No modern laboratory is complete without at least one basic microscope, an essential tool for biologists in medical research. Transmitted light methods have largely been replaced by fluorescent ...

Researchers seeking to explore live-cell dynamics can now turn to rapid, precise, and gentle technologies that address conventional microscopy challenges such as limited temporal resolution and ...

Seeing chemistry unfold inside living cells is one of the biggest challenges of modern bioimaging. Raman microscopy offers a ...

Optical diffraction tomography (ODT) has long been recognized for its potential in non-invasive, label-free imaging of live biological cells. However, a major challenge arises when ODT is applied to ...

Scientists at the Center for Cell Dynamics, School of Biological and Behavioral Sciences, Queen Mary University of London, in collaboration with Carl Zeiss, have developed an innovative live-cell ...

Researchers have developed a DF-FPDT imaging system where, (a) is the schematic of the DF-FPDT system based on a commercial microscope integrated with a programmable angular LED array for illumination ...

Scientists have long wanted to watch iron(II) move inside living cells as it fuels metabolism, shapes immunity, and, in some ...

Peking University, April 2, 2025: A team from Peking University’s College of Future Technology, led by Professor Xi Peng, in collaboration with Professor Jin Dayong at the Eastern Institute of ...

Tunable red to green emissions in upconversion nanoparticles allow precise identification of single particles, enabling accurate, long-term multicolor tracking in complex live cell environments.

Single-cell functional analysis enables scientists to examine the unique characteristics of each cell within organs, tissues, and cell cultures. Unlike bulk-cell analysis, single-cell analysis allows ...