Lighting technology used in smartphone displays is able to activate live cells that are genetically programmed to respond to light, scientists at the University of St Andrews have revealed.
The findings as “a bit like cells watching TV”, in the words of Professor Malte Gather from the School of Physics and Astronomy, who led the research.
Using the ability of organic light emitting diodes (OLEDs) to “switch on” individual cells in the lab opens the door to cell-specific optogenetic control in cultured neuronal networks, brain slices, and other biomedical research applications.
Working with Dr Gareth Miles from the School of Psychology and Neuroscience, Professor Gather and his team used OLEDs to manipulate individual, live cells from a human embryonic kidney cell line that were tweaked to produce a light-sensitive protein. Upon exposure to blue OLED light from pixels directly underneath the cell, the electric activity of individual targeted cells was stimulated, while neighbouring cells remained in the dark and stayed inactive.
[caption id="attachment_3867” align="aligncenter” width="640”] Credit: A. Steude et al[/caption]
To test their approach, the team used a standard cell line.
The goal, however, is to apply the technology to activate individual neurons or groups of neurons, which would facilitate new ways of studying neuronal network function in the lab and ultimately advance knowledge of the neuronal dysfunction that underlies devastating neurodegenerative conditions such as Alzheimer’s Disease, Parkinson’s Disease and Motor Neurone Disease.
Professor Gather said:
We hope to apply OLED technology to study processes in networks of neurons in a new way. Depending on which picture we show to the network, we expect to see different responses and thus better understand how the cells are linked within the network. A principal advantage of the lens-free OLED approach is the capability to perform multiple experiments in parallel and without damage to the cells.“
The results suggest that OLEDs are an ideal platform technology for investigating and controlling biological processes with single cell resolution.
Study: Arrays of microscopic organic LEDs for high-resolution optogenetics, Science Advances (2016). DOI: 10.1126/sciadv.1600061
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