Lodbergmcmanus1331

We have developed a versatile label-free surface-enhanced Raman spectroscopic platform for detecting various biotargets via proximity hybridization-triggered DNA assembly based on the 736 cm-1 Raman peak of adenine breathing mode. We initially immobilized the first probe to AuNPs and modified the second with poly adenine. Presence of target DNA or protein molecules assembled a sandwich complex that brought the poly adenine close to the AuNPs surface, generating Raman signals, that were proportional to target molecule concentration. These approach exhibits high sensitivity, with a detection limit of 5.4 pM, 47 fM, and 0.51 pg/mL for target DNA, thrombin and CEA, respectively. Owing to a one step proximity dependent complex formation, this technique is simple and can be completed within 40 min, making it a promising candidate for point-of-care testing applications.The most effective utilization of platinum (Pt) in fuel cells is achieved through the use of nanoparticles (NPs) that offer a large electrochemically active surface area. Because the stability of NPs decreases as they become smaller, their size and size distribution must be known in order to optimize the catalysts' durability, while offering high catalytic activity. Single particle inductively coupled plasma mass spectrometry (spICPMS) can quantify the mass of metallic NPs suspended in aqueous medium, which can then be converted into a size if the NPs' shape, density and composition are known. In this study, for the first time, spICPMS was compared to transmission electron microscopy (TEM) for the characterization of 10 nm Pt NPs. After verifying the accurate sizing of commercial Pt NPs with diameters of 30, 50 and 70 nm, spICPMS with solution calibration was applied to laboratory-synthesized 10 nm Pt NPs possessing a near spherical shape and 10 ± 2 nm diameter according to TEM. The same NPs were also analyzed by spICPMS with Pt size calibration using Pt NPs standards. Irrespectively of the calibration strategy, spICPMS measured the entire population of 659 Pt NPs (6-65 nm), while TEM analyzed the 500 Pt NPs that appeared isolated in the field of view (6-18 nm). Analysis of the size distribution histograms revealed that the modal and mean diameters were respectively 10 and 11 ± 2 nm using solution calibration, and 12 and 13 ± 2 nm using particle size calibration. Both of these mean diameters are in agreement with the TEM measurements according to a Student's t-test at the 95% confidence level, demonstrating that spICPMS, with a size detection limit of 6 nm, can accurately quantify 10-nm Pt NPs while at the same time analyzing the entire sample.An organic-inorganic hybrid monolith incorporated with titanium dioxide nanotubes (TNTs) and hydrophilic deep eutectic solvents (DESs) was prepared and evaluated by the isolation of proteins using solid phase microextraction. Selinexor A typical polymerization system was composed of choline chloride/methacrylic acid (ChCl/MAA, DESs monomer), glycidyl methacrylate (GMA), as well as ethylene glycol dimethacrylate (EDMA) in the presence of TNTs. Then the epoxy groups on the surface of the resulting monolith were modified with amino groups. The synergistic effect of TNTs and DESs monomer to improve the enrichment performance of the sorbent significantly was demonstrated. Compared with the corresponding TNTs/DESs-free monolith, the recoveries of BSA and OVA were increased to 98.6% and 92.7% (RSDs less then 2.0%), with an improvement of more than 60.0%. With a correlation coefficient of determination (R2) higher than 0.9995, the enrichment factors (EFs) were 21.9-28.3-fold. In addition, the resulting monolith was further applied to specifically capture proteins from rat liver according to their pI value, followed by HPLC-MS/MS analysis. The results indicated that the developed monolith was an effective material to isolate protein species of interest according to the pI value of target proteins.Stir-bar sorptive extraction (SBSE) is a popular solvent-less sample preparation method, which is widely applied for the sampling and preconcentration of a wide range of non-polar solutes. A typical stir-bar for SBSE is composed of a polydimethylsiloxane (PDMS) film, coated onto a glass jacket with an incorporated magnet core. Sampling is carried out by direct immersion or by exposing the stir-bar to the headspace of the sample. To-date the majority of reported SBSE devices have used PDMS as the sorbent, with a few alternative commercially SBSE coatings available (such as polyethylene glycol and polyacrylate), which limits the applicability of SBSE to more polar and hydrophilic solutes. The interest in more selective extraction has been the driving force behind the recent development of novel SBSE coatings, particularly those exhibiting selectivity towards more polar solutes. During the last decade, a significant number of novel SBSE coatings were introduced utilising different fabrication approaches, including surface adhesion, molecular imprinting, sol-gel technology, immobilised monoliths, and solvent exchange processes. A range of nano- and micro-carbon-based materials, functional polymers, metal organic frameworks (MOFs), and inorganic nanoparticles have been employed for this purpose. Some of these SBSE coatings have exhibited higher thermal and chemical stability and delivered wider selectivity profiles. This review aims to summarise these significant developments, reported over the past six years, with specific attention to novel materials and selectivity for extending the potential applications of SBSE.The detection of phenolic compounds is relevant not only for their possible benefits to human health but also for their role as chemical pollutants, including as endocrine disruptors. The required monitoring of such compounds on-site or in field analysis can be performed with electrochemical biosensors made with polyphenol oxidases (PPO). In this review, we describe biosensors containing the oxidases tyrosinase and laccase, in addition to crude extracts and tissues from plants as enzyme sources. From the survey in the literature, we found that significant advances to obtain sensitive, robust biosensors arise from the synergy reached with a diversity of nanomaterials employed in the matrix. These nanomaterials are mostly metallic nanoparticles and carbon nanostructures, which offer a suitable environment to preserve the activity of the enzymes and enhance electron transport. Besides presenting a summary of contributions to electrochemical biosensors containing PPOs in the last five years, we discuss the trends and challenges to take these biosensors to the market, especially for biomedical applications.