Mosaic System

Mosaic is the perfect tool for active illumination applications such as Optogenetics, optophysiology, photobleaching/activation and uncaging. This patented combination of digital mirror device used with a microscope delivers high speed targeting of complex light patterns to your sample. For optogenetics you can even combine complimentary activating and inhibitory wavelengths at the same time for tight spatial target protein control

Mosaic is a patented instrument platform built around MEMS Digital Mirror Devices (DMD). DMDs were developed at Texas Instruments in 1987 and are now in widespread use in digital projectors and other display devices. The DMD comprises an array of individually addressable micro-mirrors that can be switched "on and off" (tilted) with MEMS "hinge" elements. DMD arrays contain hundreds of thousands to millions of micro-mirrors.

Mosaic exploits DMD in a proprietary programmable platform, integrated with scientific light sources including lasers, LEDs and arc lamps, and operates from 360 to 800 nm. It is offered with a range of high performance microscope adapter optics and can be integrated with CLSM, spinning disk and wide field imaging modalities.

High speed frame switching (5000 Hz) makes Mosaic suitable for many dynamic applications including bleaching, uncaging, photoswitching, optogenetics and constrained illumination. Variable intensity distributions can be achieved by rapid gating of mirror patterns. Mosaic has a unique capability to illuminate in parallel an arbitrary number of complex regions (sometimes called “zero delta t”) that sets it apart from galvo-based devices and makes it especially attractive for uncaging, photoswitching and light activation. It is a unique tool for the study of optically stimulated intra and inter-cellular activity in neuroscience and physiology, as well as for function-structure studies with photoswitching fluorescent proteins. Mosaic uses dichroic coupling to the microscope light path and is therefore capable of simultaneous stimulation and imaging.