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脳神経外科、眼科、形成外科、耳鼻咽喉科、歯科の専門医向けに厳選された、最新の科学・臨床リソースを探索しませんか？貴重な症例や洞察、シンポジウムなど、多彩なコンテンツをご覧いただけます。手術用顕微鏡の最先端技術に焦点を当て、AR蛍光、3D視覚化、術中OCTイメージングといった革新的技術が、複雑な手術の精度向上や意思決定の最適化にどのように貢献するかをご紹介します。

History, Developments and Trends of Microscopy in Cancer Research

Cancer is a global disease, with 18 million new cases diagnosed and 10 million cancer-related deaths worldwide in 2020. This burden is set to increase, with a projected increase in cases of ~55% by…

Mouse fibroblasts where F-actin is labelled with FITC (green), tubulin with Cy5 (red), and nuclei with DAPI (blue). Image courtesy of Dr. Günter Giese, Max Planck Institute for Medical Research, Heidelberg, Germany.

Overview of Fluorescent Dyes in terms of Applications and Properties

An introduction to commonly used fluorescent dyes and an overview of their characteristics are given in this article. Fluorescence microscopy is used for the study of specific cellular components with…

Leica Microsystems Life Science Product

Predictive Service Prevents Downtime in Ghent

At the VIB BioImaging Core in Ghent, Belgium, researchers depend on Leica’s Stellaris 8 confocal microscope to explore the frontiers of biomedical science. When Leica’s RemoteCare system detected a…

Virally labeled neurons (red) and astrocytes (green) in a cortical spheroid derived from human induced pluripotent stem cells. THUNDER Model Organism Imager with a 2x, 0.15 NA objective at 3.4x zoom was used to produce this 425 µm Z-stack (26 positions) which is presented here as an Extended Depth of Field (EDoF) projection. Images courtesy of Dr. F. Birey, Dr. S. Pasca laboratory, Palo Alto, CA.

Guide to Live-Cell Imaging

For a wide range of applications in various research fields of life science, live-cell imaging is an indispensable tool for visualizing cells in a state as close to in vivo, i.e. living and active, as…

Brain organoid labeled with lamin (green) and tubulin (magenta), acquired using Viventis Deep. Courtesy of Akanksha Jain, Treutlein Lab ETH-DBSSE Basel (Switzerland).

Faster & Deeper Insights into Organoid and Spheroid Models

Gain deeper, more translatable, insights into organoid and spheroid models for drug discovery and disease research by overcoming key imaging challenges. In this eBook, explore advanced microscopy…

Image of roundworm C. elegans acquired with a M205 FA fluorescence automated stereo microscope in combination with Rottermann contrast. Areas labelled with mCherry are seen as reddish purple.

A Guide to C. elegans Research – Working with Nematodes

Efficient microscopy techniques for C. elegans research are outlined in this guide. As a widely used model organism with about 70% gene homology to humans, the nematode Caenorhabditis elegans (also…

Optic nerve regeneration in the Xenopus laevis tadpole.

A Novel Laser-Based Method for Studying Optic Nerve Regeneration

Optic nerve regeneration is a major challenge in neurobiology due to the limited self-repair capacity of the mammalian central nervous system (CNS) and the inconsistency of traditional injury models.…

Fluorescence microscopy of sectioned tissue, showing the interface between the extensor digitorum longus muscle and the common peroneal nerve in the adult rat. Regenerative peripheral nerve interface (RPNI) at 2 weeks. Image acquired using Mica. Stained for nuclei (blue), neurofilaments (green) and S100B (red). Image courtesy of Dr. Aaron Lee, Department of Bioengineering (Lab of Dr. Rylie Green), Imperial College London.

How to Image Axon Regeneration in Deep Muscle Tissue

This study highlights Dr. Aaron Lee’s research on mapping nerve regeneration in muscle grafts post-amputation. Limb loss often leads to reduced quality of life, not only from tissue loss but also due…

Mouse brain slice which was immunostained with GFAP-A647 and imaged using a THUNDER Imager Tissue. Courtesy of H. Xu, University of Pennsylvania, Philadelphia, USA.

神経科学研究

神経変性疾患の理解向上に取り組んでいる、もしくは神経系の機能を研究をしていますか？ライカマイクロシステムズのイメージングソリューションによってブレイクスルーを起こす方法をご覧ください。