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 ...

Biologists are very interested in how proteins, lipids and other compounds are organized and interact in systems. Very few organizational details can be gained by using standard transmission-based ...

Computational fluorescence microscopy (CFM) requires accurate point spread function (PSF) characterization for high-quality ...

descSPIM enables three-dimensional imaging of diverse tissues like neural cells and cancerous tumors. The widespread dissemination and adoption of descSPIM can accelerate biomedical discoveries. Three ...

A Simple Touchscreen Fluorescence Cell Imager Improves Workflow for Routine Applications Whether it’s for gaining a better understanding of how cells work, studying the effects of drugs or toxins on ...

Microscopy continues to transform the life sciences. Here are five recent breakthroughs made possible by the technique.

Striking the Right Balance between Signal Strength and Long-Term Cell Health A key challenge with live-cell fluorescence imaging is the ability to visualize weak fluorescent signals over background ...

Light microscopy is a key tool that scientists use to image cells, organelles, subcellular structures, and molecules such as proteins and nucleic acids. Because visible light leaves biological ...

What does the inside of a cell really look like? In the past, standard microscopes were limited in how well they could answer this question. Now, researchers have succeeded in developing a microscope ...