polluted mainly by chemical and biological toxins which can causes a serious threat to ecosystems and human health. Regular monitoring of chemical and biological toxins in water sources is the primary step in any preventive method. Traditional detection methods include adsorption and chromatography coupled with mass spectrometry. The devices based on these techniques are not easy to be carried for on-site detection and require laborious sample preparation protocols. However, advancements in nanomaterial-based sensors have provided solutions to these challenges. Recent developments in plasmonic sensors lead to extraordinary advancements in the area of ultra-sensitive detection at the single particle or molecular level. Noble metal nanoparticles of gold (Au) and silver (Ag) exhibit excellent plasmonic properties and have been applied for the selective and label-free detection of very low concentrations of aquatic pollutants. The present review represent the progress made towards the development and application of plasmonic nanosensors, specifically gold and silver nanoparticle-based sensors for the detection and quantification of various pollutants and contaminations in water. The design and fabrication of plasmonic nanosensors were given emphasis as it is fundamental in enhancing their affinity towards specific pollutant of interest. The effectiveness of plasmonic sensors in reducing the use of expensive instruments while enabling on-site multifunctional detection of toxin contaminants and also the future potential of plasmonic sensors will be highlighted.     

Opto-electrochemical nanosensor array for remote DNA detection

A high-density array of opto-electrochemical nanosensors is presented for remote DNA detection. It was fabricated by chemical etching of a coherent optical fibre bundle to produce a nanotip array. The surface of the etched bundle was sputter-coated with a thin ITO layer which was eventually insulated by an electrophoretic paint. The fabrication steps produced a high-density array of electrochemical nanosensors which retains the optical fibre bundle architecture and its imaging properties. A DNA probe was then immobilized on the nanosensor array surface in a polypyrrole film by electropolymerisation. After hybridisation with the complementary sequence, detection of the strepavidin-R-phycoerythrin label is performed by fluorescence imaging through the optical fibre bundle itself. Control experiments and regeneration steps have also been successfully demonstrated on this nanostructured opto-electrochemical platform.     

Analysis of inflammatory biomarkers from tissue biopsies by chip-based immunoaffinity CE

To aid in the biochemical analysis of human skin biopsies, a semiautomatic chip-based CE system has been developed for measuring inflammatory biomarkers in microdissected areas of the biopsy. Following solubilization of the dissected tissue, the desired biomarkers were isolated by immunoaffinity capture using a panel of 12 antibodies, immobilized on a disposable glass fiber disk, within the extraction port of the chip. The captured analytes were labeled with a 635 nm light-emitting laser dye and electroeluted into the separation channel. Electrophoretic separation of all of the analytes was achieved in 2.2 min with quantification of each peak being performed by online LIF detection and integration of each peak area. Comparison of the results obtained from the chip-based system to those obtained using commercially available high-sensitivity immunoassays demonstrated that the chip-based assay provides a fast, accurate procedure for studying the concentrations of inflammatory biomarkers in complex biological materials. The degree of accuracy and precision achieved by the chip-based CE is comparable to conventional immunoassays and the system is capable of analyzing circa six samples per hour. With the ever-expanding array of antibodies that are commercially available, this chip-based system can be applied to a wide variety of different biomedical analyses.     

Chemosensing hybrid materials: Chalcones‐functionalized cage‐like mesoporous SBA‐16 material for highly selective detection of toxic metal ions

Highly selective and low‐cost optical nanosensors of organic–inorganic hybrid materials for heavy metal ions detection have been prepared via the functionalization of mesoporous silica (SBA‐16) with chalcone fluorescent chromophores. The successful attachment of organic chalcone moieties and preservation of original structure of SBA‐16 after the anchoring process were confirmed by extensive characterizations using various techniques like Fourier transform infrared and UV–visible spectroscopies, transmission electron microscopy, nitrogen adsorption–desorption isotherms, low‐angle X‐ray diffraction and thermogravimetric analysis. The colorimetric behaviour, selectivity and sensitivity were also investigated. The optical nanosensors respond selectively to heavy metal ions, such as Mn²⁺, Fe³⁺, Co²⁺, Ni²⁺, Cu²⁺, Zn²⁺, Cd²⁺ and Hg²⁺, with observable colour changes in 0.01 M Tris–HCl aqueous buffer solution. Also, the optical sensing ability of the investigated nanosensors to the mentioned metal ions was investigated using steady‐state absorption and emission techniques. Significant increase in the absorption spectra and a static quenching in the emission spectra are observed upon adding various concentrations of the studied metal ions. The spectral changes as well as the observable colour changes suggest that the investigated nanosensors are suitable for simple, economic, online analysis and remote design of these toxic metal ions with fast kinetic responses. Finally, the low detection limits for all the studied metals are in good agreement with those recommended by both the US Environmental Protection Agency and World Health Organization, except for Hg²⁺ and Cd²⁺, indicating that the investigated nanosensors have hypersensitivity, selectivity and better recognition for all the studied metal ions.     

Immunoaffinity capillary electrophoresis: a new versatile tool for determining protein biomarkers in inflammatory processes

Many diseases caused by inflammatory processes can progress to a chronic state causing deterioration in the quality of life and a poor prognosis for long-term survival. To address inflammatory diseases effectively, early detection and novel therapeutics are required. However, this can be challenging, in part because of the lack of early predictive biomarkers and the limited availability of adequate technologies capable of the identification/characterization of key predictive biomarkers present in biological materials, especially those found at picomolar concentrations and below. This review highlights the need for state-of-the art methodologies, with high-sensitivity and high-throughput capabilities, for determination of multiple biomarkers. Although many new biomarkers have been discovered recently, existing technology has failed to successfully bring this advancement to the patient's bedside. We present an overview of the various advances available today to extend the discovery of predictive biomarkers of inflammatory diseases; in particular, we review the technology of immunoaffinity capillary electrophoresis (IACE), which combines the use of antibodies as highly selective capture agents with the high resolving power of capillary electrophoresis. This two-dimensional hybrid technology permits the quantification and characterization of several protein biomarkers simultaneously, including subtle structural changes such as variants, isoforms, peptide fragments, and post-translational modifications. Furthermore, the results are rapid, sensitive, can be performed at a relatively low cost, without the introduction of false positive or false negative data. The IACE instrumentation can have relevance to medical, pharmaceutical, environmental, military, cultural heritage (authenticity of art work), forensic science, industrial and research fields, and in particular as a point-of-care biomarker analyzer in translational medicine.     

Sensitive and selective fluorescence detection of guanosine nucleotides by nanoparticles conjugated with a naphthyridine receptor

Novel fluorescent nanosensors, based on a naphthyridine receptor, have been developed for the detection of guanosine nucleotides, and both their sensitivity and selectivity to various nucleotides were evaluated. The nanosensors were constructed from polystyrene nanoparticles functionalized by (N-(7-((3-aminophenyl)ethynyl)-1,8-naphthyridin-2-yl)acetamide) via carbodiimide ester activation. We show that this naphthyridine nanosensor binds guanosine nucleotides preferentially over adenine, cytosine, and thymidine nucleotides. Upon interaction with nucleotides, the fluorescence of the nanosensor is gradually quenched yielding Stern–Volmer constants in the range of 2.1 to 35.9 mM⁻¹. For all the studied quenchers, limits of detection (LOD) and tolerance levels for the nanosensors were also determined. The lowest (3σ) LOD was found for guanosine 3’,5’-cyclic monophosphate (cGMP) and it was as low as 150 ng/ml. In addition, we demonstrated that the spatial arrangement of bound analytes on the nanosensors’ surfaces is what is responsible for their selectivity to different guanosine nucleotides. We found a correlation between the changes of the fluorescence signal and the number of phosphate groups of a nucleotide. Results of molecular modeling and ζ-potential measurements confirm that the arrangement of analytes on the surface provides for the selectivity of the nanosensors. These fluorescent nanosensors have the potential to be applied in multi-analyte, array-based detection platforms, as well as in multiplexed microfluidic systems.     

Luminescent nanobeads for optical sensing and imaging of dissolved oxygen

A variety of luminescent oxygen nanosensors were prepared by addressable staining of poly(styrene-block-vinylpyrrolidone) nanobeads with metal–ligand complexes whose luminescence is quenched by oxygen. They display optimal sensitivity in responding to dissolved oxygen in concentrations from 0 to 100% air saturation. The nanobeads based on cyclometallated iridium(III) complexes with coumarins are especially promising due to excellent brightnesses. The nanosensors respond virtually in real time to altering oxygen concentration and are capable of recording even very rapid changes in oxygen partial pressure. Signals are obtained by determination of luminescence lifetime in the frequency domain and in the time domain, and by ratiometric measurement of luminescence intensity. The nanosensors have been applied to sensing and imaging of dissolved oxygen, to monitor the consumption of oxygen during enzymatic oxidation of glucose, and to monitoring dissolved oxygen in a growing culture of E. coli.     

Development of nanomaterial chemosensors for toxic metal ions sensing

Heavy metal ions are harmful to aquatic life and humans owing to their high toxicity and non‐biodegradability, so their removal from wastewater is an important task. Therefore, this work focuses on designing suitable, simple and economical nanosensors to detect and remove these metal ions with high selectivity and sensitivity. Based on this idea, different types of mesoporous materials such as hexagonal SBA‐15, cubic SBA‐16 and spherical MCM‐41, their chloro‐functionalized derivatives, as well as 4‐(4‐nitro‐phenylazo)‐naphthalen‐1‐ol (NPAN) azo dye have been synthesized, with the aim of designing some optical nanosensors for metal ions sensing applications. The mentioned azo dye has been anchored into the chloro‐functionalized mesoporous materials. The designed nanosensors were characterized using scanning and transmission electron microscopy as well as Fourier transform infrared and UV–visible spectral analysis, nitrogen adsorption–desorption isotherms, low‐angle X‐ray diffraction and thermogravimetric analyses. Their optical sensing to various toxic metal ions such as Cd (II), Hg (II), Mn (II), Fe (II), Zn (II) and Pb (II) at different values of pH (1.1, 4.9, 7 and 12) was investigated. The optimization of experimental conditions, including the effect of pH and metal ion concentration, was examined. The experimental results showed that the solution pH had a major impact on metal ion detection. The optical nanosensors respond well to the tested metal ions, as reflected by the enhancement in both absorption and emission spectra upon adding different concentrations of the metal salts and were fully reversible on adding ethylene diamine tetra acetic acid or citric acid to the formed complexes. High values of the binding constants for the designed nanosensors were observed at pHs 7 and 12, confirming the strong chelation of different metals to the nanosensor at these pHs. Also, high binding constants and sensitivity were observed for NPAN‐MCM‐41 as a nanosensor to detect the different metal ions. From the obtained results, we succeeded in transforming the harmful azo dye into an environmentally friendly form via designing of the optical nanosensors used to detect toxic metal ions in wastewater with high sensitivity.     

Nanosensors in environmental analysis

Nanoscience and nanotechnology deal with the study and application of structures of matter of at least one dimension of the order of less than 100 nm (1 nm = one millionth of a millimetre). However, properties related to low dimensions are more important than size. Nanotechnology is based on the fact that some very small structures usually have new properties and behaviour that are not displayed by the bulk matter with the same composition.This overview introduces and discusses the main concepts behind the development of nanosensors and the most relevant applications in the field of environmental analysis. We focus on the effects (many of which are related to the quantum nature) that distinguish nanosensors and give them their particular behaviour. We will review the main types of nanosensors developed to date and highlight the relationship between the property monitored and the type of nanomaterial used.We discuss several nanostructures that are currently used in the development of nanosensors: nanoparticles, nanotubes, nanorods, embedded nanostructures, porous silicon, and self-assembled materials. In each section, we first describe the type of nanomaterial used and explain the properties related to the nanostructure. We then briefly describe the experimental set up and discuss the main advantages and quality parameters of nanosensing devices. Finally, we describe the applications, many of which are in the environmental field.     

Precipitation as a simple and versatile method for preparation of optical nanochemosensors

Optical nanosensors for such important analytes as oxygen, pH, temperature, etc. are manufactured in a simple way via precipitation. Lipophilic indicators are entrapped into nanobeads based on poly(methyl methacrylate), polystyrene, polyurethanes, ethylcellulose, and other polymers. Charged groups greatly facilitate formation of the small beads and increase their stability. Sensing properties of the beads can be tuned by choosing the appropriate indicator. Nanosensors for carbon dioxide and ammonia are found to be cross-sensitive to pH if dispersed in aqueous media. These nanobeads are successfully employed to design bulk optodes. Nanochemosensors with enhanced brightness via light-harvesting and multi-functional magnetic nanosensors also are prepared.     

基于分子印迹与表面增强拉曼散射的蛋白质疾病标志物检测研究进展

异常的蛋白质表达与疾病的发生与发展密切相关,因此蛋白质已作为疾病标志物广泛应用于疾病的早期诊断、治疗监测和预后评估.然而,临床样本中的蛋白质疾病标志物通常含量极低,并存在高丰度的基质干扰,对检测方法的特异性和灵敏度提出挑战.目前,蛋白质疾病标志物的检测方法主要是免疫分析.但是,免疫分析主要依赖抗体进行特异性识别,而抗体...     

基于双纳米金探针杂交法检测HBV DNA

利用双纳米金探针结合基因芯片平台建立了一种检测乙肝病毒基因(HBV DNA)的新方法. 根据HBV DNA的保守序列设计捕获探针和信号报告探针, 通过一对互补的纳米金检测探针的双杂交法对HBV DNA进行信号放大, 最后进行银染, 达到对HBV DNA的可视化检测. 该方法的灵敏度高, 可检测10 fmol/L的HBV DNA, 且能在1.5 h内完成检测. 其具有的快速、 高灵敏度及低成本等优势使其有望发展成为一种检测HBV DNA的新方法.     

Color fingerprinting of proteins by calixarenes embedded in lipid/polydiacetylene vesicles

"Naked eye" color detection of proteins was achieved by embedding calixarene receptors within vesicles comprising phospholipids and the chromatic polymer polydiacetylene. Dramatic visible absorbance changes were induced through electrostatic interactions between the protein surface and the vesicle-incorporated hosts. The colorimetric responses could be induced by micromolar protein concentrations, and furthermore, specific protein fingerprints could be obtained by incorporating different receptors within the vesicles. Fluorescence and circular dichroism experiments confirmed the relationship between the colorimetric phenomena and protein docking on the surface of the chromatic vesicles. The colorimetric assay constitutes a generic platform for high-sensitivity detection of soluble proteins and for evaluation of protein surface charge distribution.     

Use of quantum dots in the development of assays for cancer biomarkers

Biomarker assays may be useful for screening and diagnosis of cancer if a set of molecular markers can be quantified and statistically differentiated between cancerous cells and healthy cells. Markers of disease are often present at very low concentrations, so methods capable of low detection limits are required. Quantum dots (QDs) are nanoparticles that are emerging as promising probes for ultrasensitive detection of cancer biomarkers. QDs attached to antibodies, aptamers, oligonucleotides, or peptides can be used to target cancer markers. Their fluorescent properties have enabled QDs to be used as labels for in-vitro assays to quantify biomarkers, and they have been investigated as in-vivo imaging agents. QDs can be used as donors in assays involving fluorescence resonance energy transfer (FRET), or as acceptors in bioluminescence resonance energy transfer (BRET). The nanoparticles are also capable of electrochemical detection and are potentially useful for “lab-on-a-chip” applications. Recent developments in silicon QDs, non-blinking QDs, and QDs with reduced-size and controlled-valence further make these QDs bioanalytically attractive because of their low toxicity, biocompatibility, high quantum yields, and diverse surface modification flexibility. The potential of multiplexed sensing using QDs with different wavelengths of emission is promising for simultaneous detection of multiple biomarkers of disease.

3-benzoyl-2-quinolinecarboxaldehyde: A novel fluorogenic reagent for the high-sensitivity chromatographic analysis of primary amines

3-Benzoyl-2-quinolinecarboxaldehyde has been synthesized and characterized for use as a precolumn fluorogenic reagent for the ultrahigh sensitivity determination of primary amines by micro-column liquid chromatography with laser-induced fluorescence detection. The reaction conditions and the spectral properties of the derivatives were investigated with standard amino-acids. The detection limits, with an HeCd laser operated at 442 nm, are in the low femtogram range. The linear dynamic range is at least three orders of magnitude. The separation of a standard amino-acid mixture and the high-sensitivity analysis of a hydrolysed protein sample are demonstrated.     

DNA/银纳米簇在分析检测中的应用

银纳米簇(AgNCs)为几个到数十个原子所组成的聚集体,核尺寸小于2 nm,具有优异的物理化学性质,常以聚合物、蛋白质、DNA等作为模板采用化学合成法制备,其中以DNA为模板合成的AgNCs(DNA/AgNCs)是一种新型的发光纳米材料,其突出的荧光特性和良好的生物相容性,被应用于纳米传感器、细胞标记与检测等多种分析领...     

The double life of conductive nanopipette: a nanopore and an electrochemical nanosensor

The continuing interest in nanoscale research has spurred the development of nanosensors for liquid phase measurements. These include nanopore-based sensors typically employed for detecting nanoscale objects, such as nanoparticles, vesicles and biomolecules, and electrochemical nanosensors suitable for identification and quantitative analysis of redox active molecules. In this Perspective, we discuss conductive nanopipettes (CNP) that can combine the advantages of single entity sensitivity of nanopore detection with high selectivity and capacity for quantitative analysis offered by electrochemical sensors. Additionally, the small physical size and needle-like shape of a CNP enables its use as a tip in the scanning electrochemical microscope (SECM), thus, facilitating precise positioning and localized measurements in biological systems.

Conductive nanopipettes: a useful tool for localized detection and analysis of single nanoscale objects.     

Protamine/heparin optical nanosensors based on solvatochromism

Optical nanosensors for the detection of polyions, including protamine and heparin, have to date relied upon ion-exchange reactions involving an analyte and an optical transducer. Unfortunately, due to the limited selectivity of the available ionophores for polyions, this mechanism has suffered from severe interference in complex sample matrices. To date no optical polyion nanosensors have demonstrated acceptable performance in serum, plasma or blood. Herein we describe a new type of nanosensor based on our discovery of a “hyper-polarizing lipophilic phase” in which dinonylnaphthalenesulfonate (DNNS⁻) polarizes a solvatochromic dye much more than even an aqueous environment. We have found that the apparent polarity of the organic phase is only modulated when DNNS⁻ binds to large polyions such as protamine, unlike singly charged ions that lack the cooperative binding required to cause a significant shift in the distribution of the polarizing DNNS⁻ ions. Our new sensing mechanism allows solvatochromic signal transduction without the transducer undergoing ion exchange. The result is significantly improved sensitivity and selectivity, enabling for the first time the quantification of protamine and heparin in human plasma using optical nanosensors that correlates with the current gold standard analysis method, the anti-Xa factor assay.

Novel optical nanosensors for the selective detection of the polycationic protamine based on solvatochromic signal change allow one to detect heparin in plasma.     

Carbon nanomaterials and metallic nanoparticles-incorporated electrochemical sensors for small metabolites: Detection methodologies and applications

Detection of small metabolite biomarkers at different concentrations could be powerfully used for disease diagnosis and progression. To enhance detection capabilities, nanomaterials possessing excellent optical and electrochemical properties have been integrated into a wide range of sensing or detection platforms. This review will highlight recent developments in creating electrochemical sensors alongside biosensors using carbon nanomaterials and metallic nanoparticles that target small metabolites. Moreover, electrochemical sensors having different detection strategies toward metabolites (such as amino acids, amino acid–derived neurotransmitters, vitamins, adenosine triphosphate, and purine derivatives) will be discussed. Finally, certain challenging issues and future aspects of nanomaterials-integrated electrochemical sensors for small metabolites will be discussed.