Cellular microvesicles and nanovesicles (exosomes) are involved in many disease processes and have major potential as biomarkers. However, developments in this area are constrained by limitations in the technology available for their measurement. Here we report on the use of fluorescence nanoparticle tracking analysis (NTA) to rapidly size and phenotype cellular vesicles. In this system vesicles are visualized by light scattering using a light microscope. A video is taken, and the NTA software tracks the brownian motion of individual vesicles and calculates their size and total concentration. Using human placental vesicles and plasma, we have demonstrated that NTA can measure cellular vesicles as small as ∼50 nm and is far more sensitive than conventional flow cytometry (lower limit ∼300 nm). By combining NTA with fluorescence measurement we have demonstrated that vesicles can be labeled with specific antibody-conjugated quantum dots, allowing their phenotype to be determined.From the Clinical EditorThe authors of this study utilized fluorescence nanoparticle tracking analysis (NTA) to rapidly size and phenotype cellular vesicles, demonstrating that NTA is far more sensitive than conventional flow cytometry.
The development of more efficient electrical storage is a pressing requirement to meet future societal and environmental needs. This demand for more sustainable, efficient energy storage has provoked a renewed scientific and commercial interest in advanced capacitor designs in which the suite of experimental techniques and ideas that comprise nanotechnology are playing a critical role. Capacitors can be charged and discharged quickly and are one of the primary building blocks of many types of electrical circuit, from microprocessors to large-sale power supplies, but usually have relatively low energy storage capability when compared with batteries. The application of nanostructured materials with bespoke morphologies and properties to electrochemical supercapacitors is being intensively studied in order to provide enhanced energy density without comprising their inherent high power density and excellent cyclability. In particular, electrode materials that exploit physical adsorption or redox reactions of electrolyte ions are foreseen to bridge the performance disparity between batteries with high energy density and capacitors with high power density. In this review, we present some of the novel nanomaterial systems applied for electrochemical supercapacitors and show how material morphology, chemistry and physical properties are being tailored to provide enhanced electrochemical supercapacitor performance.
Y2O3:Eu nanocrystals in the size range 70–100 nm have been synthesized with a photoluminescence efficiency 10–20 % higher than that of the commercial bulk material. The Figure shows nanocrystalline Y2O3:Eu after firing of the precursor material. It can be seen that the crystals are structurally perfect, i.e., no defects are found within the crystal structure.
A simple extension of the reflection high-energy electron diffraction oscillation technique to vicinal surfaces provides a means of studying surface diffusion during molecular beam epitaxial growth. The basis of the method is described and some preliminary results for Ga diffusion during the growth of GaAs films with (001) 2×4 and 3×1 reconstructed surfaces are presented.
The quantum spin properties of nitrogen-vacancy defects in diamond have diverse applications including quantum computing and communications 1 , but nanodiamonds also have attractive properties for in vitro biosensing, including brightness 2 , low cost 3 , and selective manipulation of their emission 4 . Nanoparticle-based biosensors are vital for early disease detection, however, often lack the required sensitivity. Here we investigated fluorescent nanodiamonds as an ultra-sensitive label for in vitro diagnostics, using a microwave field to modulate emission intensity 5 , and frequency-domain analysis 6 to separate the signal from background autofluorescence 7 , which typically limits sensitivity.We focused on the common, low-cost lateral flow format as an exemplar, achieving detection limits of 8.2 × 10 −19 M for a biotin-avidin model, 10 5 -fold more sensitive than gold nanoparticles; and a use-case demonstration of single-copy detection of HIV-1 RNA with a short 10-minute isothermal amplification step, including a pilot using a clinical plasma sample with an extraction step. This ultra-sensitive quantum-diagnostics platform is applicable to numerous diagnostic test formats and diseases with the potential to transform early diagnosis, benefiting patients and populations.Rapid point-of-care tests have transformed access to disease testing in a variety of community settings, including clinics, pharmacies and the home 30 . Among the most common tests worldwide are paper microfluidic lateral flow assays (LFAs), with 276 million sold in 2017 for malaria alone 31 . LFAs satisfy many of the REASSURED criteria 32 for diagnostics, however, despite widespread use they are still limited by inadequate sensitivity to detect the low levels of biomarkers necessary for early disease detection.Fluorescent markers can be highly sensitive, but are practically limited by background fluorescence from the sample, substrate, or readout technique. In the case of nitrocellulose substrates used in LFAs, there is a significant background autofluorescence 7 , which inherently limits sensitivity. Various methods have been reported to reduce this effect, such as membrane modification to reduce background fluorescence 33 , exciting in the nearinfrared range and using upconverting nanoparticles 34 , and time-gated detection using longpersistent phosphors 35 to separate background fluorescence, which has a shorter lifetime.These methods have shown ∼10-fold improvements in sensitivity over gold nanoparticles, limited by relatively low brightness.Here we show the use of FNDs as a fluorescent label in an LFA format as a demonstrator of their first use for in vitro diagnostics, taking advantage of their high brightness and selective modulation. The use of a narrowband resonator allows for the lowpower generation of microwave-frequency electromagnetic fields, suitable for a point-ofcare device, to efficiently separate the signal from the background in the frequency domain by lock-in 6 detection. We aimed, after characterisation, functionalisation,...
With mounting concerns over climate change, the utilisation or conversion of carbon dioxide into sustainable, synthetic hydrocarbons fuels, most notably for transportation purposes, continues to attract worldwide interest. This is particularly true in the search for sustainable or renewable aviation fuels. These offer considerable potential since, instead of consuming fossil crude oil, the fuels are produced from carbon dioxide using sustainable renewable hydrogen and energy. We report here a synthetic protocol to the fixation of carbon dioxide by converting it directly into aviation jet fuel using novel, inexpensive iron-based catalysts. We prepare the Fe-Mn-K catalyst by the so-called Organic Combustion Method, and the catalyst shows a carbon dioxide conversion through hydrogenation to hydrocarbons in the aviation jet fuel range of 38.2%, with a yield of 17.2%, and a selectivity of 47.8%, and with an attendant low carbon monoxide (5.6%) and methane selectivity (10.4%). The conversion reaction also produces light olefins ethylene, propylene, and butenes, totalling a yield of 8.7%, which are important raw materials for the petrochemical industry and are presently also only obtained from fossil crude oil. As this carbon dioxide is extracted from air, and re-emitted from jet fuels when combusted in flight, the overall effect is a carbon-neutral fuel. This contrasts with jet fuels produced from hydrocarbon fossil sources where the combustion process unlocks the fossil carbon and places it into the atmosphere, in longevity, as aerial carbon - carbon dioxide.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.
hi@scite.ai
334 Leonard St
Brooklyn, NY 11211
Copyright © 2024 scite LLC. All rights reserved.
Made with 💙 for researchers
Part of the Research Solutions Family.