The human brain is an organic CPU made of trillions of connections between many billions of neurons. Understanding such a complicated organ is a massive scientific undertaking, and researchers often use simplified models to uncover small pieces of the neurological puzzle. In a report published in Micromachines, researchers at The University of Tokyo Institute of Industrial Science describe their method to create one such model, using microscopic plates to connect neurons together one cell at a time.
Research into the brain typically involves the use of in vitro cultures, which are collections of neurons grown together in a dish. A culture represents, in effect, a highly pared-down version of a brain, and one that can be chemically or electrically manipulated. While cultures are indispensable to neurological research, they suffer from considerable limitations.
"In vitro culture models are essential tools because they approximate relatively simple neuron networks and are experimentally controllable," study first author Shotaro Yoshida explained. "These models have been instrumental to the field for decades.
The problem is that they're very difficult to control, since the neurons tend to make random connections with each other. If we can find methods to synthesise neuron networks in a more controlled fashion, it would likely spur major advances in our understanding of the brain."
The researchers took advantage of recent insights into how neurons behave; namely, that geometric shapes can help guide neurons, telling them where and how to grow. In this case, the team used a synthetic neuron-adhesive material to make a microscopic plate.
The plate is circular with two protruding rectangles, somewhat resembling a bead on a tight string. They found that this shape guides neurons to grow in a very defined way: when placed onto the microplate, a neuron's cell body settles onto the circle, while the axon and dendrites ? the branches that let neurons communicate with each other ? grow lengthwise along the rectangles.
"What was especially important in this system was to have control over how the neurons connected," Yoshida added. "We designed the microplates to be movable, so that by pushing them around, we could physically move two neurons right next to each other. Once we placed them together, we could then test whether the neurons were able to transmit a signal."
Neurons communicate with one another through synapses, specialised structures that let chemical messengers travel from one neuron to the next. Using a technique to visualise the parts of a synapse, the research team found that the microplate-riding neurons were indeed able to form these communication hubs.
What was more, the hubs were functional: when one neuron lit up with electrically charged ions, its partner lit up at precisely the same time.
While the team aims to further refine the system (only a small fraction of neurons could be successfully connected through working synapses), the results of the study suggest an important step forward in using microplates for research.
"This is, to the best of our knowledge, the first time a mobile microplate has been used to morphologically influence neurons and form functional connections," lead investigator Shoji Takeuchi concluded.
"We believe the technique will eventually allow us to design simple neuron network models with single-cell resolution. It's an exciting prospect, as it opens many new avenues of research that aren't possible with our current suite of experimental tools."
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Image credit: University of Tokyo.