According to the World Health Organization (WHO), almost 2 billion people each year are infected worldwide with flu-like pathogens including influenza. This is a contagious disease caused by viruses belonging to the family Orthomyxoviridae. Employee absenteeism caused by flu infection costs hundreds of millions of dollars every year. To successfully treat influenza virus infections, detection of the virus during the initial development phase of the infection is critical, when tens to hundreds of virus-associated molecules are present in the patient’s pharynx. In this study, we describe a novel universal diamond biosensor, which enables the specific detection of the virus at ultralow concentrations, even before any clinical symptoms arise. A diamond electrode is surface-functionalized with polyclonal anti-M1 antibodies, which then serve to identify the universal biomarker for the influenza virus, M1 protein. The absorption of the M1 protein onto anti-M1 sites of the electrode change its electrochemical impedance spectra. We achieved a limit of detection of 1 fg/ml in saliva buffer for the M1 biomarker, which corresponds to 5–10 viruses per sample in 5 minutes. Furthermore, the universality of the assay was confirmed by analyzing different strains of influenza A virus.
We report on the preparation method of nanocrystalline titanium dioxide modified with platinum by using nanosecond laser ablation in liquid (LAL). Titania in the form of anatase crystals has been prepared in a two-stage process. Initially, irradiation by laser beam of a titanium metal plate fixed in a glass container filled with deionized water was conducted. After that, the ablation process was continued, with the use of a platinum target placed in a freshly obtained titania colloid. In this work, characterization of the obtained nanoparticles, based on spectroscopic techniques--Raman, X-ray photoelectron and UV-vis reflectance spectroscopy--is given. High resolution transmission electron microscopy was used to describe particle morphology. On the basis of photocatalytic studies we observed the rate of degradation process of methylene blue (MB) (a model organic pollution) in the presence of Pt modified titania in comparison to pure TiO2--as a reference case. Physical and chemical mechanisms of the formation of platinum modified titania are also discussed here. Stable colloidal suspensions containing Pt modified titanium dioxide crystalline anatase particles show an almost perfect spherical shape with diameters ranging from 5 to 30 nm. The TiO2 nanoparticles decorated with platinum exhibit much higher (up to 30%) photocatalytic activity towards the degradation of MB under UV illumination than pure titania.
In this study, we have demonstrated the fabrication of novel materials called boron-doped carbon nanowalls (B:CNWs), which are characterized by remarkable electrochemical properties such as high standard rate constant (k°), low peak-to-peak separation value (ΔE) for the oxidation and reduction processes of the [Fe(CN)] redox system, and low surface resistivity. The B:CNW samples were deposited by the microwave plasma-assisted chemical vapor deposition (CVD) using a gas mixture of H/CH/BH and N. Growth results in sharp-edged, flat, and long CNWs rich in sp as well as sp hybridized phases. The achieved high values of k° (1.1 × 10 cm s) and ΔE (85 mV) are much lower compared to those of the glassy carbon or undoped CNWs. The enhanced electrochemical performance of the B:CNW electrode facilitates the simultaneous detection of DNA purine bases: adenine and guanine. Both separated oxidation peaks for the independent determination of guanine and adenine were observed by means of cyclic voltammetry or differential pulse voltammetry. It is worth noting that the determined sensitivities and the current densities were about 1 order of magnitude higher than those registered by other electrodes.
Titanium dioxide nanotubes gain considerable attention
as a photoactive material due to chemical stability, photocorrosion
resistance, or low-cost manufacturing method. This work presents scalable
pulsed laser modification of TiO2 nanotubes resulting in
enhanced photoactivity in a system equipped with a motorized table,
which allows for modifications of both precisely selected and any-large
sample area. Images obtained from scanning electron microscopy along
with Raman and UV–vis spectra of laser-treated samples in a
good agreement indicate the presence of additional laser-induced shallow
states within band gap via degradation of crystalline structure. However,
X-ray photoelectron spectroscopy spectra revealed no change of chemical
nature of the modified sample surface. Photoelectrochemical measurements
demonstrate superior photoresponse of laser-treated samples up to
1.45-fold for an energy beam fluence of 40 mJ/cm2 compared
to that of calcined one. According to the obtained results, optimal
processing parameters were captured. Mott–Schottky analysis
obtained from impedance measurements indicates an enormous (over an
order of magnitude) increase of donor density along with a +0.74 V
positive shift of flat band potential. Such changes in electronic
structure are most likely responsible for enhanced photoactivity.
Thus, the elaborated method of laser nanostructuring can be successfully
employed to the large-scale modification of titania nanotubes resulting
in their superior photoactivity. According to that, the results of
our work provide a contribution to wider applications of materials
based on titania nanotubes.
Nitrogen doped titania nanotubes were successfully sensitized by the electrochemical method, i.e.as-anodized titania was immersed in different amine (diethylenetriamine -DETA, triethylamine -TEA, and ethylenediamine -EDA) and urea (U) solutions and a constant potential was applied. The highly ordered morphology of fabricated N-TiO 2 was investigated by scanning electron microscopy. Spectroscopic techniques, i.e. UV-Vis spectroscopy, Raman spectroscopy, X-ray photoelectron spectroscopy and photoluminescence spectroscopy, were utilized to characterize absorbance capability and the crystalline phase, to confirm the presence of nitrogen atoms and to study charge recombination, respectively. The highest photocurrent under both UV-Vis and visible illumination (l 4 420 nm) was registered for the N-TiO 2 sample obtained from diethylenetriamine solution, used as a nitrogen precursor. The photocurrent density exhibited during UV-Vis irradiation by the most active nitrogen doped titania was 2.83 times higher compared to pure TiO 2 nanotubes. The photocatalytic activity studies demonstrated a significant improvement when N-TiO 2 -DETA (52%) and N-TiO 2 -U samples (49%) where used instead of undoped TiO 2 (27%). The presented results show that electrochemical doping with 0.5 M amine or urea solutions is a simple, cheap and effective strategy to introduce nitrogen atoms into the titania structure without affecting its morphology.
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