UK markets closed
  • FTSE 100

    7,500.89
    +34.98 (+0.47%)
     
  • FTSE 250

    20,338.96
    +93.53 (+0.46%)
     
  • AIM

    933.20
    +4.84 (+0.52%)
     
  • GBP/EUR

    1.1820
    +0.0002 (+0.02%)
     
  • GBP/USD

    1.2139
    -0.0064 (-0.52%)
     
  • BTC-GBP

    20,170.31
    +326.28 (+1.64%)
     
  • CMC Crypto 200

    574.64
    +3.36 (+0.59%)
     
  • S&P 500

    4,280.15
    +72.88 (+1.73%)
     
  • DOW

    33,761.05
    +424.38 (+1.27%)
     
  • CRUDE OIL

    91.88
    -2.46 (-2.61%)
     
  • GOLD FUTURES

    1,818.90
    +11.70 (+0.65%)
     
  • NIKKEI 225

    28,546.98
    +727.65 (+2.62%)
     
  • HANG SENG

    20,175.62
    +93.19 (+0.46%)
     
  • DAX

    13,795.85
    +101.34 (+0.74%)
     
  • CAC 40

    6,553.86
    +9.19 (+0.14%)
     

Scientists create remote-controlled flies by hacking their brains

·1-min read
 (Wikimedia Commons)
(Wikimedia Commons)

Scientists have figured out how to hack the brains of fruit flies in order to control them wirelessly.

A team of neuroengineers led by Rice University were able to use magnetic signals to activate targeted neurons that control the body position and movement of the flies.

The remote-controlled insects represent the “holy grail” of neurotechnologies, according to Rice University’s Jacob Robinson, as the science could be used in everything from treating diseases, to developing brain-machine interfaces.

To achieve the feat, the research team brought together experts in genetic engineering, nanotechnology and electrical engineering. They began by genetically engineering the flies to express a certain heat-sensitive ion channel in their neurons.

By injecting iron oxide nanoparticles into their brains to act as a heat trigger, the researchers were able to use a magnetic field to heat up the particles and activate the neuron.

The specific neuron they chose was one that caused the insects to spread their wings, which is a common mating gesture.

A demonstration of the technique, published in the scientific journal Nature Materials, showed that it was able to activate neural circuits 50 times faster than any previous technology.

“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 Robinson, an associate professor in electrical and computer engineering at Rice University and one of the study’s authors.

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

Our goal is to create a safe and engaging place for users to connect over interests and passions. In order to improve our community experience, we are temporarily suspending article commenting