Medical

Tiniest-ever LED implants could help find cures for neurological disorders

Tiniest-ever LED implants could help find cures for neurological disorders
The LED probes can both activate individual neurons, and detect subsequent responses in neighboring neurons
The LED probes can both activate individual neurons, and detect subsequent responses in neighboring neurons
View 4 Images
Each probe is less than a tenth of a millimeter wide
1/4
Each probe is less than a tenth of a millimeter wide
The probes contain 12 LEDs that are no larger than a neuron's cell body, along with 32 electrodes
2/4
The probes contain 12 LEDs that are no larger than a neuron's cell body, along with 32 electrodes
The technology has already been tested on mice at New York University, in a study on how the animals form memories
3/4
The technology has already been tested on mice at New York University, in a study on how the animals form memories
The LED probes can both activate individual neurons, and detect subsequent responses in neighboring neurons
4/4
The LED probes can both activate individual neurons, and detect subsequent responses in neighboring neurons
View gallery - 4 images

Before cures for diseases such as Alzheimer's can be found, scientists need to develop a better understanding of how neurons in the brain communicate with one another. Researchers at the University of Michigan recently took a step towards that goal, by developing what are said to be the smallest LED probes ever implanted in a living brain.

In the field of optogenetics, implanted optical fibers are used to stimulate brain cells by exposing them to pulses of light, while a second device records how they react. According to the U Michigan scientists, however, such a setup can't record the manner in which neurons communicate with one another – the new probes can reportedly do just that.

Each probe is less than a tenth of a millimeter wide, and contains 12 LEDs that are no larger than a neuron's cell body, along with 32 electrodes. Any one LED can activate a single neuron. When it does so, the electrodes are able to detect any responses from other neurons in the surrounding network.

The probes contain 12 LEDs that are no larger than a neuron's cell body, along with 32 electrodes
The probes contain 12 LEDs that are no larger than a neuron's cell body, along with 32 electrodes

The technology has already been tested on mice at New York University, in a study on how the animals form memories.

"Now we can know how a group of cells, both adjacent and farther away, are responding to the activation of a single cell," says UM postdoctoral researcher Fan Wu. "This will help us better understand how these cells are communicating with each other."

A paper on the probes was published this month in the journal Neuron. Scientists at the University of Illinois and Washington University have previously developed their own neuron-activating LED probes, although they don't also contain electrodes for measuring responses.

Source: University of Michigan

View gallery - 4 images
No comments
0 comments
There are no comments. Be the first!