There are obvious differences between cancerous cells and normal cells in morphology, chemical properties and mechanical properties. The detection of cytochemical and mechanical properties of tumor ...

Confocal laser endomicroscopy (CLE) is an emerging optical imaging technique that enables real‐time, in vivo visualisation of tissues at a cellular level. In the context of head and neck cancer, CLE ...

Confocal microscopy is an optical sectioning technique that utilizes fluorescence to generate a high resolution / high contrast image compared to traditional epifluorescence. These systems use a laser ...

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 ...

There is a growing demand for non-invasive insights into the complex three-dimensional subcellular dynamics within living tissues at the frontier of biological research. Professor Xi Peng's group at ...

Leica Stellaris 5 confocal microscope with Lightning Super-Resolution is in PISB 408 . This point scanning confocal microscope uses a DMi8 inverted stand with a tandem scanner, 4 Power HyD spectral ...

Evident has pioneered the proprietary, next-generation SilVIR detector system for the FV4000 laser confocal microscope. This detector sets a new benchmark in multicolor imaging, offering exceptionally ...

Confocal laser endomicroscopy is gaining attention as a potential alternative to traditional tissue biopsies in gastroenterology, offering real-time, cellular-level imaging during endoscopic ...

Introducing the FLUOVIEW ™ FV4000 confocal laser scanning microscope and FV4000MPE multiphoton laser scanning microscope, featuring groundbreaking advancements in imaging technology that empower ...

Confocal microscopy is a powerful technology for visualizing multiparameter cellular and molecular phenomena. Researchers increasingly seek to expand the number of fluorophores for real-time analysis, ...

In the mid-1950s, Princeton University researcher Marvin Minsky sought a way to increase signal-to-noise when imaging central nervous system samples. Because CNS tissue is very dense and scatters ...