Life Science Research

This is the place to expand your knowledge, research capabilities, and practical applications of microscopy in various scientific fields. Learn how to achieve precise visualization, image interpretation, and research advancements. Find insightful information on advanced microscopy, imaging techniques, sample preparation, and image analysis. Topics covered include cell biology, neuroscience, and cancer research with a focus on cutting-edge applications and innovations.

TauSense Technology Imaging Tools

Leica Microsystems’ TauSense technology is a set of imaging modes based on fluorescence lifetime. Found at the core of the STELLARIS confocal platform, it will revolutionize your imaging experiments.…

The Power HyD Detector Family

Powerful photon counting detectors on the STELLARIS confocal platform provide improved photon counting, ultra-sensitive imaging and more color options in the NIR spectrum.

TauSTED 775 resolves the intricate cytoskeleton network labeled with SiR-tubulin (glow - Spyrochrome), and trafficking vesicles labeled with CF594 (cyan - Biotium).

A Guide to Super-Resolution

Find out more about Leica super-resolution microscopy solutions and how they can empower you to visualize in fine detail subcellular structures and dynamics.

Guide to Microscopy in Cancer Research

Cancer is a complex and heterogeneous disease caused by cells deficient in growth regulation. Genetic and epigenetic changes in one or a group of cells disrupt normal function and result in…

THUNDER Imagers: High Performance, Versatility and Ease-of-Use for your Everyday Imaging Workflows

This webinar will showcase the versatility and performance of THUNDER Imagers in many different life science applications: from counting nuclei in retina sections and RNA molecules in cancer tissue…

Fluorescence microscopy image on the left with no distinction between the fluorescent signal and background autofluorescence. FLIM was used in the image on the right to differentiate autofluorescence in chloroplasts (blue) from the desired fluorescent signal from the cell membrane (green).

Learn how to Remove Autofluorescence from your Confocal Images

Autofluorescence can significantly reduce what you can see in a confocal experiment. This article explores causes of autofluorescence as well as different ways to remove it, from simple media fixes to…

Principles of Multiphoton Microscopy for Deep Tissue Imaging

This tutorial explains the principles of multiphoton microscopy for deep tissue imaging. Multiphoton microscopy uses excitation wavelengths in the infrared taking advantage of the reduced scattering…

Stimulated Raman Scattering Microscopy Probes Neurodegenerative Disease

Despite decades of research, the molecular mechanisms underlying some of the most severe neurodegenerative diseases, such as Alzheimer’s or Parkinson’s, remain poorly understood. The progression of…

Improve Cryo Electron Tomography Workflow

Leica Microsystems and Thermo Fisher Scientific have collaborated to create a fully integrated cryo-tomography workflow that responds to these research needs: Reveal cellular mechanisms at…