We introduce a precise three-dimensional (3D) localization method of spherical gold nanoparticle probes using model-based correlation coefficient mapping. To accomplish this, a stack of sample images at different z-positions are acquired, and a 3D intensity profile of the probe serving as the model is used to map out the positions of nanoparticles in the sample. By using this model-based correlation imaging method, precise localization can be achieved in imaging techniques with complicated point spread functions (PSF) such as differential interference contrast (DIC) microscopy. We demonstrated the localization precision of 4-7 nm laterally and 16 nm axially for 40-nm gold nanospheres at an imaging rate of 10 frames per second. The 3D superlocalization method was applied to tracking gold nanospheres during live endocytosis events.
In this study, dispersive liquid-liquid microextraction (DLLME) combined with ultra high pressure liquid chromatography (UHPLC)-tunable ultraviolet detection (TUV), was developed for pre-concentration and determination of trace levels of tetracyclines, including 4-epitetracycline, 4-epichlortetracycline, doxycycline, chlortetracycline oxytetracycline, tetracycline, 4-epianhydrotetracycline and anhydrotetracycline, in aqueous samples. La (III) was used as the chelating agent to form a hydrophobic complex compound with tetracyclines, followed by extraction with ionic liquids. Some important parameters that may affect extraction efficiencies were examined and optimized. Under the optimum conditions, linearity of the method was observed in the range of 0.1-200 lg L -1 , with correlation coefficients (r 2 ) [0.992. The limits of detection and quantification were 0.031-0.079 and 0.10-0.26 lg L -1 , respectively. The spiked recoveries of eight target compounds in river water, fishpond water and hog leachate were achieved in the range of 62.6-96.3, 58.9-94.5, 55.1-86.1%, respectively.
Multicolored semiconductor quantum dots have shown great promise for construction of miniaturized light-emitting diodes with compact size, low weight and cost, and high luminescent efficiency. The unique size-dependent luminescent property of quantum dots offers the feasibility of constructing single-color or full-color output light-emitting diodes with one type of material. In this paper, we have demonstrated the facile fabrication of blue-, green-, red- and full-color-emitting semiconductor quantum dot optical films via a layer-by-layer assembly technique. The optical films were constructed by alternative deposition of different colored quantum dots with a series of oppositely charged species, in particular, the new use of cationic starch on glass substrates. Semiconductor ZnSe quantum dots exhibiting blue emission were deposited for fabrication of blue-emitting optical films, while semiconductor CdTe quantum dots with green and red emission were utilized for construction of green- and red-emitting optical films. The assembly of integrated blue, green and red semiconductor quantum dots resulted in full-color-emitting optical films. The luminescent optical films showed very bright emitting colors under UV irradiation, and displayed dense, smooth and efficient luminous features, showing brighter luminescence in comparison with their corresponding quantum dot aqueous colloid solutions. The assembled optical films provide the prospect of miniaturized light-emitting-diode applications.
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