Mercaptoacetic acid (RSH)-capped CdS nanocrystals (NCs) was demonstrated to be electrochemically reduced during potential scan and react with the coreactant S2O8(2-) to generate strong electrochemiluminescence (ECL) in aqueous solution. Based on the ECL of CdS NCs, a novel label-free ECL biosensor for the detection of low-density lipoprotein (LDL) has been developed by using self-assembly and gold nanoparticle amplification techniques. The biosensor was prepared as follows: The gold nanoparticles were first assembled onto a cysteamine monolayer on the gold electrode surface. This gold nanoparticle-covered electrode was next treated with cysteine and then reacted with CdS NCs to afford a CdS NC-electrode. Finally, apoB-100 (ligand of LDL receptor) was covalently conjugated to the CdS NC-electrode. The modification procedure was characterized by cyclic voltammetry, electrochemical impedance spectroscopy, and atomic force microscopy, respectively. The resulting modified electrode was tested as ECL biosensor for LDL detection. The LDL concentration was measured through the decrease in ECL intensity resulting from the specific binding of LDL to apoB-100. The ECL peak intensity of the biosensor decreased linearly with LDL concentration in the range of 0.025-16 ng mL-1 with a detection limit of 0.006 ng mL-1. The CdS NCs not only showed high ECL intensity and good biocompatibility but also could provide more binding sites for apoB-100 loading. In addition, the gold nanoparticle amplification for protein ECL analysis was applied to the improvement of the detection sensitivity. Thus, the biosensor exhibited high sensitivity, good reproducibility, rapid response, and long-term stability.
MnO2 has been widely studied as the pseudo-capactive electrode material of high-performance supercapacitors for its large operating voltage, low cost, and environmental friendliness. However, it suffers from low conductivity and being hardly handle as the electrodes of supercapacitors especially with flexibility, which largely limit its electrochemical performance and application. Herein, we report a novel ternary composite paper composed of reduced graphene sheet (GR)-patched carbon nanotube (CNT)/MnO2, which has controllable structures and prominent electrochemical properties for a flexible electrode of the supercapacitor. The composite paper was prepared by electrochemical deposition of MnO2 on a flexible CNT paper and further adsorption of GR on its surface to enhance the surface conductivity of the electrode and prohibit MnO2 nanospheres from detaching with the electrode. The presence of GR was found remarkably effective in enhancing the initial electrochemical capacitance of the composite paper from 280 F/g to 486.6 F/g. Furthermore, it ensures the stability of the capacitance after a long period of charge/discharge cycles. A flexible CNT/polyaniline/CNT/MnO2/GR asymmetric supercapacitor was assembled with this composite paper as an electrode and aqueous electrolyte gel as the separator. Its operating voltage reached 1.6 V, with an energy density at 24.8 Wh/kg. Such a composite structure derived from a multiscale assembly can offer not only a robust scaffold loading MnO2 nanospheres but also a conductive network for efficient ionic and electronic transport; thus, it is potentially promising as a novel electrode architecture for high-performance flexible energy storage devices.
A strategy for label-free oligonucleotide (DNA) analysis has been proposed by measuring the DNA-morpholino hybridization hindered diffusion flux of probe ions Fe(CN)(6)(3-) through nanochannels of a porous anodic alumina (PAA) membrane. The flux of Fe(CN)(6)(3-) passing through the PAA nanochannels is recorded using an Au film electrochemical detector sputtered at the end of the nanochannels. Hybridization of the end-tethered morpholino in the nanochannel with DNA forms a negatively charged DNA-morpholino complex, which hinders the diffusion of Fe(CN)(6)(3-) through the nanochannels and results in a decreased flux. This flux is strongly dependent on ionic strength, nanochannel aperture, and target DNA concentration, which indicates a synergetic effect of steric and electrostatic repulsion effects in the confined nanochannels. Further comparison of the probe flux with different charge passing through the nanochannels confirms that the electrostatic effect between the probe ions and DNA dominates the hindered diffusion process. Under optimal conditions, the present nanochannel array-based DNA biosensor gives a detection limit of 0.1 nM.
Electrochemiluminescence (ECL)-based
capacitance microscopy using
a square-wave voltage is established unprecedentedly to realize the
label-free visualization of species on electrode surfaces and cellular
plasma membranes. The drop in the local capacitance upon the binding
of species to the surface or to a cellular membrane is derived to
induce a relatively larger potential drop (V
dl) across the double layer on the local electrode surface,
which is utilized to prompt enhanced ECL at the binding position.
The square-wave voltage with a frequency of as high as 1.5 kHz is
proven to be favorable for the discrimination of the local ECL from
the surrounding signal. Using this new detection principle and resultant
capacitance microscopy, carcinoembryonic antigens (CEA) at amounts
of as low as 1 pg can be visualized. Further application of this approach
permits the direct imaging of CEA antigens on single MCF-7 cells through
the capacitance change after the formation of the antigen–antibody
complex. Successful visualization of the analyte without any ECL tag
will allow not only special capacitance microscopy for label-free
bioassays but also a novel ECL detection approach for the sensitive
detection of biomolecules.
CdSe hollow spherical assemblies composed of 5 nm nanoparticles have been synthesized sonochemically. During the process, amorphous Cd(OH)2, which acts as the in‐situ template, directs the growth of primary CdSe nanoparticles on its surface and their assembly into hollow spherical structures. The Figure is a schematic of the proposed mechanism for the formation of the hollow chalcogenide spheres.
Confined and free diffusion of phenol occur in the electric double layer (EDL) and extra‐EDL region in the nanochannels of porous anodic alumina (see picture). The inductive effect of the EDL electric field on the phenol molecules slows their diffusion, but it is negligible in the free‐diffusion region. The extent of the two regions depends on EDL thickness, and hence the diffusion flux increases with increasing ionic strength of the electrolyte.
Air electrodes with high catalytic activity are of great importance for rechargeable zinc-air batteries. Herein, a flexible, binder-free composite air electrode for zinc-air batteries is reported, which utilizes a lightweight, conductive, and crosslinked aerogel film of carbon nanotubes (CNTs) functioned as a 3D catalyst-supporting scaffold for bifunctional cobalt (II/III) oxides and as a current collector. The composite electrode shows high catalytic activities for both oxygen reduction reaction and oxygen evolution reaction, resulting from the synergistic effect of nitrogen-doped CNTs and spinel Co O nanoparticles. Solid-state Zn-air batteries assembled using such free-standing air electrodes (without the need of additional current collectors) are bendable and show low resistances, low charge/discharge overpotentials, and a high cyclic stability.
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