Viral replication strategies and life cycles vary depending on the virus types and can differ throughout all stages, including virus entry, replication, latency, and shedding (Figure 1). Understanding infection and ...
This application note introduces you to a new approach that correlates optical tweezers and the latest imaging techniques to study phase separation properties in real time. Based on four recent ...
Dynamic Single-Molecule analysis One of the big challenges in Drug Discovery today is that all current life science tools working at the molecular level either measure static structure or average ...
Scientists can use optical tweezers to trap beads and catch a filament with motor proteins bound to it in-between. This filament can then be manipulated by moving the beads, while ...
Scientists can use optical tweezers to trap beads and catch a biomolecule, such as a protein, in between. The folding and unfolding of the protein can then be monitored by ...
The m-Trap™ is the first entry-level optical tweezers instrument specifically developed for high resolution single-molecule research
Below you will find various links to Application notes on a variety of subjects using the Lumicks optical tweezer systems. Study and Visualize DNA / RNA Structural Dynamics at the ...
The C-Trap™ is the world’s first instrument that allows simultaneous manipulation and visualisation of single-molecule interactions in real time.
