虎扑电竞 虎扑电竞

Can Lab-Grown Neurons Exhibit Plasticity?

"Neurons that fire together, wire together" describes the neural plasticity seen in human brains, but neurons grown in a dish don't seem to follow these rules. Neurons that are cultured in-vitro form random and meaningless networks that all fire together. They don't accurately represent how a real brain would learn, so we can only draw limited conclusions from studying it.

But what if we could develop in-vitro neurons that actually behaved more naturally?

A research team at Tohoku University has used microfluidic devices to reconstitute biological neuronal networks bearing connectivity resembling that found in animal nervous systems. They showed that such networks exhibit complex activity patterns that were able to be "reconfigured" by repetitive stimulation. This remarkable finding provides new tools for studying learning and memory.

The results were published online in Advanced Materials Technologies on November 23, 2024.

(a) Schematic of the microfluidic device and cell culture. (b) Photograph of neuronal networks. Neurons are separated by square areas, and these are connected through the microchannels. ?Hakuba Murota et al.

In certain areas of the brain, information is encoded and stored as "neuronal ensembles," or groups of neurons that fire together. Ensembles change based on input signals from the environment, which is considered to be the neural basis of how we learn and remember things. However, studying these processes using animal models is difficult because of its complex structure.

"The reason there is a need to grow neurons in the lab is because the systems are much simpler," remarks Hideaki Yamamoto (Tohoku University), "Lab-grown neurons allow scientists to explore how learning and memory work in highly controlled conditions. There is a demand for these neurons to be as close to the real thing as possible."

(a) Activities of neurons and neuronal ensembles that emerged during the experiment. Each grey dot indicates the individual activity of the neuron. Colour lines at the bottom represent detected neuronal ensembles. (b) Spatial maps of neurons belonging to neuronal ensembles. (c) The changes in frequency of occurrence of neuronal ensembles during experiments. The frequency of each ensemble is changed before and after stimulation. ?Hakuba Murota et al.

The research team created a special model using a microfluidic device--a small chip with tiny 3D structures. This device allowed neurons to connect and form networks similar to those in the animals' nervous system. By changing the size and shape of the tiny tunnels (called microchannels) that connect the neurons, the team controlled how strongly the neurons interacted.

The researchers demonstrated that networks with smaller microchannels can maintain diverse neuronal ensembles. For example, the in-vitro neurons grown in traditional devices tended to only exhibit a single ensemble, while those grown with the smaller microchannels showed up to six ensembles. Additionally, the team found that repeated stimulation modulates these ensembles, showing a process resembling neural plasticity, as if the cells were being reconfigured.

This microfluid technology in conjunction with in-vitro neurons could be used in the future to develop more advanced models that can mimic specific brain functions, like forming and recalling memories.

Publication Details:

Title: Precision Microfluidic Control of Neuronal Ensembles in Cultured Cortical Networks
Authors: Hakuba Murota, Hideaki Yamamoto, Nobuaki Monma, Shigeo Sato, Ayumi Hirano-Iwata
Journal: Advanced Materials Technologies
DOI: 10.1002/admt.202400894

Press release in Japanese

虎扑电竞:

Hideaki Yamamoto
虎扑电竞 Institute of Electrical Communication
Email: hideaki.yamamoto.e3tohoku.ac.jp
Website: https://researchmap.jp/7000010006

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