The immobilization of anti-IgG on Au-colloid modified gold electrodes has been investigated. A cleaned gold electrode was first immersed in a mercaptoethylamine (AET) solution, and then gold nanoparticles were chemisorbed onto the thiol groups of the mercaptoethylamine. Finally, anti-IgG was adsorbed onto the surface of the gold nanoparticles. Potentiometric immunosensor, cyclic voltammetry, and electrochemical impedance techniques were used to investigate the immobilization of anti-IgG on Au colloids. In the impedance spectroscopic study, an obvious difference of the electron transfer resistance between the Au-colloid modified electrode and the bare gold electrode was observed. The cyclic voltammogram tends to be more irreversible with increased anti-IgG concentration. Using the potentiometric immunosensor, the proposed technique is based on that the specific agglutination of antibody-coated gold nanoparticles, averaging 16 nm in diameter, in the presence of the corresponding antigen causes a potential change that is monitored by a potentiometry. It is found that the developed immunoagglutination assay system is sensitive to the concentration of IgG antigen as low as 12 ng mL(-1). Experimental results showed that the developed technique is in satisfactory agreement with the ELISA method, and that gold nanoparticles can be used as a biocompatible matrix for antibody or antigen immobilization. 相似文献
The cover picture shows that sequential 1,1‐dihydrosilylation of terminal aliphatic alkynes with primary silanes enabled by one earth‐abundant cobalt catalyst has been developed. This protocol is operationally simple using readily available aliphatic alkynes, including simple acetylene and complex drug derivative, for efficient access to valuable gem‐bis(dihydrosilyl)alkanes in highly regioselective and atom‐economic manners. Corresponding asymmetric transformations are achieved with excellent enantioselectivities. More details are discussed in the article by Lu et al. on page 457–461.
Zusammenfassung An Stelle eines Choppers wird zur Modulation des flammenspektrometrischen Signals die Probenflüssigkeit periodisch der Flamme zugeführt (intermittierende Zerstäubung). Es wird zunächst über die beobachtete Eigenmodulation der Zerstäubung berichtet und danach über die intermittierende Zerstäubung mit Frequenzen bis zu 50 Hz. Anschließend wird an Hand von Beispielen gezeigt, daß sich die intermittierende Zerstäubung als besonders vorteilhaft in der Absorptions-Flammenspektrometrie erweist. Wird das Gleichlicht des Hintergrundstrahlers mittels der intermittierenden Zerstäubung in der Flamme moduliert und ein Wechselstromverstärker verwendet, so fallen der 0- und 100%-Durchlässigkeitspunkt zusammen. Bei der Registrierung über die Wellenlänge werden dann nur solche Linien angezeigt, welche in der Flamme das eingestrahlte Licht absorbieren.
Summary For modulating the flame spectrometric signal without using a chopper the sample is introduced into the flame periodically (intermittent atomisation). First, the observed self-modulation of the atomisation is described and subsequently the intermittent atomisation with frequencies up to 50 cps. Some examples demonstrate that intermittent atomisation proves to be especially advantageous in absorption flame spectrometry. When modulating the light of the dc-operated line source by means of intermittent atomisation and using ac-amplification of the modulated signal the 0- and 100%-transmittance points of the transmittance scale are the same. When scanning over the wave length only such lines are detected which absorb the light of the background source.
Der Fa. Siemens-Reiniger Werke AG., Erlangen, und insbesondere Herrn Ing. Engel danken wir auch an dieser Stelle für die leihweise Überlassung des Flüssigkeitsstrahloscillographen Cardirex 31 B. — Herrn K. RÜdiger danken wir für die wertvollen Hinweise und für die Durchführung der Werkstattarbeiten. 相似文献
Current methods for single nucleotide polymorphism (SNP) analysis are time-consuming and complicated. We aimed at development of one-step real-time fluorescence mutant-allele-specific amplification (MASA) method for rapid SNP analysis. The method is a marriage of two technologies: MASA primers for target DNA and a double-stranded DNA-selective fluorescent dye, SYBR Green I. Genotypes are separated according to the different threshold cycles of the wild-type and mutant primers. K-rar oncogene was used as a target to validate the feasibility of the method. The experimental results showed that the different genotypes can be clearly discriminated by the assay. The real-time fluorescence MASA method will have an enormous potential for fast and reliable SNP analysis due to its simplicity and low cost. 相似文献