Multilayer Nanoparticles Research Articles

A FRET-based ratiometric sensor for mercury ions in water with multi-layered silica nanoparticles as the scaffold

A FRET system was built for ratiometric sensing of Hg(2+) in water with multilayered silica nanoparticles as the scaffold. This architecture ensures the control over the location of both donor and acceptor and their separation distance within nanoparticles, affording higher energy transfer efficiency and higher signal-to-background ratio for particle-based sensing.

Multilayer enzyme-coupled magnetic nanoparticles as efficient, reusable biocatalysts and biosensors

Herein we report the development of a highly active, magnetically retrievable and reusable biocatalyst using multilayer enzyme coupled-magnetic nanoparticles (MNPs) prepared by layer-by-layer assembly using two well-studied enzymes, horseradish peroxidase (HRP) and glucose oxidase (GOX), as a model enzyme system. We show that by combining the use of a biocompatible linker as well as biospecific immobilisation, the first layer enzyme in our HRP(1)-MNP system retains the native activity of the enzyme in solution, and the overall catalytic activity of the multilayer enzyme system, HRP(x)-MNP, increases linearly with the increasing number of enzyme layers. Furthermore, the HRP(x)-MNP system can be conveniently retrieved by using an external magnetic field and reused for 10 consecutive cycles without apparent reduction of catalytic activity. We also report the development of a novel coupled bienzyme, GOX/HRP(x)-MNP, system that can perform bi-enzymatic reactions to couple the colourless GOX-catalyzed reaction to the chromophoric HRP-catalyzed reaction via H(2)O(2) production. This model bienzyme-MNP system can be used for simple, rapid colorimetric quantification of micromolar glucose.

Size Dependence of Air Oxidation for Mg Nanoparticle

The size dependence of the air oxidation for Mg nanoparticles is studied by Mg K-edge NEXAFS and AFM techniques. In the case of the exposure to the air for 3 days, the degree of the air oxidation for Mg nanoparticles increases with reduction of the size of Mg nanoparticle. However, the opposite size dependence is observed in the case of the exposure to the air for 25 days, i.e. the air oxidation reaction for the smaller Mg nanoparticles is more inhibited in the case of long term exposure to the air. This size dependence is attributed to the occupation of the free spaces between Mg nanoparticles, which protects against the incursion of the air component molecules into the multilayer of Mg nanoparticles. [DOI: 10.1380/ejssnt.2011.315]

Para-Mercaptobenzoic acid-modified silver nanoparticles as sensing media for the detection of ammonia in air based on infrared surface enhancement effect

To utilize the large signals provided by surface-enhanced infrared absorption (SEIRA) measurements for chemical sensing, a new sensing scheme was proposed and demonstrated for detection of ammonia in air samples. To increase the SEIRA effect, a sensing phase composed of multi-layers of silver nanoparticles (AgNPs) was prepared using a chemically controlled electroless deposition method. para-Mercaptobenzoic acid (pMBA) served as the controlling agent in formation of AgNPs, a surface modification agent of AgNPs for sensing, and a stabilizer to protect the AgNPs from coagulation and oxidation. The sensing approach utilized the interaction between pMBA and ammonia, which involves the formation of carboxylate-ammonium complex. After interaction, the enhanced IR absorption bands of pMBA on AgNPs were significantly changed and able to provide quantitative information on the ammonia concentrations. To optimize the conditions for preparing sensing elements, parameters used to form multi-layers of AgNPs were systematically varied and their corresponding sensitivities in detection of ammonia were recorded. The results indicate that AgNPs with diameters in the range of 100 nm provided the best performance in terms of detecting ammonia via the SEIRA effect. Also, the analytical signal generally increased as the number of layers of AgNPs increased, but was limited to certain layers, depending on the reaction conditions used in preparation of AgNPs. The sensing elements were found to be highly selective to ammonia and the detection limit approached 150 ppb with a linear range up to 25 ppm.

The Effect of Multilayer Gold Nanoparticles on the Electrochemical Response of Ammonium Ion Biosensor Based on Alanine Dehydrogenase Enzyme

The use of multilayer of gold nanoparticles (AuNPs) attached on gold electrode surface via thiol chemistry to fabricate an ammonium (NH4+) ion biosensor based on alanine dehydrogenase (AlaDH) was investigated. The approach of the study was based on construction of biosensor by direct deposition of AuNPs and 1,8-octanedithiol (C8-DT) onto the gold electrode surface. For the immobilisation of enzyme, 2-mercaptoethanol (2BME) was first covalently attached to AlaDH via esther bonding and then followed by chemically attached the 2BME-modified AlaDH (2BME-AlaDH) moiety onto the AuNPs electrode via the exposed thiol group of 2BME. The resulting biosensor response was examined by means of amperometry for the quantification ofNH4+ion. In the absence of enzyme attachment, the use of three layers of AuNPs was found to improve the electrochemistry of the gold electrode when compared with no AuNPs was coated. However, when more than three layers of AuNPs were coated, the electrode response deteriorated due to excessive deposition of C8-DT. When AlaDH was incoporated into the AuNPs modified electrode, a linear response toNH4+ion over the concentration range of 0.1–0.5 mM with a detection limit of 0.01 mM was obtained. In the absence of AuNPs, theNH4+ion biosensor did not exhibit any good linear response range although the current response was observed to be higher. This work demonstrated that the incorporation of AuNPs could lead to the detection of higherNH4+ion concentration without the need of dilution for highNH4+ion concentration samples with a rapid response time of <1 min.

Use of thermally annealed multilayer gold nanoparticle films in combination analysis of localized surface plasmon resonance sensing and MALDI mass spectrometry

A self-assembled film of gold nanoparticles (AuNPs) with a raspberry-like morphology was prepared on a glass plate by the layer-by-layer thermal annealing of multilayer films of AuNPs. It was possible to control the morphology of the obtained films of AuNPs by changing the annealing temperature, duration of annealing, and number of layers. On investigating the plasmonic properties of these films, we found that AuNP films with a raspberry-like morphology yielded the highest refractive index unit, which is a critical parameter in localized surface plasmon resonance (LSPR) sensing, as compared to other types of AuNP films. Self-assembled AuNP films with a raspberry-like morphology were subsequently functionalized with 11-mercaptoundecanoic acid (MUA) to enable the binding of lysozyme to the MUA-modified Au surface. The superior limit of detection for the LSPR sensing of lysozyme in a buffer solution was found to be in the picomolar range (∼10(-12) M). The high sensitivity observed in the region was attributed to the raspberry-like morphology, where the AuNPs were packed closely together, and the electromagnetic field confinement was most intense (i.e., at hot spots). The MUA-modified, self-assembled AuNP films with a raspberry-like morphology were finally used in the combination analysis of LSPR sensing and matrix-assisted laser desorption/ionization mass spectrometry (MALDI-MS) for the selective detection and identification of lysozyme in human serum.

Targeted multicomponent polysomes for high efficiency, simultaneous anti-sense and gene delivery

Gene therapy is an elegant alternative to chemotherapy, with its well known severe side-effects, as cancer therapy. While viral gene delivery systems bear the risk of infection, polymer-aided delivery suffers low transfection efficacy combined with a relatively high cell toxicity by the used polycations. Here we introduce a targeted polymeric multicomponent submicrometric delivery system delivering simultaneously siRNA and a plasmid to guarantee that both nucleic acids are entering the same cell. The biodegradable 300 nm multilayer particles release siRNA against c-Myc mRNA in order to arrest cell proliferation and then subsequently transfect cancer cells with a wild-type p53 plasmid to induce apoptosis. A high selectivity along with a comparably high transfection efficacy in cancer cells was reached by an electrostatic binding of folic acid to the particle surface. As a result a transfection efficacy and gene expression of around 80–90% was reached in vitro in different cancer cell lines but the particles cause toxicity or apoptosis in only 15% of the healthy cells. The multifunctionality of the electrostatically assembled multilayer nanoparticles significantly improves the transfection efficacy of the non-toxic polycation, chitosan and the combined delivery of siRNA and a plasmid to the same cells holds promises for future gene therapies.

A new photoelectrochemical aptasensor for the detection of thrombin based on functionalized graphene and CdSe nanoparticles multilayers

A photoelectrochemical sensing strategy for highly sensitive detection of thrombin was developed based on a layer-by-layer (LBL) assembly of functionalized graphene and CdSe nanoparticles.

Aerosol‐based technologies in nanoscale manufacturing: from functional materials to devices through core chemical engineering

Manufacturing of nanoscale materials and devices offers a number of exciting opportunities for chemical engineers to contribute substantially in product development, process scale-up, and environmental compliance. Current research in nanoscale science and engineering has been directed primarily toward the design and synthesis of (a) materials with passive nanostructures (e.g., nanostructured coatings, dispersion of nanoparticles, as well as bulk nanostructured metals, polymers and ceramics), and (b) active devices with nanostructured materials (e.g., transistors, amplifiers, targeted drugs and delivery systems, sensors, actuators and adaptive structures). Such materials are usually produced through self-assembly of nanoparticles in gasor liquid-phase processes or through compaction of nanopowders. Even though nanoparticles have been in use for a long time (e.g., carbon black, photographic films, fumed silica), the knowledge base for their synthesis and characterization has increased dramatically in the last 30 years with the development of a number of sophisticated scientific instruments, new synthetic processes at the nanoscale, and computational advances. This progress has contributed decisively to the development of effective and quantitative understanding of (a) nanomaterial properties and their dependence on their constituent parts, and (b) synthesis methods on which their fabrication is based, resulting in the discovery of new materials with an array of new functionalities and potential applications with promises of more to come in the future. To date, however, rather little of the aforementioned has been translated into actual industrial products. Most of these exciting discoveries have been made in basic science laboratories with little motivation or capacity to investigate and invent processes for the economic manufacturing of these nanotechnology products; the ‘‘bread and butter’’ of chemical engineers. In fact, little is known about how well these new properties are reproduced during large-scale manufacturing of such nanomaterials. More importantly, there is little understanding on how such manufacturing processes can be designed and operated, while issues arise regarding the controllability of such process operations and sustainability of the product quality, safety and potential hazards for personnel, environment and consumers. The associated risks constitute key issues in developing manufacturing technologies by major industries, a drive that has been part of what is recently referred to as ‘‘green’’ manufacturing. Two of the major challenges are: first, low-cost manufacturing of sophisticated nanostructured materials, and second, the economical and reliable assembly of such materials into functional devices. To meet these challenges a quantitative advancement of the current understanding of the corresponding manufacturing technologies is needed for the synthesis of mixed, functionalized and/or layered nanomaterials, significantly beyond the simple ones in the market today, with close attention to product handling, safety and health effects. Furthermore, assembling of devices with such materials (e.g., synthesis, deposition and processing of multilayers of functional nanoparticles) is needed to meet today’s engineering challenges in energy, mobility, health and life sciences (e.g., nonintrusive medical diagnostics and even cures for chronic and serious illnesses). While most of the current research in nanotechnology is driven by the imperative of scientific questions on the synthesis and characterization of passive nanoscale materials and/or active devices, with minimal attention paid to the Correspondence concerning this article should be addressed to S. E. Pratsinis at sotoris.pratsinis@ptl.mavt.ethz.ch.

Two-Photon Poly(phenylenevinylene) DFB Laser

Two-photon pumped lasing of a poly(phenylenevinylene)-titania-silica (PPV-TiO2-SiO2) nanocomposite comprised of PPV synthesized within the void spaces of a multilayer nanoparticle TiO2 and SiO2 1D photonic crystal is reported for the first time. With this distributed feedback (DFB) device, we have discovered the surprising result that two photon lasing requires only a factor of 2 higher intensity than one photon lasing thereby allowing laser excitation densities far below those that cause material degradation. The lower excitation density makes possible laser operation in the high-repetition rate regime and the use of compact and cheap NIR pump sources. All this makes our device rather interesting for optical telecommunication applications.

Tunable Conductive Nanoparticle Wire Arrays Fabricated by Convective Self-Assembly on Nonpatterned Substrates

Ordered arrays of centimeter-long nanoparticle wires are fabricated by convective self-assembly from aqueous suspensions of 18 nm gold colloids, on flat SiO(2)/Si substrates without any prepatterning. The orientation of the wires can be switched from parallel to perpendicular to the substrate-liquid-air contact line by controlling the substrate temperature. While the wires parallel to the meniscus are obtained by a stick-slip process, a mechanism based on critical density-triggered particle pinning is proposed to explain the formation of wires perpendicular to the meniscus. The geometry of the wire arrays is tuned by simply controlling the meniscus translation speed. Wires are typically characterized by widths of a few micrometers (1.8-8.2 µm), thicknesses of mono- to multilayers (18-70 nm), and spacings of few tens of micrometers. The fabricated nanoparticle wires are conductive, exhibiting a metallic resistive behavior in ambient conditions. Resistivity values of 5 × 10(-6) and 5 × 10(-2) Ωm are obtained on multilayer and monolayer nanoparticle wires, respectively. Such conductive nanoparticle wire arrays, fabricated by a simple and low-cost bottom-up strategy, offer opportunities for developing nanoparticle-based functional devices.

Persistent Multilayer Electrode Adsorption of Polycationic Au Nanoparticles

Multilayers of mixed monolayer thiolate-protected Au nanoparticles with polycationic ligand shells are strongly and persistently adsorbed on Pt electrodes from dilute CH3CN/electrolyte solutions of the nanoparticles. The adsorption is so robust that the electrodes can be transferred, with rinsing, to nanoparticle-free CH3CN/electrolyte (and other organic solvents) and their voltammetry observed without significant desorption. The nanoparticles have the average composition [Au225(TEA-thiolate+)X(SC6Fc)Y][ClO4−lX, where X = 18, 22, or 27. The cation sites are a quaternary ammonium-terminated ligand (TEA-thiolate+ = −S(CH2)11N(CH2CH3)3+). The ferrocene content of the ligand shell (Y) allows voltammetric detection of the adsorption, and also affects it. This work describes how the extent of nanoparticle adsorption (surface coverage, ΓNP mol/cm2) depends on the manner of exposure of the electrode (with potential scanning, at a fixed potential, or at open circuit) to the nanoparticle solution, and on the nanopa...

A Three‐Dimensional Nanostructured Array of Protein Nanoparticles

AbstractHere a novel technique is reported to construct a three‐dimensional (3D) array of well‐defined and controllable multilayered nanostructures of proteins that is based on alternate layer‐by‐layer assembly of bacterial protein nanoparticles and DNA on a patterned array of gold dots. This is the first report on protein‐based multilayer stacking, which has the following significant advantages over conventional multilayer assemblies: 1) avoiding hazardous chemicals, the multilayer assembly is implemented in aqueous solution under mild temperature and pH conditions over a relatively short period; 2) direct multilayer growth from designated position is possible by controlling the aspect ratio; 3) multicomponent stacking can be easily performed through alternate stacking of different building blocks (in this case protein nanoparticles); and 4) a wide variety of 3D arrays can be constructed using various functionalized protein nanoparticles that are easily prepared through a simple genetic engineering approach. In this study, as a proof of concept, the developed 3D and patterned arrays of protein nanoparticle multilayers are successfully applied to the multiplexed bioassays of breast and colorectal cancer markers.

Pharmacological effect of orally delivered insulin facilitated by multilayered stable nanoparticles

Intestinal uptake, insulinemia and hypoglycemic effect of orally delivered insulin encapsulated in polyelectrolytically stable nanoparticles were evaluated in streptozotocin-induced Wistar diabetic rats. Nanoparticles with 396 nm mean diameter were formed by alginate and dextran sulfate nucleating around calcium and binding to poloxamer, stabilized by chitosan, and subsequently coated with albumin. The resulting negatively charged nanoparticles retained insulin bioactivity and enhanced pharmacological availability by shielding insulin from enzymatic degradation and through chemical and physical facilitation of permeation through the intestinal membrane. Insulin nanoencapsulated through a simplified method avoiding harsh conditions and organic solvents, reduced plasma glucose levels to 40% of the basal values with a sustained hypoglycemic effect over 24 h. Pharmacodynamic and pharmacokinetic parameters were evaluated at a dose of 50 IU/kg nanoencapsulated insulin, and 13% oral bioavailability showed a threefold increase in comparison to free insulin. Confocal microscopy showed internalization of nanoencapsulated insulin in the small intestinal mucosa using independently labeled insulin–FITC and alginate–RBITC. Therefore the nanoformulation facilitated the oral delivery of insulin, and potentially that of other therapeutic proteins.

Nanocompression of individual multilayered polyhedral nanoparticles

Inorganic layered materials can form hollow multilayered polyhedral nanoparticles. Thesize of these multi-wall quasi-spherical structures varies from 4 to 300 nm. Thesematerials exhibit excellent tribological and wear-resisting properties. Measuring andevaluating the stiffness of individual nanoparticle is a non-trivial problem. Thecurrent paper presents an in situ technique for stiffness measurements of individualWS2 nanoparticles which are 80 nm or larger using a high resolution scanning electronmicroscope (HRSEM). Conducting the experiments in the HRSEM allows elucidation ofthe compression failure strength and the elastic behavior of such nanoparticles underuniaxial compression.

Surface plasmon resonance biosensor modified with multilayer silver nanoparticles films

We alternately deposited negatively charged Ag-(3-mercaptopropionic acid) (Ag-MPA) sol and positively charged poly-(diallyldimethylammonium) (PDDA) on gold substrate modified with 4-aminothiophenol (4-ATP), through electrostatic layer-by-layer (LBL) self-assembly. We characterized the prepared three-dimensional Ag/PDDA multilayer films by surface plasmon resonance (SPR) and atomic force microscope (AFM). The thickness of each film in the multilayer films, the deposition effect of Ag nanoparticles, and the processing of DNA adsorption are characterized by SPR. AFM characterization shows that DNA/3(PDDA/Ag)/4-ATP composite is uniformly and firmly distributed on the surface of gold films. Compared with other sensors, gentamicin could be highly sensitively measured by DNA/3(PDDA/Ag)/4-ATP/Au sensor. There is a good linear relationship in the concentration range of 5 × 10 −8 to 1 × 10 −4 mol/L. The linear equation is found to be Δ θ SPR = 1.3521 × 10 −5 c + 0.08641 (the correlation coefficient is 0.9983) with detection limit of 1 × 10 −9 mol/L. Since such LBL assembly film is simple to prepare, the work described here provides an effective method for studying small molecule drugs on SPR.

Fast and Scalable Printing of Large Area Monolayer Nanoparticles for Nanotexturing Applications

Recently, there have been several studies demonstrating that highly ordered nanoscale texturing can dramatically increase performance of applications such as light absorption in thin-film solar cells. However, those methods used to make the nanostructures are not compatible with large-scale fabrication. Here we demonstrate that a technique currently used in roll-to-roll processing to deposit uniform thin films from solution, a wire-wound rod coating method, can be adapted to deposit close-packed monolayers or multilayers of silica nanoparticles on a variety of rigid and flexible substrates. Amorphous silicon thin films deposited on these nanoparticle monolayers exhibit 42% higher absorption over the integrated AM 1.5 spectrum than the planar controls. This simple assembly technique can be used to improve solar cells, fuel cells, light emitting diodes and other devices where ordered nanoscale texturing is critical for optimal performance.

An Antireflective Nanostructure Array Fabricated by Nanosilver Colloidal Lithography on a Silicon Substrate.

An alternative method is presented for fabricating an antireflective nanostructure array using nanosilver colloidal lithography. Spin coating was used to produce the multilayered silver nanoparticles, which grew by self-assembly and were transformed into randomly distributed nanosilver islands through the thermodynamic action of dewetting and Oswald ripening. The average size and coverage rate of the islands increased with concentration in the range of 50–90 nm and 40–65%, respectively. The nanosilver islands were critically affected by concentration and spin speed. The effects of these two parameters were investigated, after etching and wet removal of nanosilver residues. The reflection nearly disappeared in the ultraviolet wavelength range and was 17% of the reflection of a bare silicon wafer in the visible range.

Jitter-free multi-layered nanoparticles optical storage disk with buffer ring

A multi-layered nanoparticles optical disk has been developed for a jitter-free high-density data storage system. The disk has nano structures composed of 300-nm-diameter photosensitive particles and 30-nm-width non-photosensitive buffer rings around them. With the buffer rings into the nanoparticles disk, a conventional confocal microscope equipped with a low numerical aperture (NA) objective picked up a particle's shape signal to generate a synchronous signal on its own. In the three-dimensional structured disk proposed, no electronically-produced reference signal is necessary for clock data recover (CDR); no jitter occurs in data decoding.

Optical Properties of Plasmon Resonances with Ag/SiO2/Ag Multi-Layer Composite Nanoparticles

Optical properties of plasmon resonance with Ag/SiO2/Ag multi-layer nanoparticles are studied by numerical simulation based on Green's function theory. The results show that compared with single-layer Ag nanoparticles, the multi-layer nanoparticles exhibit several distinctive optical properties, e.g. with increasing the numbers of the multi-layer nanoparticles, the scattering efficiency red shifts, and the intensity of scattering enhances accordingly. It is interesting to find out that slicing an Ag-layer into multi-layers leads to stronger scattering intensity and more “hot spots" or regions of stronger field enhancement. This property of plasmon resonance of surface Raman scattering has greatly broadened the application scope of Raman spectroscopy. The study of metal surface plasmon resonance characteristics is critical to the further understanding of surface enhanced Raman scattering as well as its applications.