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A new high-resolution virtual microscopy technique enables the rapid visualisation of tissue, paving the way for histopathology analysis during surgery.
A new label-free technique has been developed for molecularly specific exosome biosensing in diagnostics and biomarker detection.
The Pan-European Solid-State NMR Infrastructure for Chemistry-Enabling Access will offer researchers access to over 30 NMR spectrometers.
This whitepaper overviews phenotypic and functional characterisation of CAR-T cells with advanced flow cytometry and live-cell analysis.
The statistical method known as maximum entropy could improve cryogenic electron microscopy (cryo-EM) for more effective drug treatments.
The Wyss Centre has announced a collaborative project to improve understanding of the brain cancer glioblastoma and develop new personalised therapies.
A comprehensive and interactive digital guide has been released by Sartorius, with real-time, live-cell imaging and analysis including links to application pages, videos and protocols.
Scientists have revealed a way to use gene therapy to turn glial brain cells into neurons, restoring vision and potentially restoring motor function.
1 October 2021 | By Sartorius
Join this roundtable of industry experts as they discuss technologies, best practices and strategies for delivering robust, stable, high-yielding cell lines to accelerate and streamline the drug discovery process.
Scientists at the New York University (NYU) Abu Dhabi have used nuclear magnetic resonance (NMR) techniques to determine the structure of a specific nanobody, Nb23. Drug Target Review’s Victoria Rees spoke with lead researcher Professor Gennaro Esposito to find out how their findings could lead to a better understanding of…
An imaging technique identified emerging drugs that activate the STING protein to alter metabolic pathway activity in cancer cells.
Sphingosine-1 phosphate was found to regulate blood glow in cerebral blood vessels in mice, presenting a potential therapeutic target.
Researchers have developed an inexpensive method for visualising blood flow in the brain that can discern the motions of individual blood cells.