Imagine you're a PhD student with a fluorescent microscope and a sample of live bacteria. What's the best way use these resources to obtain detailed observations of bacterial division from the sample?

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

Fluorescence lifetime imaging microscopy (FLIM) is a sophisticated optical technique that measures the decay rate of fluorescence emission from biological specimens, providing detailed insights into ...

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 ...

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 ...

Innovative laser scanning design unlocks high-precision observations at up to 10,000 frames per second, making the microscope a powerful recording tool Two-photon microscopy (TPM) has revolutionized ...

Researchers have developed a high-speed 3D imaging microscope that can capture detailed cell dynamics of an entire small whole organism at once. The ability to image 3D changes in real time over a ...

Two-photon microscopy (TPM) has revolutionized the field of biology by enabling researchers to observe complex biological processes in living tissues at high resolution. In contrast to traditional ...

When single-molecule super-resolution microscopes were first commercialized some 15 years ago, they made headlines for their ability to resolve individual molecules and structures at the nanometer ...