Simple Method Developed to Characterize Immune Cells in Tumors
By LabMedica International staff writers Posted on 27 Jul 2016 |
Image: A whole-slide scanner with OlyVIA software (Photo courtesy of Olympus).
Despite recent achievements in the development of cancer immunotherapies, only a small group of patients typically respond to them and therefore predictive markers of disease course and response to immunotherapy are urgently needed.
A new method has been developed for analyzing multiple tissue markers using only one slide of a tumor section to better understand immune response occurring locally. The multiplexed immunohistochemical consecutive staining on a single slide (MICSSS) helps characterize human cells involved in immune responses at the tissue site, before and after treatment with immunotherapy.
Scientists at the Icahn School of Medicine at Mount Sinai (New York, NY, USA) and their international colleagues obtained paraffin-embedded human tonsils, ulcerative colitis, non-small cell lung cancer (NSCLC), melanoma, and colorectal tumor samples from their Biorepository tissue bank. The formalin-fixed paraffin embedded (FFPE) were processed for immunohistochemistry (IHC) and images were acquired using an Olympus whole-slide scanner with OlyVIA software (Olympus Life Science, Center Valley, PA, USA) or an Eclipse Ci-E microscope (Nikon Instruments, Melville, NY, USA).
The authors have described a multiplexed chromogenic IHC strategy for high-dimensional tissue analysis that circumvents many of the limitations of regular chromogenic, immunofluorescence, and mass cytometry approaches that could be readily implemented in clinical pathology laboratories. The MICSSS method provides a new powerful tool to map the microenvironment of tissue lesional sites with excellent resolution, in a sample-sparing manner, to monitor immune changes in situ during therapy and help identify prognostic and predictive markers of clinical outcome in patients with cancer and inflammatory diseases.
Sacha Gnjatic, PhD, an Associate Professor and senior co-author said, “Our goal was to get a better understanding of immunologic responses at the tumor site while addressing the need for high-dimensional analysis using as little tissue as possible. We need more comprehensive analyses of the immune microenvironment of tumors, as part of our immune monitoring to inform treatment and predict outcomes for cancer patients.” The study was published on July 14, 2016, in the journal Science Immunology.
Related Links:
Icahn School of Medicine at Mount Sinai
Olympus Life Science
Nikon Instruments
A new method has been developed for analyzing multiple tissue markers using only one slide of a tumor section to better understand immune response occurring locally. The multiplexed immunohistochemical consecutive staining on a single slide (MICSSS) helps characterize human cells involved in immune responses at the tissue site, before and after treatment with immunotherapy.
Scientists at the Icahn School of Medicine at Mount Sinai (New York, NY, USA) and their international colleagues obtained paraffin-embedded human tonsils, ulcerative colitis, non-small cell lung cancer (NSCLC), melanoma, and colorectal tumor samples from their Biorepository tissue bank. The formalin-fixed paraffin embedded (FFPE) were processed for immunohistochemistry (IHC) and images were acquired using an Olympus whole-slide scanner with OlyVIA software (Olympus Life Science, Center Valley, PA, USA) or an Eclipse Ci-E microscope (Nikon Instruments, Melville, NY, USA).
The authors have described a multiplexed chromogenic IHC strategy for high-dimensional tissue analysis that circumvents many of the limitations of regular chromogenic, immunofluorescence, and mass cytometry approaches that could be readily implemented in clinical pathology laboratories. The MICSSS method provides a new powerful tool to map the microenvironment of tissue lesional sites with excellent resolution, in a sample-sparing manner, to monitor immune changes in situ during therapy and help identify prognostic and predictive markers of clinical outcome in patients with cancer and inflammatory diseases.
Sacha Gnjatic, PhD, an Associate Professor and senior co-author said, “Our goal was to get a better understanding of immunologic responses at the tumor site while addressing the need for high-dimensional analysis using as little tissue as possible. We need more comprehensive analyses of the immune microenvironment of tumors, as part of our immune monitoring to inform treatment and predict outcomes for cancer patients.” The study was published on July 14, 2016, in the journal Science Immunology.
Related Links:
Icahn School of Medicine at Mount Sinai
Olympus Life Science
Nikon Instruments
Latest Pathology News
- Hyperspectral Dark-Field Microscopy Enables Rapid and Accurate Identification of Cancerous Tissues
- AI Advancements Enable Leap into 3D Pathology
- New Blood Test Device Modeled on Leeches to Help Diagnose Malaria
- Robotic Blood Drawing Device to Revolutionize Sample Collection for Diagnostic Testing
- Use of DICOM Images for Pathology Diagnostics Marks Significant Step towards Standardization
- First of Its Kind Universal Tool to Revolutionize Sample Collection for Diagnostic Tests
- AI-Powered Digital Imaging System to Revolutionize Cancer Diagnosis
- New Mycobacterium Tuberculosis Panel to Support Real-Time Surveillance and Combat Antimicrobial Resistance
- New Method Offers Sustainable Approach to Universal Metabolic Cancer Diagnosis
- Spatial Tissue Analysis Identifies Patterns Associated With Ovarian Cancer Relapse
- Unique Hand-Warming Technology Supports High-Quality Fingertip Blood Sample Collection
- Image-Based AI Shows Promise for Parasite Detection in Digitized Stool Samples
- Deep Learning Powered AI Algorithms Improve Skin Cancer Diagnostic Accuracy
- Microfluidic Device for Cancer Detection Precisely Separates Tumor Entities
- Virtual Skin Biopsy Determines Presence of Cancerous Cells
- AI Detects Viable Tumor Cells for Accurate Bone Cancer Prognoses Post Chemotherapy