A dyad as photocatalyst for light-driven sulfide oxygenation with water as the unique oxygen atom source

With the objective to convert light energy into chemical oxidation energy, a ruthenium-based dyad constituted of the assembly of a photosensitizer and a catalytic fragment was synthesized. Upon irradiation with blue LEDs, and in the presence of an electron acceptor, the complex is able to catalyze selective sulfide oxygenation involving an oxygen atom transfer from water to the substrate. Electrochemical and photophysical studies highlighted a proton-coupled electron transfer (PCET) to access to a high valent oxidant Ru(IV) oxo species.     

On-chip pumping for pressure mobilization of the focused zones following microchip isoelectric focusing

Isoelectric focusing (IEF), traditionally accomplished in slab or tube gels, has also been performed extensively in capillary and, more recently, in microchip formats. IEF separations performed in microchips typically use electroosmotic flow (EOF) or chemical treatment to mobilize the focused zones past the detection point. This report describes the development and optimization of a microchip IEF method in a hybrid PDMS-glass device capable of controlling the mobilization of the focused zones past the detector using on-chip diaphragm pumping. The microchip design consisted of a glass fluid layer (separation channels), a PDMS layer and a glass valve layer (pressure connections and valve seats). Pressure mobilization was achieved on-chip using a diaphragm pump consisting of a series of reversible elastomeric valves, where a central diaphragm valve determined the volume of solution displaced while the gate valves on either side imparted directionality. The pumping rate could be adjusted to control the mobilization flow rate by varying the actuation times and pressure applied to the PDMS to actuate the valves. In order to compare the separation obtained using the chip with that obtained in a capillary, a serpentine channel design was used to match the separation length of the capillary, thereby evaluating the effect of diaphragm pumping itself on the overall separation quality. The optimized mIEF method was applied to the separation of labeled amino acids.     

Optimization of capillary electrophoresis conditions for a glucagon competitive immunoassay using response surface methodology

The capillary electrophoresis (CE) conditions for a competitive immunoassay of glucagon were optimized for highest sensitivity of the immunoassay and resolution of the electrophoretic peaks using a Box–Behnken design. Injection time, voltage ramp time, and separation voltage were varied between three levels and two responses, bound-to-free (B/F) ratio of the immunoassay peaks and resolution between the peaks, were measured. Analysis of variance was applied to fit a predictive model, and a desirability function was used to simultaneously optimize both responses. A 10-s injection, 1.6-min ramp time, and a 22-kV separation voltage were the conditions found when high B/F was given more emphasis than high resolution. To test the model, calibration curves of a glucagon immunoassay were measured at the optimum and least optimum CE conditions. Optimal conditions increased the sensitivity of the immunoassay by 388% compared to the least optimum conditions while maintaining adequate resolution.

Formation of Cyclobutane Thymine Dimers from UVA Photosensitization of Pyridopsoralen Monoadducted DNA

The present report provides evidence that thymine dimerization can be UVA photosensitized at a tetranucleotide, 5′-TATT-3′, by a 7-methyl-pyrido(3, 4-c)psoralen monoadduct in DNA. The efficiency of the photoprocess depends on the tetranucleotide flanking sequences. These results demonstrate that one DNA lesion can originate the contiguous formation of a second type of lesion and emphasize the sequence-specific response to interaction of drugs with DNA. Results are related to the sensitivity of DNA to 1, 10-phenanthroline-cuprous ion complex nucleolytic activity and discussed in terms of the major role of local deformability of DNA in interaction with ligands.     

Replacement of Volatile Acetic Acid by Solid SiO2@COOH Silica (Nano)Beads for (Ep)Oxidation Using Mn and Fe Complexes Containing BPMEN Ligand

Mn and Fe BPMEN complexes showed excellent reactivity in catalytic oxidation with an excess of co-reagent (CH₃COOH). In the straight line of a cleaner catalytic system, volatile acetic acid was replaced by SiO₂ (nano)particles with two different sizes to which pending carboxylic functions were added (SiO₂@COOH). The SiO₂@COOH beads were obtained by the functionalization of SiO₂ with pending nitrile functions (SiO₂@CN) followed by CN hydrolysis. All complexes and silica beads were characterized by NMR, infrared, DLS, TEM, X-ray diffraction. The replacement of CH₃COOH by SiO₂@COOH (100 times less on molar ratio) has been evaluated for (ep)oxidation on several substrates (cyclooctene, cyclohexene, cyclohexanol) and discussed in terms of activity and green metrics.     

Use of a capillary electrophoresis instrument with laser-induced fluorescence detection for DNA quantitation. Comparison of YO-PRO-1 and PicoGreen assays

Highly selective and sensitive assays are required for detection and quantitation of the small masses of DNA typically encountered in clinical and forensic settings. High detection sensitivity is achieved using fluorescent labeling dyes and detection techniques such as spectrofluorometers, microplate readers and cytometers. This work describes the use of a laser-induced fluorescence (LIF) detector in conjunction with a commercial capillary electrophoresis instrument for DNA quantitation. PicoGreen and YO-PRO-1, two fluorescent DNA labeling dyes, were used to assess the potential of the system for routine DNA analysis. Linearity, reproducibility, sensitivity, limits of detection and quantitation, and sample stability were examined for the two assays. The LIF detector response was found to be linear (R2 > 0.999) and reproducible (RSD < 9%) in both cases. The PicoGreen assay displayed lower limits of detection and quantitation (20 pg and 60 pg, respectively) than the YO-PRO-1 assay (60 pg and 260 pg, respectively). Although a small variation in fluorescence was observed for the DNA/dye complexes over time, quantitation was not significantly affected and the solutions were found to be relatively stable for 80 min. The advantages of the technique include a 4- to 40-fold reduction in the volume of sample required compared to traditional assays, a 2- to 20-fold reduction in the volume of reagents consumed, fast and automated analysis, and low cost (no specific instrumentation required).     

Psoralen derivatives and longwave ultraviolet irradiation are active in vitro against human melanoma cell line

Cutaneous malignant melanoma is a very serious form of skin cancer that arises from melanocytes. Currently there is no effective treatment for metastatic melanoma so intense clinical trials are evaluating new drugs for this human malignancy. Psoralens are a group of compounds that bind to DNA in rapidly dividing cells and with ultraviolet light in the A band (UVA) cause DNA crosslinking, thereby preventing cellular division. They are used in the treatment of psoriasis and cutaneous T-cell lymphoma among other skin and blood diseases. We have investigated the cytotoxic potential of three psoralen derivatives plus UVA exposure (PUVA) on a established cell line of human melanoma. Cells were treated with different concentrations of 8-methoxypsoralen (8-MOP), 4,5',8-trimethylpsoralen (TMP) and 7-methylpyridopsoralen (MPP), for 1 h and after exposure to UVA light (0.3 J/cm(2)) were allowed to recover over a 24-72 h period. Viability was assessed by the microculture 3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide (MTT) colorimetric assay. Cisplatin, one of the most important drugs in the chemotherapy of melanoma, was included for comparative studies. All the psoralen derivatives tested were markedly cytotoxic in a dose and post-exposure-time dependent manner. The IC(50) values for 72 h of post-exposure time were as follows: MPP=0.05+/-0.01, TMP=0.13+/-0.003 and 8-MOP=10.79+/-1.85 micromol/L. Regardless of the limitations of the in vitro model, our results suggested that the lower IC(50) values of TMP and MPP might be of clinical importance.     

Microfluidic chip-based protein capture from human whole blood using octadecyl (C18) silica beads for nucleic acid analysis from large volume samples

We have previously described the development of a novel capillary-based photopolymerized monolith that offered unprecedented efficiency (approximately 85%) for DNA extraction from pre-purified human genomic DNA [J. Wen, C. Guillo, J.P. Ferrance, J.P. Lander, Anal. Chem. 78 (2006) 1673]. However, the major drawback associated with this phase was the limited binding capacity and low extraction efficiency (<40%) when purifying nucleic acids from a volume of whole blood greater than 0.1 microL. The limited DNA binding capacity, hypothesized to result from an overwhelming mass of protein overloading the monolith phase, severely limits the clinical utility, which will require a whole blood DNA capacity orders of magnitude larger. One proposed solution involved use of a protein capture bed to remove the majority of the protein present in blood before nucleic acid extraction was performed. To evaluate this, microchips with different channel configurations were designed and tested containing silica beads with various reversed phases, and their protein capture efficiency determined. Triton X-100 in the cell lysis buffer was found to be a critical component, greatly affecting the binding of proteins to the C18 reversed phase. An optimum Triton X-100 concentration of 0.1% was determined to enhance red and white blood cell lysis without adversely affecting protein binding to the C18 phase. A parallel 4-chamber design was found to be optimal, with 70% of the proteins (1020+/-45 microg) from a load solution containing 10 microL of whole blood captured on the C18 phase in a single microdevice. Electrophoretic analysis of the proteins in the flow-through of the C18 phase showed the absence of hemoglobin and larger proteins/peptides, indicating that they had been captured by the C18 phase, preventing these polymerase chain reaction inhibitory proteins from reaching and binding to the subsequent matrix which would be used for DNA capture.     

Two-color electrophoretic immunoassay for simultaneous measurement of insulin and glucagon content in islets of Langerhans

A multianalyte CE competitive immunoassay using two-color detection was developed to measure insulin and glucagon in islets of Langerhans. Insulin was quantified with FITC-insulin (Ins*) and anti-insulin antibodies (Ins Ab) and glucagon was quantified with Cy5-glucagon (Glu*) and anti-glucagon antibodies (Glu Ab). A 3 mW Ar(+) laser at 488 nm and a 25 mW laser diode at 635 nm were used to excite FITC and Cy5, respectively. Fluorescence was split with a half-silvered mirror and passed through a 520 +/- 20 nm bandpass filter or a 663 nm longpass filter for the detection of insulin and glucagon, respectively. The two-color detection format enabled independent quantitation of both analytes even with concentrations of insulin immunoassay reagents 20-fold higher than glucagon reagents. Simultaneous calibration curves were generated and used to determine insulin and glucagon content in islets of Langerhans. Amounts of insulin and glucagon were 56.6 +/- 3.2 and 1.0 +/- 0.5 ng/islet, respectively. LODs were 7 nM insulin and 3 nM glucagon. The assay will be applicable to fast monitoring of multiple peptides secreted from islets of Langerhans and can be applied to other systems for the quantitation of multiple analytes with large differences in concentrations.