Microscopy technique makes finer images of deeper tissue, more quickly
Researchers could rapidly obtain high-resolution images of blood vessels and neurons within the brain.
Researchers could rapidly obtain high-resolution images of blood vessels and neurons within the brain.
Radioactive molecules are sensitive to subtle nuclear phenomena and might help physicists probe the violation of the most fundamental symmetries of nature.
MIT engineers design the first synthetic circuit that consists entirely of fast, reversible protein-protein interactions.
Study offers evidence, based on gravitational waves, to show that the total area of a black hole’s event horizon can never decrease.
Study demonstrates the power of low-cost air quality sensors during volcanic eruption.
The design could lead to conformable wearable monitors to track skin cancer and other conditions.
Study suggests a common mechanism underlies some behavioral traits seen in autism and schizophrenia.
Graduate student Ellen Zhong helped biologists and mathematicians reach across departmental lines to address a longstanding problem in electron microscopy.
How 3D-printed models of neuronal axons could accelerate development of new therapies to treat neurodegenerative disorders.
In a 3Q, Salvatore Vitale describes how gravitational-wave signals suggest black holes completely devoured their companion neutron stars.
The sensor technology could also be used to create clothing that detects a variety of pathogens and other threats.
By making the microbes more tolerant to toxic byproducts, researchers show they can use a wider range of feedstocks, beyond corn.
As “visual recognition memory” emerges in the visual cortex, one circuit of inhibitory neurons supplants another, and slower neural oscillations prevail.
Alumni of the MIT New Engineering Education Transformation Program (NEET) worked together remotely from across the globe to design thinking machines.
The new carbon-based material could be a basis for lighter, tougher alternatives to Kevlar and steel.