THUNDER 3D 生細胞および 3D 培養細胞
THUNDER Imaging Systems
製品紹介
Home
Leica Microsystems
THUNDER 3D 生細胞および 3D 培養細胞
3D バイオロジーをリアルタイムに解き明かす*
最新の記事を読む
How Efficient is your 3D Organoid Imaging and Analysis Workflow?
Organoid models have transformed life science research but optimizing image analysis protocols remains a key challenge. This webinar explores a streamlined workflow for organoid research, starting…
Rapid Check of Live Stem Cells in Cell-Culture Inserts set in Multi-Well Plates
See how efficient imaging of live iPSC stem cells within cell-culture inserts set in a multi-well plate can be done to evaluate the cells using a THUNDER Imager. Just read this article.
How to Get Deeper Insights into your Organoid and Spheroid Models
In this eBook, learn about key considerations for imaging 3D cultures, such as organoids and spheroids, and discover microscopy solutions to shed new insights into dynamic processes in 3D real-time
Exploring Subcellular Spatial Phenotypes with SPARCS
Discover spatially resolved CRISPR screening (SPARCS), a platform for microscopy-based genetic screening for spatial subcellular phenotypes at the human genome scale.
Introduction to Fluorescent Proteins
Overview of fluorescent proteins (FPs) from, red (RFP) to green (GFP) and blue (BFP), with a table showing their relevant spectral characteristics.
Imaging Organoid Models to Investigate Brain Health
Imaging human brain organoid models to study the phenotypes of specialized brain cells called microglia, and the potential applications of these organoid models in health and disease.
How Microscopy Helps the Study of Mechanoceptive and Synaptic Pathways
In this podcast, Dr Langenhan explains how microscopy helps his team to study mechanoceptive and synaptic pathways, their challenges, and how they overcome them.
What are the Challenges in Neuroscience Microscopy?
eBook outlining the visualization of the nervous system using different types of microscopy techniques and methods to address questions in neuroscience.
The Role of Iron Metabolism in Cancer Progression
Iron metabolism plays a role in cancer development and progression, and modulates the immune response. Understanding how iron influences cancer and the immune system can aid the development of new…
How is Microscopy Used in Spatial Biology? A Microscopy Guide
Different spatial biology methods in microscopy, such as multiplex imaging, are helping to better understand tissue landscapes. Learn more in this microscopy guide.
Going Beyond Deconvolution
Widefield fluorescence microscopy is often used to visualize structures in life science specimens and obtain useful information. With the use of fluorescent proteins or dyes, discrete specimen…
Studying Ocular Birth Defects
This article discusses how lens formation and ocular birth defects can be studied with sharp widefield microscopy images which are acquired rapidly. The mouse ocular lens is used as a model to study…
Fast, High Acuity Imaging and AI-assisted Analysis
The use of state-of-the-art AI systems is pushing image analysis into a new generation. Challenges like the conflict between imaging power and sample integrity are being overcome with THUNDER’s…
Create New Options for Live Cell Imaging
The use of state-of-the-art AI systems is pushing image analysis into a new generation. Challenges like the conflict between imaging power and sample integrity are being overcome with THUNDER’s…
Find Relevant Specimen Details from Overviews
Switch from searching image by image to seeing the full overview of samples quickly and identifying the important specimen details instantly with confocal microscopy. Use that knowledge to set up…
Accurately Analyze Fluorescent Widefield Images
The specificity of fluorescence microscopy allows researchers to accurately observe and analyze biological processes and structures quickly and easily, even when using thick or large samples. However,…
Save Time and Effort with AI-assisted Fluorescence Image Analysis
The powerful synergy of THUNDER and Aivia analyze fluorescence images with greater accuracy, even when using low light excitation.
How to Improve Live Cell Imaging with Coral Life
For live-cell CLEM applications, light microscopy imaging is a critical step for identifying the right cell in the right state at the right time. In this article, Leica experts share their insights on…
Optimizing THUNDER Platform for High-Content Slide Scanning
With rising demand for full-tissue imaging and the need for FL signal quantitation in diverse biological specimens, the limits on HC imaging technology are tested, while user trainability and…
Physiology Image Gallery
Physiology is about the processes and functions within a living organism. Research in physiology focuses on the activities and functions of an organism’s organs, tissues, or cells, including the…
Neuroscience Images
Neuroscience commonly uses microscopy to study the nervous system’s function and understand neurodegenerative diseases.
Developmental Biology Image Gallery
Developmental biology explores the development of complex organisms from the embryo to adulthood to understand in detail the origins of disease. This category of the gallery shows images about…
Putting Dynamic Live Cell Data into the Ultrastructural Context
With workflow Coral Life, searching for a needle in the haystack is a thing of the past. Take advantage of correlative light and electron microscopy to identify directly the right cell at the right…
Download The Guide to Live Cell Imaging
In life science research, live cell imaging is an indispensable tool to visualize cells in a state as in vivo as possible. This E-book reviews a wide range of important considerations to take to…
Studying Cell Division
Cell division is a biological process during which all cellular components must be distributed among the daughter cells. The division process requires firm coordination for success. Microscopy is…
The Power of Pairing Adaptive Deconvolution with Computational Clearing
Learn how deconvolution allows you to overcome losses in image resolution and contrast in widefield fluorescence microscopy due to the wave nature of light and the diffraction of light by optical…
Improvement of Imaging Techniques to Understand Organelle Membrane Cell Dynamics
Understanding cell functions in normal and tumorous tissue is a key factor in advancing research of potential treatment strategies and understanding why some treatments might fail. Single-cell…
Image Gallery: THUNDER Imager
To help you answer important scientific questions, THUNDER Imagers eliminate the out-of-focus blur that clouds the view of thick samples when using camera-based fluorescence microscopes. They achieve…
From Organs to Tissues to Cells: Analyzing 3D Specimens with Widefield Microscopy
Obtaining high-quality data and images from thick 3D samples is challenging using traditional widefield microscopy because of the contribution of out-of-focus light. In this webinar, Falco Krüger…
An Introduction to Computational Clearing
Many software packages include background subtraction algorithms to enhance the contrast of features in the image by reducing background noise. The most common methods used to remove background noise…
Factors to Consider When Selecting a Research Microscope
An optical microscope is often one of the central devices in a life-science research lab. It can be used for various applications which shed light on many scientific questions. Thereby the…
How Can Immunofluorescence Aid Virology Research?
Modern virology research has become as crucial now as ever before due to the global COVID-19 pandemic. There are many powerful technologies and assays that virologists can apply to their research into…
Computational Clearing - Enhance 3D Specimen Imaging
This webinar is designed to clarify crucial specifications that contribute to THUNDER Imagers' transformative visualization of 3D samples and improvements within a researcher's imaging-related…
THUNDER Imagers: High Performance, Versatility and Ease-of-Use for your Everyday Imaging Workflows
This webinar will showcase the versatility and performance of THUNDER Imagers in many different life science applications: from counting nuclei in retina sections and RNA molecules in cancer tissue…
Alzheimer Plaques: fast Visualization in Thick Sections
More than 60% of all diagnosed cases of dementia are attributed to Alzheimer’s disease. Typical of this disease are histological alterations in the brain tissue. So far, there is no cure for this…
Real Time Images of 3D Specimens with Sharp Contrast Free of Haze
THUNDER Imagers deliver in real time images of 3D specimens with sharp contrast, free of the haze or out-of-focus blur typical of widefield systems. They can even image clearly places deep inside a…
応用分野
生細胞イメージング
視点を単体の顕微鏡コンポーネントから必要なすべての機能を備えた生細胞イメージングソリューションへと移し、ライカ マイクロシステムズは顕微鏡、LAS X イメージングソフトウェア、カメラおよび専用サードパーティコンポーネントを 1 つの完全な生細胞イメージングシステムに統合します。
ゼブラフィッシュを用いた研究
スクリーニング、ソーティング、マニピュレーションおよびイメージングを通じて最良の結果を得るためには、細部や構造を観察して、研究の次の段階に向けて正しい判断を下す必要があります。
優れた光学系と高解像度で定評のあるライカの実体顕微鏡と透過照明スタンドは、世界中の研究者から支持されています。
光子操作
光子操作という用語は、事象を引き起こし、長時間にわたり生細胞におけるダイナミックで複雑な挙動を観察するため蛍光分子の性質を利用するための広範な技術を指すものです。ブリーチングであろうと活性化であろうと、変換、アブレーションあるいは結合技術であろうと、研究者は高解像度で事象を実現させ観察するに充分なシステムを必要とします。
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。
オルガノイドと3D細胞培養
ライフサイエンス研究で近年最も目覚ましい発展の一つは、オルガノイド、スフェロイド、生体機能チップモデルなどの3D細胞培養システムの開発です。 3D細胞培養は、細胞が成長し、全3次元で周囲と相互作用できる人工環境です。 これらの条件は、生体内条件に似ています。
ウイルス学
ウイルス研究のためのイメージングと試料作製ソリューション
顕微鏡の高度な技術
高度な顕微鏡技術には、高解像度および超解像のイメージング技術が含まれます。これらの技術は主に、細胞や組織などの試料にできるだけ優しく、極めて高い解像度で生物学的事象を可視化するために使用されます。 研究者は、高度な顕微鏡技術によって、生物学的経路、遺伝子やタンパク質の発現、病気のメカニズムなどに大きな影響を与える生体分子を調べ、理解することができます。
顕微鏡の基本的な技術
顕微鏡の基本的な技術は、顕微鏡ステージ上の試料全体が光源にさらされる形で使用されます。試料全体は、上方(倒立型)または下方(標準的な正立顕微鏡の場合)から白色光で照らされます。試料の透明度や観察対象・観察部位に応じて、複雑な細胞構造を識別するために異なる蛍光粒子を使用します。
微分干渉(DIC)顕微鏡
微分干渉(DIC)顕微鏡は、光源と集光レンズの間に偏光フィルターとウォラストンプリズムを配置した広視野顕微鏡で、対物レンズとカメラセンサーや接眼レンズの間にも偏光フィルターとウォラストンプリズムを配置しています。
位相差顕微鏡
位相差顕微鏡では、染色することなく、多くの種類の生物試料の構造をより優れたコントラストで観察できます。
暗視野顕微鏡
暗視野コントラスト法は、生体試料の構造や物質試料の不均一な特徴から生じる光の回折や散乱を利用する方法です。
