ZnO nanosheets, nanonails, and well-aligned nanorods were fabricated on Zn foils by a solvothermal approach using ethanol as the solvent. A lower synthesis temperature and a shorter time period favor the formation of nanosheets. By optimizing the synthesis temperature and time period, ZnO nanonails with a hexagonal cap and a long stem could be produced. A higher temperature was not favorable to produce uniform and smooth nanorods. Well-aligned ZnO nanorod arrays were produced with diameters within 100-250 nm and lengths up to approximately 6 microm when NaOH was added to the solvent. By optimizing the reaction parameters, the morphology, size, and orientation of the nanoforms could be tailored. The ZnO nanorods exhibit an excitonic strong UV emission and a defect-related broad green emission at room temperature. The defect-related green emission band decreased with the improvement of the degree of alignment of the nanorods.
Anisotropic growth of ZnO nanorod arrays on ZnO thin films was achieved at a temperature of 90 degrees C by a surfactant-assisted soft chemical approach with control over size and orientation. ZnO thin films with c-axis preferred orientation had been achieved by the sol-gel technique. Lengths, diameters, and the degree of alignment of the ZnO nanorods were controlled by changing the experimental parameters. It was observed that the surfactant was essential to restrict the lateral growth of the nanorods, whereas the pH level of the reaction medium controlled the length of the nanorods. On the other hand, the orientation of the nanorods depended on the crystalline orientation of the film as well as the pH of the reaction medium. Room-temperature photoluminescence studies revealed that the ZnO nanorods with the best alignment exhibited the best emission property. The ZnO nanorods exhibited a strong UV emission peak at approximately 3.22 eV, ascribed to the band-edge emission. The field emission studies of the well-aligned nanorod arrays exhibited a low turn-on field of 1.7 V/microm to get an emission current density of 0.1 microA/cm(2).
Small
extracellular vesicles (sEVs) generated from the endolysosomal
system, often referred to as exosomes, have attracted interest as
a suitable biomarker for cancer diagnostics, as they carry valuable
biological information and reflect their cells of origin. Herein,
we propose a simple and inexpensive electrical method for label-free
detection and profiling of sEVs in the size range of exosomes. The
detection method is based on the electrokinetic principle, where the
change in the streaming current is monitored as the surface markers
of the sEVs interact with the affinity reagents immobilized on the
inner surface of a silica microcapillary. As a proof-of-concept, we
detected sEVs derived from the non-small-cell lung cancer (NSCLC)
cell line H1975 for a set of representative surface markers, such
as epidermal growth factor receptor (EGFR), CD9, and CD63. The detection
sensitivity was estimated to be ∼175000 sEVs, which represents
a sensor surface coverage of only 0.04%. We further validated the
ability of the sensor to measure the expression level of a membrane
protein by using sEVs displaying artificially altered expressions
of EGFR and CD63, which were derived from NSCLC and human embryonic
kidney (HEK) 293T cells, respectively. The analysis revealed that
the changes in EGFR and CD63 expressions in sEVs can be detected with
a sensitivity in the order of 10% and 3%, respectively, of their parental
cell expressions. The method can be easily parallelized and combined
with existing microfluidic-based EV isolation technologies, allowing
for rapid detection and monitoring of sEVs for cancer diagnosis.
The solvothermal process was employed to grow ZnO nanorods at low temperature on
conducting substrate, which is extremely important for making efficient electrical contacts
in various applications based on ZnO nanorods. Efforts were made to find the ideal
growth parameters for better alignment of the ZnO nanorods with a view to tailor
their luminescent properties. The ZnO nanorod arrays were characterized by
scanning electron microscopy (SEM), transmission electron microscopy (TEM),
energy dispersive analysis of x-rays (EDAX) and x-ray diffraction study. The ZnO
nanorod arrays were found to have excellent UV emission properties at room
temperature. Aligned ZnO nanorod arrays exhibit good field emission properties,
revealing their applicability as cathode materials for field emission based devices.
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