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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。

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…

Dr. Nordmann in conversation with Dr. Falk Schlaudraff, Manager Product Management Uprights (widefield/compound) at Leica Microsystems

How a Breakthrough in Spatial Proteomics Saved Lives

Toxic epidermal necrolysis (TEN) is a rare but devastating reaction to common medications like antibiotics or gout treatments. It begins innocuously, often as a rash, but can escalate rapidly into…

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。

Zebrafish-embryo image captured using a THUNDER Imager Tissue and live instant computational clearing.

Improving Zebrafish-Embryo Screening with Fast, High-Contrast Imaging

Discover from this article how screening of transgenic zebrafish embryos is boosted with high-speed, high-contrast imaging using the DM6 B microscope, ensuring accurate targeting for developmental…

Image: Human stem cell-derived mid brain organoids. Courtesy of Dr Tanya Singh, University of Oxford.

Unlocking the Secrets of Organoid Models in Biomedical Research

Get ready to delve deeper into the world of organoids and 3D models, which are essential tools for advancing our understanding of human health. Navigating these complex structures and obtaining clear…

Spherulitic crystals of hippuric acid, which were imaged with a Leica microscope using crossed polarizers, showing so-called Maltese crosses.

A Guide to Polarized Light Microscopy

Polarized light microscopy (POL) enhances contrast in birefringent materials and is used in geology, biology, and materials science to study minerals, crystals, fibers, and plant cell walls.

Area of a printed circuit board (PCB) which was imaged with extended depth of field (EDOF) using digital microscopy.

顕微鏡を知る：被写界深度

顕微鏡において被写界深度は、凹凸の変化が⼤きい構造を持つ試料をピントがあったシャープに観察・撮像するために重要なパラメータです。被写界深度は、開⼝数、解像度、倍率の相関関係によって決定され、解像度とパラメータは反⽐例の関係にあります。被写界深度と解像度のバランスが最適になるように調整することができる顕微鏡もあります。