Wireless Activation of Targeted Brain Circuits in Less Than One Second

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Summary: A newly developed system uses wireless technology to remotely activate specific brain networks in fruit flies in less than one second.

Source: Rice University

A research team led by Rice University neuroengineers has created wireless technology to remotely activate specific brain circuits in fruit flies in under one second.

In a published demonstration in Nature Materialsresearchers from Rice, Duke University, Brown University and Baylor College of Medicine used magnetic signals to activate targeted neurons that controlled the body position of freely moving fruit flies in an enclosure.

“To study the brain or to treat neurological disorders the scientific community is searching for tools that are both incredibly precise, but also minimally invasive,” said study author Jacob Robinson, an associate professor in electrical and computer engineering at Rice and a member of Rice’s Neuroengineering Initiative.

“Remote control of select neural circuits with magnetic fields is somewhat of a holy grail for neurotechnologies. Our work takes an important step toward that goal because it increases the speed of remote magnetic control, making it closer to the natural speed of the brain.”

Robinson said the new technology activates neural circuits about 50 times faster than the best previously demonstrated technology for magnetic stimulation of genetically defined neurons.

“We made progress because the lead author, Charles Sebesta, had the idea of ​​using a new ion channel that was sensitive to the rate of temperature change,” Robinson said.

“By bringing together experts in genetic engineering, nanotechnology and electrical engineering we were able to put all the pieces together and prove this idea works. This was really a team effort of world-class scientists we were fortunate enough to work with.”

The researchers used genetic engineering to express a special heat-sensitive ion channel in neurons that cause flies to partially spread their wings, a common mating gesture.

The researchers then injected magnetic nanoparticles that could be heated with an applied magnetic field. An overhead camera watched flies as they roamed freely about an enclosure atop an electromagnet. By changing the magnet’s field in a specified way, the researchers could heat the nanoparticles and activate the neurons.

Researchers from Rice University, Duke University, Brown University and Baylor College of Medicine developed a magnetic technology to wirelessly control neural circuits in fruit flies. They used genetic engineering to express heat-sensitive ion channels in neurons that control the behavior and iron nanoparticles to activate the channels. When researchers activated a magnetic field in the flies’ enclosure, the nanoparticles converted magnetic energy to heat, firing the channels and activating the neurons. An overhead camera filmed flies during experiments, and a visual analysis showed flies with the genetic modifications assumed the wing-spread posture within approximately half a second of receiving the magnetic signal. Credit: C. Sebesta and J. Robinson/Rice University

An analysis of video from the experiments showed flies with the genetic modifications assumed the wing-spread posture within approximately half a second of the magnetic field change.

Robinson said the ability to activate genetically targeted cells at precise times could be a powerful tool for studying the brain, treating disease and developing direct brain-machine communication technology.

Robinson is principal investigator on MOANA, an ambitious project to develop headset technology for nonsurgical, wireless, brain-to-brain communication. Short for “magnetic, optical and acoustic neural access,” MOANA is funded by the Defense Advanced Research Projects Agency (DARPA) to develop headset technology that can both “read,” or decode, neural activity in one person’s visual cortex and “write, “or encode, that activity in another person’s brain. The magnetogenetic technology is an example of the latter.

Robinson’s team is working toward a goal of partially restoring vision to patients who are blind. By stimulating parts of the brain associated with vision, MOANA researchers hope to give patients a sense of vision even if their eyes no longer work.

Credit: Rice University

“The long-term goal of this work is to create methods for activating specific regions of the brain in humans for therapeutic purposes without ever having to perform surgery,” Robinson said. “To get to the natural precision of the brain we probably need to get a response down to a few hundredths of a second. So there is still a way to go.”

Rice study co-authors include Sebesta, Daniel Torres Hinojosa, Joseph Asfouri, Guillaume Duret, Kaiyi Jiang, Linlin Zhang, Qingbo Zhang and Gang Bao. Additional co-authors include Boshuo Wang, Zhongxi Li, Stefan Goetz and Angel Peterchev of Duke; Zhen Xiao and Vicki Colvin of Brown; and Herman Dierick of Baylor.

Funding: The research was funded by DARPA (N66001-19-C-4020), the National Science Foundation (1707562), the Welch Foundation (C-1963) and the National Institutes of Health (R01MH107474).

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About this neurotech research news

Author: Jade Boyd
Source: Rice University
Contact: Jade Boyd – Rice University
Image: The image is credited to C. Sebesta and J. Robinson/Rice University

OriginalResearch: Closed access.
Subsecond multichannel magnetic control of select neural circuits in freely moving flies” by Jacob Robinson et al. Nature Materials


Abstract

Subsecond multichannel magnetic control of select neural circuits in freely moving flies

Precisely timed activation of genetically targeted cells is a powerful tool for the study of neural circuits and control of cell-based therapies.

Magnetic control of cell activity, or ‘magnetogenetics’, using magnetic nanoparticle heating of temperature-sensitive ion channels enables remote, non-invasive activation of neurons for deep-tissue applications and freely behaving animal studies.

However, the in vivo response time of thermal magnetogenetics is currently tens of seconds, which prevents precise temporal modulation of neural activity. Moreover, magnetogenetics has yet to achieve in vivo multiplexed stimulation of different groups of neurons.

Here we produce subsecond behavioral responses in Drosophila melanogaster by combining magnetic nanoparticles with a rate-sensitive thermoreceptor (TRPA1-A). Furthermore, by tuning magnetic nanoparticles to respond to different magnetic field strengths and frequencies, we achieve subsecond, multichannel stimulation.

These results bring magnetogenetics closer to the temporal resolution and multiplexed stimulation possible with optogenetics while maintaining the minimal invasiveness and deep-tissue stimulation possible only by magnetic control.

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