Global health is changing as a result of developments in life sciences research and technology, and these advancements have the potential to offer innovative and improved approaches to promote a ...

Stanford researchers have combined two microscopy techniques to create a one-of-a-kind instrument that can show cell ...

The rapid evolution of microscopy techniques has transformed our ability to visualise biological structures and processes at unprecedented resolutions. Advances in live‐cell imaging, super‐resolution ...

Light-sheet fluorescence microscopy (LSFM), with its innovative design of selective plane illumination and orthogonal ...

Modern bioassays tend to fall under three common modalities: colorimetric, luminometric or fluorometric. Colorimetric assays record the amount of light absorbed by a reporter compound. This absorbance ...

In recent years, fluorescence quenching microscopy (FQM) 1-3 has emerged as a viable technique that allows for the swift, cost-effective, and accurate imaging of two-dimensional (2D) materials like ...

Pushing the MINFLUX technique to higher spatial and temporal precision allows protein dynamics to be observed under physiological conditions. Scientists led by Nobel Laureate Stefan Hell at the Max ...

One widely used technique in cellular and molecular biology is fluorescence microscopy, which is employed both to observe the interactions between various components of an organism and for spatial ...

Explore advances in protein imaging techniques and spatial proteomics. Learn how modern imaging tools reveal protein dynamics and organization in cells.

Fluorescence light microscopy has the unique ability to observe cellular processes over a scale that bridges four orders of magnitude. Yet, its application to living cells is fundamentally limited by ...

Conventional light microscopy has been instrumental for the study of cells and microorganisms; fluorescence microscopy has enabled visualization of even smaller cell features by selectively adding ...