Leica Microsystems: Science Lab

Science Lab

Das Wissensportal von Leica Microsystems bietet Ihnen Wissens- und Lehrmaterial zu den Themen der Mikroskopie. Die Inhalte sind so konzipiert, dass sie Einsteiger, erfahrene Praktiker und Wissenschaftler gleichermaßen bei ihrem alltäglichen Vorgehen und Experimenten unterstützen. Entdecken Sie interaktive Tutorials und Anwendungsberichte, erfahren Sie mehr über die Grundlagen der Mikroskopie und High-End-Technologien - werden Sie Teil der Science Lab Community und teilen Sie Ihr Wissen!

Developing embryos of different species at different stages during the elongation of their posterior body axis, from left to right in developmental time. The labelled regions in red depict a region of undifferentiated cells called the tailbud, with the corresponding region generated from that tissue shaded in grey. Upper row: lamprey; middle row: catshark; bottom row, zebrafish. This figure has been adapted from the following publication: Steventon, B., Duarte, F., Lagadec, R., Mazan, S., Nicolas, J.-F., & Hirsinger, E. (2016). Species tailoured contribution of volumetric growth and tissue convergence to posterior body elongation in vertebrates. Development, 2016. 143(10):1732-41

How to Study Gene Regulatory Networks in Embryonic Development

Join Dr. Andrea Boni by attending this on-demand webinar to explore how light-sheet microscopy revolutionizes developmental biology. This advanced imaging technique allows for high-speed, volumetric…

Mikrobielle Welten erforschen: Räumliche Interaktionen in 3D Lebensmittelmatrizen

Das Micalis Institute ist eine gemeinsame Forschungseinheit in Zusammenarbeit mit INRAE, AgroParisTech und der Université Paris-Saclay. Seine Mission ist es, innovative Forschung im Bereich der…

Dapi – Nucleus, GFP – Plasma Membrane, Thickness 100µm, 63x objektive, 469 Z planes, 2 channels, THUNDER Imager 3D Cell Culture. Courtesy M.Sc. Dana Krauß, Medical University of Vienna (Austria).

How Efficient is your 3D Organoid Imaging and Analysis Workflow?

Organoid models have transformed life science research but optimizing image analysis protocols remains a key challenge. This webinar explores a streamlined workflow for organoid research, starting…

40x magnification of organoids cluster taken on Mateo TL.Cell type: esophageal squamous carcinoma; scale bar 15µm. Courtesy of bioGenous, China.

Overcoming Observational Challenges in Organoid 3D Cell Culture

Learn how to overcome challenges in observing organoid growth. Read this article and discover new solutions for real-time monitoring which do not disturb the 3D structure of the organoids over time.

Spheroid stained with Cyan: Dapi nuclear countertain; Green AF488 Involucrin; Orange AF55 Phalloidin Actin; Magenta AF647 CK14.

Notable AI-based Solutions for Phenotypic Drug Screening

Learn about notable optical microscope solutions for phenotypic drug screening using 3D-cell culture, both planning and execution, from this free, on-demand webinar.

Murine esophageal organoids (DAPI, Integrin26-AF 488, SOX2-AF568) imaged with the THUNDER Imager 3D Cell Culture. Courtesy of Dr. F.T. Arroso Martins, Tamere University, Finland.

How to Get Deeper Insights into your Organoid and Spheroid Models

In this eBook, learn about key considerations for imaging 3D cultures, such as organoids and spheroids, and discover microscopy solutions to shed new insights into dynamic processes in 3D real-time

The principle of the FusionOptics technology: Of the two separate beam paths (1), one provides depth of field (2) and the other high resolution (3). In the brain, the two images of the sample are merged into a single, optimal 3D image (4).

What is the FusionOptics Technology?

Leica stereo microscopes with FusionOptics provide optimal 3D perception. The brain merges two images, one with large depth of field and the other with high resolution, into one 3D image.

Branched organoid growing in collagen where the Nuclei are labeled blue. To detect the mechanosignaling process, the YAP1 is labeled green.

Examining Developmental Processes In Cancer Organoids

Interview: Prof. Bausch and Dr. Pastucha, Technical University of Munich, discuss using microscopy to study development of organoids, stem cells, and other relevant disease models for biomedical…

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.