Researchers have built the world’s first artificial neuron that’s capable of mimicking the function of an organic brain cell - including the ability to translate chemical signals into electrical impulses and communicate with other human cells.
These artificial neurons are the size of a fingertip and contain no ‘living’ parts, but the team is working on shrinking them down so they can be implanted into humans. This could allow us to effectively replace damaged nerve cells and develop new treatments for neurological disorders, such as spinal cord injuries and Parkinson’s disease.
"Our artificial neuron is made of conductive polymers and it functions like a human neuron," lead researcher Agneta Richter-Dahlfors from the Karolinska Institutet in Sweden said in a press release.
Until now, scientists have only been able to stimulate brain cells using electrical impulses, which is how they transmit information to the cells. But in our bodies, they're stimulated by chemical signals, and this is how they communicate with other neurons.
By connecting enzyme-based biosensors to organic electronic ion pumps, Richter-Dahlfors and her team have now managed to create an artificial neuron that can mimic this function, and they've shown that it can communicate chemically with organic brain cells even over large distances.
"The sensing component of the artificial neuron senses a change in chemical signals in one dish, and translates this into an electrical signal," said Richter-Dahlfors. "This electrical signal is next translated into the release of the neurotransmitter acetylcholine in a second dish, whose effect on living human cells can be monitored."
This means that artificial neurons could theoretically be integrated into complex biological systems, such as our bodies, and could allow scientists to replace or bypass damaged nerve cells. So imagine being able to use the device to restore function to paralyzed patients, or heal brain damage.
"Next, we would like to miniaturize this device to enable implantation into the human body," said Richer-Dahlfors.“We foresee that in the future, by adding the concept of wireless communication, the biosensor could be placed in one part of the body, and trigger release of neurotransmitters at distant locations."
"Using such auto-regulated sensing and delivery, or possibly a remote control, new and exciting opportunities for future research and treatment of neurological disorders can be envisaged," she added.
The results of lab trials have been published in the journal Biosensors and Bioelectronics.
We're really looking forward to seeing where this research goes. While the potential for treating neurological disorders are incredibly exciting, the artificial neurons could one day also help us to supplement our mental abilities and add extra memory storage or offer faster processing, and that opens up some pretty awesome possibilities.