Scientists have built an artificial neuron that can mimic the function of a human nerve cell and communicate in the same way as our neurons do.
Neurons are isolated from each other and communicate with the help of chemical signals, commonly called neurotransmitters or signal substances.
Inside a neuron, these chemical signals are converted to an electrical action potential, which travels along the axon of the neuron until it reaches the end.
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To date, the primary technique for neuronal stimulation in human cells is based on electrical stimulation.
However, scientists at the Swedish Medical Nanoscience Centre (SMNC) at Karolinska Institutet in collaboration with colleagues at Linkoping University, have now created an organic bioelectronic device that is capable of receiving chemical signals, which it can then relay to human cells.
"Our artificial neuron is made of conductive polymers and it functions like a human neuron," said lead investigator Agneta Richter-Dahlfors, professor of cellular microbiology.
"The sensing component of the artificial neuron senses a change in chemical signals in one dish, and translates this into an electrical signal.
"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," Richter-Dahlfors said.
The researchers hope that their innovation, described in the journal Biosensors & Bioelectronics , will improve treatments for neurologial disorders which currently rely on traditional electrical stimulation.
The new technique makes it possible to stimulate neurons based on specific chemical signals received from different parts of the body. In the future, this may help physicians to bypass damaged nerve cells and restore neural function.
"Next, we would like to miniaturise 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," said Richer-Dahlfors.