Leica Microsystems
Leica Microsystems ist ein weltweit führender Hersteller von Mikroskopen und wissenschaftlichen Instrumenten. Im 19. Jahrhundert als Familienunternehmen gegründet, war die Geschichte des Unternehmens auf dem Weg zum Weltkonzern von beispielloser Innovation geprägt.
Die traditionell enge Zusammenarbeit mit der Wissenschaft ist der Schlüssel zur Innovationstradition von Leica Microsystems, die auf die Ideen der Anwender zurückgreift und auf deren Bedürfnisse zugeschnittene Lösungen schafft. Auf globaler Ebene ist Leica Microsystems in drei Divisionen gegliedert, die alle zu den führenden Anbietern in ihrem jeweiligen Bereich gehören: Life Science, Industrie und Medizin.
Das Unternehmen ist in über 100 Ländern mit 6 Produktionsstandorten in 5 Ländern, Vertriebs- und Serviceorganisationen in 20 Ländern und einem internationalen Händlernetz vertreten. Der Hauptsitz des Unternehmens liegt in Wetzlar, Deutschland.
Which Sensor is the Best for Confocal Imaging?
The Hybrid Photodetectors (HyD) are! Why that is the case is explained in this short Science Lab article.
See the Structure with Microscopy - Know the Composition with Laser Spectroscopy
The advantages of a 2-in-1 materials analysis solution combining optical microscopy and laser induced breakdown spectroscopy (LIBS) for simultaneous visual and chemical inspection are described in…
Visualization of DNA Molecules
Precise low angle rotary shadowing with heavy metals (like platinum) can be used in transmission electron microscopy (TEM) to observe molecular details of objects previously absorbed on a thin, low…
The Future of Fluorescence in Vascular Neurosurgery
In vascular neurosurgery, surgical microscopes are used to provide a magnified and illuminated view of the surgical field. Although surgeons benefit greatly from the superb image quality and optical…
Using U-Shaped Glass Capillaries for Sample Mounting
The DLS microscope system from Leica Microsystems is an innovative concept which integrates the Light Sheet Microscopy technology into the confocal platform. Due to its unique optical architecture,…
Practical Applications of Broad Ion Beam Milling
Mechanical polishing can be time consuming and frustrating. It can also introduce unwanted artifacts when preparing cross-sectioned samples for electron backscatter diffraction (EBSD) in the scanning…
Digital Microscopy in Earth Science
Classical polarized light (compound) microscopes can only be used for prepared samples, because the working distance they offer is insufficient for whole samples. This means that thicker and bigger…
Mission Impossible Accomplished: Tunable Colors for Non-descanning Detection
Leica Microsystems’ 4Tune detector, the key component of the SP8 DIVE Deep In Vivo Explorer, provides spectrally tunable image recording with non-descanning detection. An innovative solution for…
Introduction to Mammalian Cell Culture
Mammalian cell culture is one of the basic pillars of life sciences. Without the ability to grow cells in the lab, the fast progress in disciplines like cell biology, immunology, or cancer research…
Laser Beam Shaping for Multicolor Multiphoton Microscopy
Multiphoton Microscopy is one of the current hot topics in life science research. The new Leica TCS SP8 DIVE from Leica Microsystems presents a series of beneficial new innovations, including a freely…
Introduction to Widefield Microscopy
This article gives an introduction to widefield microscopy, one of the most basic and commonly used microscopy techniques. It also shows the basic differences between widefield and confocal…
Optimization of the Interplay of Optical Components for Aberration Free Microscopy
Optical microscopes are used to magnify objects which are otherwise invisible for the human eye. For this purpose high quality optics is necessary to achieve appropriate resolution. However, besides…
About the Most Important Considerations When Imaging Deep Into Mouse Tissue
When operating a confocal microscope, or when discussing features and parameters of such a device, we inescapably mention the pinhole and its diameter. This short introductory document is meant to…
Primary Beam Splitting Devices for Confocal Microscopes
Current fluorescence microscopy employs incident illumination which requires separation of illumination and emission light. The classical device performing this separation is a color-dependent beam…
Was macht das Pinhole im konfokalen Mikroskop?
Wer ein konfokales Mikroskop benutzt und über die Eigenschaften und Parameter eines solchen Gerätes diskutiert, wird notwendigerweise über das Pinhole reden – und wie dessen Größe sich auf das…
Rodent and Small-Animal Surgery
Learn how you can perform rodent (mouse, rat, hamster) and small-animal surgery efficiently with a microscope for developmental biology and medical research applications by reading this article.
Navigating Through the Brain
One of the challenges of neurosurgery is orientation at the surgical site. When resecting tumors, removing arteriovenous malformations, or clipping aneurysms, surgeons often have to work near healthy…
Milestones in Incident Light Fluorescence Microscopy
Since the middle of the last century, fluorescence microscopy developed into a bio scientific tool with one of the biggest impacts on our understanding of life. Watching cells and proteins with the…