Fibre guides optogenetics to brain breakthroughs
Advances in optical fibres and microscale LEDs are furthering neuroscientists’ understanding of the brain, Susan Curtis discovers
Advances in optical fibres and microscale LEDs are furthering neuroscientists’ understanding of the brain, Susan Curtis discovers
What is the potential of optogenetics? What are the future business fields and sales markets? The Innovation Network Optogenetics aims to answer these questions
The Laser Zentrum Hannover (LZH), has set up a German-based optogenetics research network to explore the potentials of light-controllable biomolecules and the latest light technology, enabling the development of new biomedical treatments
As microscopes become ever more powerful, a growing band of businesses are racing to make the latest technologies more accessible and more affordable, reports Rebecca Pool
Illustration of a three-dimensional crystal with various types of confining centres. (a) Crystal with four confining centres, each trapping waves (yellow) in all three dimensions simultaneously. (b) Crystal with a linear confining centre where waves can propagate in one dimension, analogous to an optical fibre. (c) Crystal with a planar confining centre where waves can propagate in two dimensions, analogous to a 2D electron gas. (Image: Vos et al.)
Newly discovered fundamental rules have been embedded into software to dramatically optimise the design of photonic integrated circuits