Novel physicochemical approach to optical biosensing that leverages the unique properties of 1DZnO nanostructures. These nanostructures exhibit high surface-to-volume ratios, high isoelectric points, and even antimicrobial activity, making them ideal candidates for biosensor development.
Scientists found E. coli bacteria can move in sync when confined in connected micro-chambers, showing how order emerges in biological systems and enabling new oscillator designs.
While scientists routinely control single-outcome molecular reactions, controlling multiple-outcome reactions remains challenging yet crucial since not all outcomes are useful.
Scientists discover how nanoscale bumps and grooves on growing surfaces can influence cellular metabolism, offering new possibilities for medical therapies and tissue engineering.
