Dr. Ryan McNamara demonstrates the role of tetraspanin proteins in tracking exosome maturation inside of the cell and the relevance of super-resolution microscopy to visualize and characterize extracellular vesicles to understand their relevance in research.
Learn how the Nanoimager allows visualization, quantification and tracking of EVs at a single-molecule level, in solution and in live cells.
Dr. Siobhan King highlights applications that can be performed on the Nanoimager including detecting and visualizing extracellular vesicles as well as imaging and tracking viral particles.
Learn how the Nanoimager platform allows visualization and quantification of extracellular vesicles at a single-molecule level.
We've compiled our latest data in a simple application note to demonstrate how researchers can size, track and characterize extracellular vesicles in solution or in live cells.
This guide focuses on recent progress in fluorescent super-resolution imaging and characterization of extracellular vesicles.
Dr. Michael Senior discusses exciting opportunities for accelerating the development pipeline and how single-molecule microscopy can deliver effective personalized immunotherapy.
Learn how the Nanoimager platform supports super-resolution imaging of cultured neuronal cells and the precise localization of different synaptic proteins.
Learn how the Nanoimager platform supports imaging of brain tissue at high sensitivity and the visualization of synaptic proteins at a single-molecule level.
Learn how the Nanoimager platform allows imaging of brain tissue at high-sensitivity and the visualization of individual synaptic proteins at high-resolution.
Download our viral particle application note which includes case studies on sizing, tracking and quantification of viral particles.
Learn how the Nanoimager platform allows visualization and quantification of viral particles at a single molecule level.
Dr. Mark Harmon highlights how to visualize structures from cell membrane to nucleus in unprecedented detail. With its small but mighty design, the Nanoimager delivers the ability to see, count and track single molecules from the convenience of your benchtop.
Learn how the Nanoimager allows real-time visualization and quantification of cellular processes at a single-molecule level, in live cells.
Learn how the Nanoimager provides a multiplex solution for novel antibiotic development.
Learn how the Nanoimager enables visualization and quantification of bacterial infection and host-pathogen interactions at a single-molecule level.
Dr. Zehra Nizami demonstrates how quick and easy it is to perform direct Stochastic Optical Reconstruction Microscopy (dSTORM) experiments and data analysis.
Download the full Nanoimager technical specifications as a PDF.
We've put together a one page, printable PDF table to help you compare the most popular fluorophores used for PALM imaging, which include photoactivatable, photoconvertible and photoswitchable fluorescent proteins, as well as synthetic dyes.
We've put together a one page, printable PDF to help you choose between the Nanoimager's key super-resolution microscopy techniques. It covers core techniques including dSTORM, PALM, SPT and smFRET.
When preparing a sample for STORM microscopy it is also crucial to select an appropriate buffer solution, which will efficiently regulate blinking behavior and help achieve high quality super-resolution images. Here is a brief guide to STORM buffer components and how they can affect sample imaging.
We have put together some tips to help you optimize your immunofluorescence staining protocol and increase the signal-to-noise ratio in your samples.
Our team of scientists are waiting to help with your questions