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Biowissenschaften

Biowissenschaften

Hier können Sie Ihr Wissen, Ihre Forschungsfähigkeiten und Ihre praktischen Anwendungen der Mikroskopie in verschiedenen wissenschaftlichen Bereichen erweitern. Erfahren Sie, wie Sie präzise Visualisierung, Bildinterpretation und Forschungsfortschritte erzielen können. Hier finden Sie aufschlussreiche Informationen über fortgeschrittene Mikroskopie, Bildgebungsverfahren, Probenvorbereitung und Bildanalyse. Zu den behandelten Themen gehören Zellbiologie, Neurowissenschaften und Krebsforschung mit Schwerpunkt auf modernsten Anwendungen und Innovationen.

Application example of hyperspectral imaging

Potential of Multiplex Confocal Imaging for Cancer Research and Immunology

Explore the new frontiers of multi-color fluorescent imaging: from image acquisition to analysis

In vivo imaging of a mouse pial and cortical vasculature through a glass window (ROSAmT/mG::Pdgfb-CreERT2 mouse meningeal and cortical visualization following tamoxifen induction and craniotomy). Courtesy: Thomas Mathivet, PhD

Windows on Neurovascular Pathologies

Discover how innate immunity can sustain deleterious effects following neurovascular pathologies and the technological developments enabling longitudinal studies into these events.

Lifetime-based multiplexing in live cells using TauSeparation. Mammalian cells expressing LifeAct-GFP (ibidi GmbH) and labelled with MitoTracker Green. Acquisition with one detector, intensity information shown in grey. The two markers can be separated using lifetime information: LifeAct-GFP (cyan), MitoTracker Green (magenta). Image acquired with STELLARIS 5.

The Power of Reproducibility, Collaboration and New Imaging Technologies

In this webinar you willl learn what impacts reproducibility in microscopy, what resources and initiatives there are to improve education and rigor and reproducibility in microscopy and how…

Donor (D) and acceptor (A) molecule which participate in FRET (Förster resonance energy transfer).

Was ist FRET mit FLIM (FLIM-FRET)?

Der Beitrag erläutert die FLIM-FRET-Methode, die Resonanzenergietransfer und Fluoreszenz-Lebensdauer-Imaging zur Untersuchung von Protein-Protein Wechselwirkungen kombiniert.

Visualizing Protein-Protein Interactions by Non-Fitting and Easy FRET-FLIM Approaches

The Webinar with Dr. Sergi Padilla-Parra is about visualizing protein-protein interaction. He gives insight into non-fitting and easy FRET-FLIM approaches.

Separation of cells based on their tracking status: A colourised binary mask of a time-lapse microscopy field of view of medium confluency with individual cells highlighted as survivors if they can be tracked since the initial movie frame (cyan), incomers if they migrated into the field of view throughout the movie (yellow) or mistracks if an error occurred in the automated trajectory reconstruction (red).

Tracking Single Cells Using Deep Learning

AI-based solutions continue to gain ground in the field of microscopy. From automated object classification to virtual staining, machine and deep learning technologies are powering scientific…

Analysis of anatomy and axon orientation of an adult mouse brain tissue with QLIPP.

Learning the Cellular Architecture from its Optical Properties

In the last 3 years, microscopists have started to use "AI based" solutions for a wide range of applications, including image acquisition optimization (smart microscopy), object classification, image…

How FLIM Microscopy Helps to Detect Microplastic Pollution

The use of autofluorescence in biological samples is a widely used method to gain detailed knowledge about systems or organisms. This property is not only found in biological systems, but also…

Step by Step Guide for FRAP Experiments

Fluorescence Recovery After Photobleaching (FRAP) has been considered the most widely applied method for observing translational diffusion processes of macromolecules. The resulting information can be…