The past several years have seen an accelerated development of technologies and methods that enable the non-invasive analysis of single cells. These are vital as single cell studies provide important evidence and deepen our understanding of how networks of cells work and evolve. Exploring the full potential of our dynamic user-interactive optical trapping system (Biophotonics Workstation), we can surround various types of cells with other cells or other microscopic objects, thus studying the relation between confinement and cell growth.
After years of working on light-driven trapping and manipulation, we can see that a confluence of developments is now ripe for the emergence of a new area that can contribute to nanobiophotonics - Light Robotics - which combines advances in microfabrication and optical micromanipulation together with intelligent control ideas from robotics, wavefront engineering and information optics. In the Summer 2017 we are publishing a 482 pages edited Elsevier book volume covering the fundamental aspects needed for Light Robotics including optical trapping systems, microfabrication and microassembly as well as underlying theoretical principles and experimental illustrations for optimizing optical forces and torques for Light Robotics.
We design and implement a software for use in real-time light shaping and biophotonics applications. Design considerations are addressed as well as options to mitigate common performance issues that arise in actual use. Testing was done on actual spatial light modulator hardware at 800x600 and 2048x2048 resolutions. Software performance is measured and analyzed.