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

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

For the first time, researchers have directly visualized how newly formed cellular organelles leave the endoplasmic reticulum ...

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 ...

Cell painting has established itself as a powerful tool for high content imaging, able to generate vast quantities of data in response to chemical perturbations. Over the past decade, cell painting ...

The cochlea is the spiral-shaped structure within the inner ear responsible for our sense of hearing. To fully understand ...

(Nanowerk News) A breakthrough in imaging technology promises to transform our understanding of the inner workings of living cells, and provide insights into a wide range of diseases. The study, ...

Workflow of the optimized deep imaging protocol for optically cleared skeletal tissue. Steps for preparing the deep-imaging bone hemisections, including tissue fixation, decalcification, dehydration, ...

A microscope picture of human bone cells (U2OS) showing the localization of a lipid (phosphatidylethanolamine). The lipid is visible in orange, the cell membrane in purple, and endosomes in white. New ...

While medical centers use ultrasound daily, so far this technology is not capable of observing body tissues at the scale of cells. Physicists from TU Delft have developed a microscopy technique based ...