Preparation of cationic latices comprising hollow thermostable particles

A method is described for the preparation of cationic latices comprising submicron hollow particles for a possible application as a thermally stable polymeric pigment in coatings or pigmented compositions on the basis of thermosetting polymers cured at temperatures up to 170–190 °C. The method is based on the deposition of melamine–formaldehyde resin in the form of cationic colloid onto anionic hollow particles resulting in the recharging of anionic hollow particles and the formation of an outer melamine shell, which provides thermal stability of the hollow particles at curing and application of pigmented coatings and compositions. © 2004 Wiley Periodicals, Inc. J Polym Sci Part A: Polym Chem 42: 2225–2234, 2004     

Implementation of a novel low‐noise InGaAs detector enabling rapid near‐infrared multichannel Raman spectroscopy of pigmented biological samples

Pigmented tissues are inaccessible to Raman spectroscopy using visible laser light because of the high level of laser‐induced tissue fluorescence. The fluorescence contribution to the acquired Raman signal can be reduced by using an excitation wavelength in the near infrared range around 1000 nm. This will shift the Raman spectrum above 1100 nm, which is the principal upper detection limit for silicon‐based CCD detectors. For wavelengths above 1100 nm indium gallium arsenide detectors can be used. However, InGaAs detectors have not yet demonstrated satisfactory noise level characteristics for demanding Raman applications. We have tested and implemented for the first time a novel sensitive InGaAs imaging camera with extremely low readout noise for multichannel Raman spectroscopy in the short‐wave infrared (SWIR) region. The effective readout noise of two electrons is comparable to that of high quality CCDs and two orders of magnitude lower than that of other commercially available InGaAs detector arrays. With an in‐house built Raman system we demonstrate detection of shot‐noise limited high quality Raman spectra of pigmented samples in the high wavenumber region, whereas a more traditional excitation laser wavelength (671 nm) could not generate a useful Raman signal because of high fluorescence. Our Raman instrument makes it possible to substantially decrease fluorescence background and to obtain high quality Raman spectra from pigmented biological samples in integration times well below 20 s. Copyright © 2015 John Wiley & Sons, Ltd.     

Retinal proteins associated with redox regulation and protein folding play central roles in response to high glucose conditions

Diabetic retinopathy typically causes poor vision and blindness. A previous study revealed that a high blood glucose concentration induces glycoxidation and weakens the retinal capillaries. Nevertheless, the molecular mechanisms underlying the effects of high blood glucose induced diabetic retinopathy remain to be elucidated. In the present study, we cultured the retinal pigmented epithelial cell line ARPE‐19 in mannitol‐balanced 5.5, 25, and 100 mM glucose media and investigated protein level alterations. Proteomic analysis revealed significant changes in 137 protein features, of which 124 demonstrated changes in a glucose concentration dependent manner. Several proteins functionally associated with redox regulation, protein folding, or the cytoskeleton are affected by increased glucose concentrations. Additional analyses also revealed that cellular oxidative stress, including endoplasmic reticulum stress, was significantly increased after treatment with high glucose concentrations. However, the mitochondrial membrane potential and cell survival remained unchanged during treatment with high glucose concentrations. To summarize, in this study, we used a comprehensive retinal pigmented epithelial cell based proteomic approach for identifying changes in protein expression associated retinal markers induced by high glucose concentrations. Our results revealed that a high glucose condition can induce cellular oxidative stress and modulate the levels of proteins with functions in redox regulation, protein folding, and cytoskeleton regulation; however, cell viability and mitochondrial integrity are not significantly disturbed under these high glucose conditions.     

Efficient photopolymerization of thick pigmented systems using upconversion nanoparticles‐assisted photochemistry

Photopolymerization of thick pigmented systems still remains challenging due to the light screening effect of the pigments. Here, we present a facile method based on upconversion nanoparticles (UCNPs)‐assisted photochemistry to achieve efficient photopolymerization and improved curing depth of pigmented systems. Under a 980‐nm laser irradiation, UCNPs are able to convert NIR light into UV and visible light to activate photoinitiators for the initiation of polymerization. Influencing factors on photopolymerization were systematically investigated. With optimal parameters, 25.5 mm of photopolymerization depth combined with 70% of maximal double bond conversion was obtained. The peak temperature of 120.4 °C during UCNPs‐assisted photopolymerization is comparable with or lower than that of some reported frontal photopolymerization applied to prepare functional composite polymeric materials. Both indentation hardness and reduced modulus of the photocured materials using UCNPs as internal lamps were higher than those of the reference cured under traditional blue LED light. © 2018 Wiley Periodicals, Inc. J. Polym. Sci., Part A: Polym. Chem. 2018 , 56, 994–1002     

Quantification of azoxystrobin and identification of two novel metabolites in lettuce via liquid chromatography–quadrupole-linear ion trap (QTRAP) mass spectrometry

Pesticide metabolite identification is gaining increased attention because of the interest in potential metabolite toxicity. Azoxystrobin is one of the most prevalent pesticide residues in foods in Europe. The majority of azoxystrobin metabolites have been identified using radiolabelled standards, which are either expensive or not readily available. Thus, alternative approaches for metabolite identification are desirable. Here, an LC-MS/MS method for quantifying azoxystrobin and identifying its metabolites using quadrupole-linear ion trap mass spectrometry is reported. Seven metabolites of azoxystrobin were identified 2 and 4 weeks after spraying lettuce with azoxystrobin. Among them, two metabolites are reported for the first time. The hydrolysis, reduction, hydroxylation, photoisomerisation and hydrolytic cleavage of ether bonds are identified as biotransformation processes involved in azoxystrobin metabolism in lettuce.