Insights into the structure and movement of T cell surface proteins could lead to new ways to fight cancers, infections and other diseases.
With unprecedented sensitivity and resolution from state-of-the-art magnets, scientists have identified for the first time the cell wall structure of one of the most prevalent and deadly fungi.
If engineers build stronger magnets, scientists promise they will come … and that discoveries will follow.
A technique called dynamic nuclear polarization is hitting its stride, using electrons to shine a light on complex molecules.
This work investigates a series of oxoiron complexes that serve as models towards understanding the mechanism of catalysis for certain iron-containing enzymes.
ICR technology helps identify new kinds of hemoglobin abnormalities.
Protein oxidative damage is a common occurrence in a number of diseases, including cancer, neurodegenerative, and cardiovascular disease. Yet, little is known about its contribution to these illnesses. We developed a new technique, utilizing an infrared laser in combination with a mass spectrometer, to selectively identify sites of oxidation in complex protein mixtures. This sensitive and rapid platform may outperform current techniques and thus shed light on the involvement of oxidative damage in each of these diseases.
Dylan Murray wants to sabotage processes that can lead to neurodegenerative disease.
Research sheds new light on the formation of harmful structures that can lead to neurodegenerative diseases.
A lot of the research conducted in powerful magnets ends up having a powerful effect on our day-to-day lives.