Leica Microsystems

Observe physiological processes over a long period while keeping your samples safe and thriving with the Viventis Deep light sheet fluorescence microscope! Watch this time-lapse of a zebrafish embryo at 3 days post fertilization. More on Viventis Deep: https://fcld.ly/l9k1n0f Caption: The video shows a 5 hour time-lapse maximum intensity projection of a zebrafish embryo along the z-axis at 3 days post fertilization. The microglia cell membrane (mpeg1:Gal4; UAS:lyn-tagRFPT) is shown in green. On the left, microglia cells are moving within the optic tectum. Their highly dynamic extensions are used for scanning the brain in order to remove dying neurons. The right side shows the bright field channel. The time scale indicates minutes and seconds. Courtesy of Prof. Francesca Peri, Department of Molecular Life Sciences, University of Zurich, Switzerland.

Want to get more done and stay comfortable during your routine material inspections? We’re going to unveil a microscope solution designed to meet the rigorous demands of quality control, R&D, and materials science. Keep your eyes peeled over the next few weeks!

The FDA is shifting focus from animal testing to Human Relevant Models — signaling a notable advancement in drug development. This move promises improved safety, reduced costs, and faster timelines for advancing therapies. Join Aaron Risinger from Molecular Devices and Andrew Barazia from Leica Microsystems — moderated by Thomas C. — as they discuss how automation and AI-driven imaging can help scale your research and therapeutic programs. Register now: https://bit.ly/42JrNLB

Explore fluorescent signals in your experiment beyond the spectral options. TauContrast in STELLARIS Cryo allows you to exploit difference in fluorescence lifetime to separate overlapping fluorophores and identify unwanted signal contributions such as grid reflection. Learn how ➡️ https://fcld.ly/xrjkr11 Image: Sample of S. cerevisiae on EM grid. Nuclei fluorescence signal in two TauSeparation channels (red, green), reflection (grid and carbon layer visualization, white)

How do trillions of cells work together to form and maintain the human body? Tarek M. Ashkar (El-Achkar), MD and Sarah Teichmann, Ph.D. will take you on a journey through 3D and 4D spatial imaging, uncovering how organs function, develop, and respond to disease. Join us for this insightful discussion. Register: https://fcld.ly/hyh0vuq

Join us today at #FOM2025! Stop by booth 48 to discover the future of #microscopy. Book hands-on sessions with our confocal & widefield platforms https://fcld.ly/n3o7eoe Learn about advanced imaging innovations to accelerate your research from our on-site experts. See you soon! #FocusonMicroscopy

We recently had the pleasure of hosting our Leica mentees at our Mannheim site. The mentees had an exciting day, exploring our production and #R&D departments, and experiencing a live demo of our cutting-edge Stellaris system. The afternoon wrapped up with a vibrant networking session, offering plenty of opportunities to learn about the various career paths of #STEM professionals within the #LeicaMicrosystems team. A big thank you to our mentees for their enthusiasm and interest, and to our dedicated Leica colleagues who made this day possible! #MentoringHessen

Observe cancer organoids over multiple days in high detail. This video is a time-lapse recording using light sheet imaging showing the growth evolution of a human colon cancer organoid acquired over 6 days. The high quality of the recording throughout the entire volume was possible by the dual view detection of the Viventis Deep Light Sheet Fluorescence Microscope. The time interval between frames is 30 minutes. The 3D representation was made using the Aivia AI image Analysis Software. Learn more about the benefits of light sheet imaging with Viventis Deep:https://fcld.ly/okur6k4 Video Description: 137 hour time-lapse of a human colon cancer organoid. The 3D representation was made with Aivia AI image Analysis Software. Nuclei expressing H2B-mNeon are shown in cyan. Courtesy of Moos, F., Suppinger, S., de Medeiros, G. et al. Open-top multisample dual-view light-sheet microscope for live imaging of large multicellular systems. Nat Methods 21, 798–803 (2024). https://lnkd.in/e7vn5Gai

Check out this opportunity to enhance your fluorescence microscopy skill set! Registration deadline is April 21st 👇

Explore a new way of getting deeper insights into #Organoids and #3DModels - Join experts from Oxford University and University College London to see what happens when #THUNDER meets the #CrestOptics Spinning Disk! Register Now → https://fcld.ly/cad6w7r Image: Human stem cell-derived mid brain organoids. Courtesy of Dr. Tanya Singh, University of Oxford.