A new method turns noise into valuable data to enhance understanding of chemical reactions and material properties with ...

A team of NYU chemists and physicists are using cutting-edge tools—holographic microscopy and super-resolution imaging—to unlock how cells build and grow tiny, dynamic droplets known as biomolecular ...

A team of NYU chemists and physicists are using cutting-edge tools—holographic microscopy and super-resolution imaging—to ...

Three-dimensional (3D) imaging is essential for investigating cellular structure and dynamics. Traditional optical methods ...

Homeostatic plasticity, the brain's method of preserving equilibrium in neural circuits, relies heavily on spontaneous ...

This study overcomes the challenge of imaging low-copy-number proteins in live cells by combining Halo-SiR labeling with sparse deconvolution structured illumination microscopy (Sparse-SIM). Targeting ...

In this study, researcher developed a new imaging approach that combines two powerful techniques to solve this problem. First ...

This cutting-edge method, developed by an international team of scientists, uses the unique properties of the X-ray laser of European XFEL at Schenefeld near Hamburg, Germany—the largest X-ray laser ...

Explore how super-resolution microscopy reveals GPCR and RTK receptor dimerization, with a focus on D2 dopamine receptor function and disease relevance.

The protein SNAP-tag is a powerful tool for labeling proteins with synthetic fluorophores for bioimaging. Scientists at the Max Planck Institute for Medical Research in Heidelberg have engineered a ...

Technological developments are pushing the emerging super-resolution fluorescence microscopy techniques into the world of three-dimensional imaging.