A team of researchers at the University of Ottawa developed a terahertz (THz) spectroscopy technique for recording movies in real time at 50,000 fps. High-speed video captures and slow-motion movies allow scientists to observe the mechanical dynamics of complex phenomena in detail. When the images in each frame are replaced by THz waves, the movies make it possible to monitor low-energy resonances and fast structural and chemical transitions in sample materials. As a result, the THz spectroscopy system, developed in collaboration with researchers from the Max Planck Institute for the Science of Light, could become a powerful tool for observing phenomena that are currently impossible to investigate because they are too fast, nonreproducible, or both. The system combines two spectroscopy techniques — chirped-pulse spectral encoding and a photonic time-stretch technique — with fast detection electronics. The first technique imprints the information carried by a THz pulse onto a chirped ...
Researchers led by UCLA professor Aydogan Ozcan developed a deep learning -enabled biosensor for multiplexed, point-of-care (POC) testing of disease biomarkers. POC biosensors provide remote and resource-limited communities with an economical, practical alternative to centralized laboratory testing. The UCLA-developed POC sensor includes a paper-based fluorescence vertical flow assay to simultaneously detect three biomarkers of acute coronary syndrome from human serum samples. The vertical flow assay is processed by a low-cost mobile reader, which quantifies the target biomarkers through trained neural networks. According to the researchers, the competitive performance of the multiplexed computational fluorescence vertical flow assay, along with its inexpensive, paper-based design and hand-held footprint, give the POC sensor promise as a platform to expand access to diagnostics in resource-limited settings. “Compared to a commonly used linear calibration method,...