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Cell DIVE Solution d’imagerie multiplex

Transformer la recherche sur les tissus grâce au multiplexage ouvert.

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Multiplexed Cell DIVE imaging of Adult Human Alzheimer’s brain tissue section demonstrating expression of markers specific to astrocytes (GFAP, S100B), microglia (TMEM119, IBA1), AD-associated markers (p-Tau217, β-amyloid) and immune cells such as CD11b+, CD163+, CD4+, and HLA-DRA+, clustered around the β-amyloid plaques.

Spatial Analysis of Neuroimmune Interactions in Alzheimer’s Disease

Alzheimer’s disease (AD) is a complex neurodegenerative disorder characterized by neurofibrillary tangles, β-amyloid plaques, and neuroinflammation. These dysfunctions trigger or are exacerbated by…

A Guide to Spatial Biology

What is spatial biology, and how can researchers leverage its tools to meet the growing demands of biological questions in the post-omics era? This article provides a brief overview of spatial biology…
Multiplexed Cell DIVE imaging to characterize the spatial landscape in Human Alzheimer’s Cortical Tissue

Probing Human Alzheimer's Cortical Section using Spatial Multiplexing

Alzheimer’s disease (AD) is the most common neurodegenerative disease and is characterized by the progressive decline of cognitive function. Spatial profiling of AD brain may reveal cellular…
Cell DIVE image of stromal remodeling around B cell follicles of follicular lymphoma patients. Stromal cells labeled with antibodies against desmin (red), SPARC (orange), vimentin (blue), and a-sma (yellow). Extracellular matrix labeled with antibody against lumican (cyan). B cells labeled with antibody against CD20 (green). Image credit: Dr. Andrea Radtke, Center for Advanced Tissue Imaging, NIAID, NIH

Empowering Spatial Biology with Open Multiplexing and Cell DIVE

Spatial biology and multiplexed imaging workflows have become important in immuno-oncology research. Many researchers struggle with study efficiency, even with effective tools and protocols. Here, we…

AI-Powered Multiplexed Image Analysis to Explore Colon Adenocarcinoma

In this application note, we demonstrate a spatial biology workflow via an AI-powered multiplexed image analysis-based exploration of the tumor immune microenvironment in colon adenocarcinoma.

A Meta-cancer Analysis of the Tumor Spatial Microenvironment

Learn how clustering analysis of Cell DIVE datasets in Aivia can be used to understand tissue-specific and pan-cancer mechanisms of cancer progression
Multiplexed Cell DIVE imaging of Colon Adenocarcinoma (CAC) tissue. A panel of approximately 30 biomarkers targeted towards various leukocyte lineages, epithelial, stromal, and endothelial cell types was utilized to characterize the tumor immune microenvironment in human colon adenocarcinoma (CAC) tissue.

Mapping the Landscape of Colorectal Adenocarcinoma with Imaging and AI

Discover deep insights in colon adenocarcinoma and other immuno-oncology realms through the potent combination of multiplexed imaging of Cell DIVE and Aivia AI-based image analysis
Clustering based analysis reveals various immune cell populations enriched in tumor cells within CT26.WT syngeneic mouse tumor models.

Spatial Architecture of Tumor and Immune Cells in Tumor Tissues

Dig deep into the spatial biology of cancer progression and mouse immune-oncology in this poster, and learn how tumor metabolism can effect immune cell function.
Pancreatic Ductal Adenocarcinoma with 11 Aerobic Glycolysis/Warburg Effect biomarkers shown – BCAT, Glut1, HK2, HTR2B, LDHA, NaKATPase, PCAD, PCK26, PKM2, SMA1, and Vimentin.

IBEX, Cell DIVE, and RNA-Seq: A Multi-omics Approach to Follicular Lymphoma

In a recent study by Radtke et al., a multi-omics spatial biology approach helps shed light on early relapsing lymphoma patients

Accelerating Discovery for Multiplexed Imaging of Diverse Tissues

Explore IBEX: Open-source multiplexed imaging. Join the collaborative IBEX Imaging Community for optimized tissue processing, antibody selection, and human atlas construction.
2D slice of colon cancer tissue stained with 30 markers and imaged using the Cell DIVE system. Analysis performed using Aivia 13’s new multiplex cell detection recipe and automatic clustering tool. Each phenotype denoted in a different color.

Transforming Multiplexed 2D Data into Spatial Insights Guided by AI

Aivia 13 handles large 2D images and enables researchers to obtain deep insights into microenvironment surrounding their phenotypes with millions of detected objects and automatic clustering up to 30…
Hepatocellular Carcinoma with 13 biomarkers shown – Beta-Catenin, CD3D, CD4, CD8a, CD31, CD44, CD163, DAPI, PanCK, PCK26, PD1, SMA, and Vimentin.

Understanding Tumor Heterogeneity with Protein Marker Imaging

Explore tumor heterogeneity and immune cell dynamics. See how quantitative imaging analysis reveals spatial relationships and molecular insights crucial for advancing cancer research and therapeutics.
Adult human Alzheimer’s brain demonstrating a panel of 15 markers.

The Shape of the Brain: Spatial Biology of Alzheimer’s Disease

Uncover cell identity and brain structure in Alzheimer's disease with Cell DIVE multiplexed imaging, demonstrating how spatial biology can lead to advances in therapy development for…
Co-detection of 10 extracellular matrix proteins and 3 topographical tissue landmarks by multiplex immunostaining within a single high-grade fibrous hotspot from a human hepatocellular carcinoma

In Situ Identification of Cancer Stem Cell Niches in Hepatocellular Carcinoma

Discover how multiplexed imaging technology uncovers cancer stem cell niches in Hepatocellular Carcinoma using multiplex immunodetection, revealing extracellular matrix dynamics. Explore precise…
Esophageal tissue with a squamous cell carcinoma labelled with the 4 biomarkers PanCk, DAPI, NaKATPase, and Vimentin.

Discover how Multiplexed Bioimaging can Advance Cancer Research

Explore multiplexing with up to 60 biomarkers, enabling advanced tumor imaging approaches to gather precise, spatially-resolved single-cell data that helps enhance cancer research and clinical…
Pancreatic Ductal Adenocarcinoma with 11 Apoptosis biomarkers shown – BAK, BAX, BCL2, BCLXL, Caspase9, CIAP1, NaKATPase, PCK26, SMAC, Vimentin, and XIAP.

Multiplexing with Luke Gammon: Advance your Spatial Biology Research

Learn how multiplexing imaging and spatial biology can help researchers better understand complex biological systems. In this interview, Dr. Gammon and Dr. Pointu of Leica Microsystems discuss pain…
Multi-tissue array with 4 markers shown including DAPI, NaKATPase, PanCk, and Vimentin.

Spatial Biology: Learning the Landscape

Spatial Biology: Understanding the organization and interaction of molecules, cells, and tissues in their native spatial context
Cell counts for each biomarker were divided by total number of cells to give a percentage of biomarker positive cells out of total cells for each biomarker.

Methods to Improve Reproducibility in Spatial Biology Research

Establish reproducibility results for a Cell DIVE multiplexed imaging study in cancer research using the BAB 200 automated system from ASLS and validated antibodies from CST
PDAC Multiplexed imaging of CST panels enables an examination of immune cell components in pancreatic ductal adenocarcinoma (IPDAC) tissue on a single slide.

Characterizing tumor environment to reveal insights and spatial resolution

Antibodies from Cell Signaling Technology are validated for use with the Cell DIVE multiplexing workflow and used to probe cell lineages in the tumor microenvironment
Pancreatic Ductal Adenocarcinoma with 5 biomarkers shown – SMA, PanCK PCK26, PanCK AE1, Vimentin, and Glut1.

Dig Deeper Into the Complexities of Pancreatic Cancer with Multiplex Imaging

Cell DIVE is an iterative staining workflow for multiplexed imaging that unveils biological pathways to dig deeper into the complexities of pancreatic cancer.
How is microscopy used in spatial biology - Teaserimage

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.
Cell DIVE Multiplex Imaging Solution

Complex Made Simple: Antibodies in Multiplexed Imaging

Build panels, plan studies, and get the most from precious reagents using this antibody multiplexing guide from Leica Microsystems
Pancreatic ductal adenocarcinoma tissue section imaged with Cell DIVE

Multiplexed Imaging Types, Benefits and Applications

Multiplexed imaging is an emerging and exciting way to extract information from human tissue samples by visualizing many more biomarkers than traditional microscopy. By observing many biomarkers…
Colon adenocarcinoma with 13 biomarkers shown

Hyperplex Cancer Tissue Analysis at Single Cell Level with Cell DIVE

The ability to study how lymphoma cell heterogeneity is influenced by the cells’ response to their microenvironment, especially at the mutational, transcriptomic, and protein levels. Protein…

Designing your Research Study with Multiplexed IF Imaging

Multiplexed tissue analysis is a powerful technique that allows comparisons of cell-type locations and cell-type interactions within a single fixed tissue sample. It is common for researchers to ask…

Be Confident in your Results with Cell DIVE Validated Antibodies

The Cell DIVE System includes a carefully curated list of hundreds of commercially available antibodies validated to offer optimal specificity and sensitivity in multiplexed imaging. That validation…

Domaines d'application

Recherche sur le cancer

Le cancer est une maladie complexe et hétérogène causée par des cellules déficientes dans la régulation de la croissance. Les modifications génétiques et épigénétiques d’une cellule ou d’un groupe de…
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