Leica Microsystems: Leica Science Lab

Science Lab

The knowledge portal of Leica Microsystems offers scientific research and teaching material on the subjects of microscopy. The content is designed to support beginners, experienced practitioners and scientists alike in their everyday work and experiments. Explore interactive tutorials and application notes, discover the basics of microscopy as well as high-end technologies – become part of the Science Lab community and share your expertise!

Brain organoid section (DAPI) acquired using THUNDER Imager Live Cell. Image courtesy of Janina Kaspar and Irene Santisteban, Schäfer Lab, TUM.

Imaging Organoid Models to Investigate Brain Health

Imaging human brain organoid models to study the phenotypes of specialized brain cells called microglia, and the potential applications of these organoid models in health and disease.

Mouse cortical neurons. Transgenic GFP (green). Image courtesy of Prof. Hui Guo, School of Life Sciences, Central South University, China

How Microscopy Helps the Study of Mechanoceptive and Synaptic Pathways

In this podcast, Dr Langenhan explains how microscopy helps his team to study mechanoceptive and synaptic pathways, their challenges, and how they overcome them.

What are the Challenges in Neuroscience Microscopy?

eBook outlining the visualization of the nervous system using different types of microscopy techniques and methods to address questions in neuroscience.

Going Beyond Deconvolution

Widefield fluorescence microscopy is often used to visualize structures in life science specimens and obtain useful information. With the use of fluorescent proteins or dyes, discrete specimen…

Mouse whole-mount retina. Image courtesy of the Experimental Ophthalmology Group, University of Murcia, Spain.

Fast, High Acuity Imaging and AI-assisted Analysis

The use of state-of-the-art AI systems is pushing image analysis into a new generation. Challenges like the conflict between imaging power and sample integrity are being overcome with THUNDER’s…

3D reconstruction of an isolated human islet

Create New Options for Live Cell Imaging

The use of state-of-the-art AI systems is pushing image analysis into a new generation. Challenges like the conflict between imaging power and sample integrity are being overcome with THUNDER’s…

Raw widefield and THUNDER image of a mouse dorsal root ganglion with tdTomato (red) expressed in the sensory neurons.

Fast, High-contrast 3D Imaging of Sensory Neurons

This article discusses how fast, high-contrast 3D imaging of dorsal root ganglion (DRG) tissue with a THUNDER Imager Tissue using large volume computational clearing (LVCC) allows sensory neurons to…

Left-hand image: The distribution of immune cells (white) and blood vessels (pink) in white adipose tissue (image captured using the THUNDER Imager 3D Cell Culture). Right-hand image: The same image after automated analysis using Aivia, with each immune cell color-coded based on its distance to the nearest blood vessel. Image courtesy of Dr. Selina Keppler, Munich, Germany.

Accurately Analyze Fluorescent Widefield Images

The specificity of fluorescence microscopy allows researchers to accurately observe and analyze biological processes and structures quickly and easily, even when using thick or large samples. However,…

Raw widefield (left) and THUNDER (right) image of Ewing Sarcoma cells (SK-ES-1).

Visualizing the Mitotic Spindle in Cancer Cells

This article demonstrates how this research is aided by visualizing more details of mitotic spindles in Ewing Sarcoma cells using the THUNDER Imager Tissue and Large Volume Computational Clearing…