Danaher Corporation’s Post

I'm elated to share our new research paper, titled "Acoustic Platforms Meet MXenes A New Paradigm Shift in the Palette of Biomedical Applications," got published in the journal Nanoscale (Royal Society of Chemistry) !!!!! In this paper, we combined acoustic science with the world of MXenes and rendered the synthetic approaches and a multitude of applications in the domain of biomedical fields like sensors, bioimaging, cancer therapy, etc. I would like to sincerely thank my friend SHAHANA C and Prof. Vivek Raju for the wonderful collaboration and last but not least my guide Prof. Abdul Rasheed P for the guidance. Follow the link to read the paper : https://lnkd.in/g_q9_sTg #acoustics #mxene #2dmaterials #biomedicalengineering #nanotechnology

 🔬 Cubes in Action Excited to share some of the innovative work our customers are doing with our CUBES!   This time, we're highlighting a study by Sabine Leitner from the University of Applied Sciences Wiener Neustadt (Fachhochschule Wiener Neustadt), Competence Centre for Preclinical Imaging and Biomedical Engineering.   The radiation dose delivered to an animal during a cone-beam-shaped micro-computed Tomography (micro-CT) is not negligible, especially in cancer research where high doses of ionizing radiation may interfere with the respective study objectives and alter the experimental outcome. This study aimed to verify the estimated, calculated dose values of the X-CUBE (micro-CT) from MOLECUBES for further preclinical in vivo imaging. Image data were acquired with the cone-beam micro-CT system, which enables a spiral acquisition mode. This study validated the dose estimation of the X-CUBE and thus provided crucial information for avoiding dose-induced radiobiological effects.   🔍 Interested in more applications like this? Visit the Knowledge Center on our website to see more of our customers' work in the spotlight. 🔗 Link to the application center can be found in the comments.   #CubesInAction #PreclinicalImaging #PreclinicalResearch #CT #ValidationResearch

We welcome Larysa Baraban to the newly established Chair of Medical Nanotechnology at the Faculty of Medicine and Universitätsklinikum Carl Gustav Carus Dresden at Technische Universität Dresden. The professorship was jointly established by the Helmholtz-Zentrum Dresden-Rossendorf (HZDR) and the Else Kröner Fresenius Center (EKFZ) for Digital Health. Larysa Barabans research focusses on #nanoelectronics for individualized cancer #immunotherapies and innovative, cost-effective methods for pathogen detection. Read the full press release here: ➡ https://lnkd.in/e3sAZGyT #MedicalNanotechnology #PrecisionOncology

🌟 Exciting Research Update! 🌟 Matthias Geiger and his team shared a really study on cell migration, a crucial process in both organ development and disease conditions like cancer. Their innovative work introduces a microfluidic system designed to investigate how cells migrate through confined spaces, which can dramatically deform the cell and its nucleus. 2-photon-polymerization has been used to create smooth anisotropically curved channels at the cell scale, with constriction channels of 2 or 4 μm radius. These channels mimic the tight extracellular matrix (ECM) environments cells navigate in the body, compressing the nucleus significantly—by 3.5% and 14.2% of its undeformed cross-sectional area, respectively. By studying cerebellar granule cells in this controlled setup, Dr.Geiger aims to uncover how geometrical confinement affects cell behavior and transcriptome. This ex vivo methodology provides new insights into cellular deformation and its potential impact on 3D-genomic architecture and DNA methylation. If you are looking for a high-resolution master mold with an advanced design like in this study, feel free to contact me or check out our mold service: https://lnkd.in/eZJK5MWj #CellBiology #Microfluidics #CancerResearch #OrganDevelopment #ScientificInnovation

🌟 Exciting Research Update! 🌟 Matthias Geiger and his team shared their latest study on cell migration, a crucial process in both organ development and disease conditions like cancer. Their innovative work introduces a microfluidic system designed to investigate how cells migrate through confined spaces, which can dramatically deform the cell and its nucleus. They used 2-Photon-Polymerization to create smooth, anisotropically curved channels at the cell scale, with constriction channels of 2 or 4 μm radius. These channels mimic the tight extracellular matrix (ECM) environments cells navigate in the body, compressing the nucleus significantly—by 3.5% and 14.2% of its undeformed cross-sectional area, respectively. By studying cerebellar granule cells in this controlled setup, the aim is to uncover how geometrical confinement affects cell behavior and transcriptome. This ex vivo methodology provides new insights into cellular deformation and its potential impact on 3D-genomic architecture and DNA methylation. If you are looking for a high-resolution master mold with an advanced design like in this study, feel free to contact me or check out our mold service: https://lnkd.in/eZJK5MWj 🚀🔬 #CellBiology #Microfluidics #CancerResearch #OrganDevelopment #ScientificInnovation

Correlative light electron #microscopy is a powerful technique that can provide contextual analysis of complex biological systems and disorders. Read this application note to learn how a research team at EMBL deconvoluted the process of cancer metastasis using different imaging modalities and Thermo Scientific’s Amira Software

Correlative light electron #microscopy is a powerful technique that can provide contextual analysis of complex biological systems and disorders. Read this application note to learn how a research team at EMBL deconvoluted the process of cancer metastasis using different imaging modalities and Thermo Scientific’s Amira Software

Correlative light electron #microscopy is a powerful technique that can provide contextual analysis of complex biological systems and disorders. Read this application note to learn how a research team at EMBL deconvoluted the process of cancer metastasis using different imaging modalities and Thermo Scientific’s Amira Software

Correlative light electron #microscopy is a powerful technique that can provide contextual analysis of complex biological systems and disorders. Read this application note to learn how a research team at EMBL deconvoluted the process of cancer metastasis using different imaging modalities and Thermo Scientific’s Amira Software

Single cell Spatial research can be challenging. The team at NanoString is committed to supporting you along the journey. One of the first tips from our scientists for successful 1000 plex assay runs is the importance of understanding the role of tissue and disease type and how it will impact data. CosMx SMI is compatible with a wide range of tissue types for both Human and Mouse, normal and diseased including panels targeted towards Oncology and Neuroscience. Our scientists have created graphs to help guide you in your analysis. Show me! https://bit.ly/3RtpntN #singlecellresearch #tipsforresearchers #SingleCellImaging #SpatialMultiomics #CellSegmentation #SpatialBiology This post may include information regarding CosMx™ SMI products for RNA detection, which products are not available in the member states of the European Unified Patent Court, as further described here - https://bit.ly/498JPIB.