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  • Microfluidics and Live Cell Imaging

    The deMello Group at ETH Zürich is engaged in a broad range of activities in the general area of microfluidics and nanoscale science. Primary specializations include the development of microfluidic devices for high-throughput biological and chemical analysis, ultra-sensitive optical detection techniques

  • Single Molecule Micromirror TIRF

    The Duderstadt Group are interested in understanding the organization and dynamics of macromolecular complexes, such as the replisome which is responsible for DNA replication.Successful DNA replication is critical for cell survival, and errors within this process have been implicated in many disease pathologies.

  • Nanophotonics

    Dr. Mivelle’s research lies within the field of nanophotonics and centers around investigations into the interactions between light and matter on the nanoscale to increase understanding of optical properties.

  • Kinetix22 Pre-Arrival Guide

    Thank you for your interest in the Kinetix22 sCMOS, the next generation in scientific CMOS cameras. This is a guide to help you prepare for the arrival of the Kinetix22, ensuring that the hardware and software of both your PC and microscope/imaging system are capable of making the most of the power of the Kinetix22 and delivering your desired data.

  • Single Molecule Spectroscopy at Heidelberg University

    Professor Herten leads the Single Molecule Spectroscopy group at Heidelberg University aiming at quantitative analytical approaches in biology and chemistry based on single-molecule data acquired with advanced fluorescence microscopy.The groups research interests range from the development of fluorescent probes for live-cell microscopy to the investigation of chemical reactions on a single-molecule level.

  • Single Molecule Tracking PALM

    The Carr Lab at the Genome Damage and Stability Centre, University of Sussex, investigates DNA metabolism processes such as DNA replication and repair. They are interested in the challenges cells face during DNA replication and the cellular processes that help the cell overcome replication fork stalling or collapse.

  • eSPIM Light Sheet

    Prof. Huang’s lab at UCSF aspires to generate a map of the entire proteome of endogenous proteins in human cells. Towards that goal they use and develop novel imaging modalities including eSPIM, a high numerical aperture epi-illumination form of selective plane illumination microscopy (SPIM).

  • Imaging Mitotic Dynamics

    Research in the Gorbsky lab focuses on the basic mechanisms of how chromosomes assemble and move during cell division in normal cells and in cancer cells, the process termed mitosis. A major emphasis is the mitotic spindle checkpoint pathway that makes sure that each copy of the 23 pairs of chromosomes is distributed equally to each of the daughter cells.

  • Single Molecule Tracking

    The lab of Prof. Kubitscheck performs a wide range of imaging across different applications including single-molecule tracking and localization, where they examine the export of ribosomal particles through nuclear pore complexes by a number of methods

  • Live Yeast Imaging

    To ensure genome stability, sexually reproducing organisms require that mating brings together exactly 2 haploid gametes and that meiosis occurs only in diploid zygotes.

  • Point Spread Function Engineering

    Christy Landes’ lab at Rice University uses point spread function (PSF) engineering by phase modulation to increase the information recoverable from a two-dimensional image.

  • Super-Resolution Microscopy at Korea University

    The Shim Group at Korea University is an interdisciplinary lab covering physical chemistry, biophysics and cell biology. Sang-Hee Shim, principal investigator and assistant professor of chemistry, leads a team composed of postdoctoral researchers and graduate students to develop new microscopic methods and apply them to answer complex biophysical questions.