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Building Three-Dimensional Neuronal Networks Coupled to Micro-Electrode Arrays

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简介:

Overview

This article describes a method for constructing a 3D neuronal network using rat embryo hippocampal neurons on a microelectrode array (MEA). The process involves layering neurons on microbeads and allowing them to self-assemble into a compact structure.

Key Study Components

Area of Science

  • Neuroscience
  • Cell culture techniques
  • Microelectrode arrays

Background

  • Neuronal networks are essential for studying brain function.
  • 3D cultures can better mimic in vivo conditions compared to 2D cultures.
  • Microelectrode arrays allow for the monitoring of neuronal activity.
  • Self-assembly techniques can enhance the structural complexity of neuronal networks.

Purpose of Study

  • To develop a reliable method for creating 3D neuronal networks.
  • To investigate the growth and connectivity of neurons in a controlled environment.
  • To utilize microbeads for enhancing the structural organization of neuronal cultures.

Methods Used

  • Isolation of rat embryo hippocampal neurons.
  • Coating of microelectrode arrays and glass microbeads with adhesion factors.
  • Layering of neurons on microbeads and transferring them to the MEA.
  • Incubation under controlled conditions to promote cell attachment and growth.

Main Results

  • Successful formation of a 2D neuronal network on the MEA.
  • Microbeads self-assembled into a hexagonal structure with adherent neurons.
  • Development of a packed 3D neuronal network over time.
  • Neurons exhibited growth and interconnectivity in the 3D structure.

Conclusions

  • The method effectively constructs 3D neuronal networks for research purposes.
  • Self-assembly of microbeads enhances the complexity of neuronal cultures.
  • This approach can be applied to study neuronal behavior and interactions.

Frequently Asked Questions

What are microelectrode arrays used for?
Microelectrode arrays are used to monitor and stimulate neuronal activity in cultured neurons.
How do microbeads contribute to neuronal culture?
Microbeads provide a scaffold for neurons to adhere to, promoting self-assembly and structural organization.
What is the significance of 3D neuronal networks?
3D neuronal networks better mimic the in vivo environment, allowing for more accurate studies of neuronal behavior.
What conditions are required for incubating the neuronal cultures?
The cultures should be incubated at 37 degrees Celsius with 5% humidified carbon dioxide.
How long does it take for the neuronal networks to develop?
The initial assembly takes several hours, with full development observed over 48 hours.
Can this method be applied to other types of neurons?
Yes, the method can potentially be adapted for other neuronal types and applications.

Take a suspension of rat embryo hippocampal neurons.

Transfer the neurons onto the adhesion factor-coated active area of a microelectrode array, or MEA. This active area is confined by a polymer structure.

Incubate the MEA. Neurons adhere to the coated MEA active area, forming a 2D neuronal network.

Additionally, transfer the neurons onto an adhesion factor-coated glass microbead monolayer in membrane inserts within a multi-well plate.

Incubate for the neurons to attach to the adhesion factor-coated beads.

Transfer the microbeads with adherent neurons to the confined MEA area containing the neuronal network.

Microbeads self-assemble to form a hexagonal structure.

Repeat the microbead transfer on the MEA several times, building layers that self-assemble, forming a packed 3D structure.

Add media to the MEA confined active area and incubate.

Neurons grow, forming an interconnected 3D neuronal network.

Plate the cells at a density of 2,000 cells per square millimeter onto the active area of the MEA, defined by the PDMS constraint to create a 2D neuronal network. Next, place the MEA device into the incubator with 5% humidified carbon dioxide atmosphere at 37 degrees Celsius.

To complete the preliminary step for the construction of 3D culture, distribute 160 microliters of the suspension with a cell concentration of 600 to 700 cells per microliter onto the surface of the microbeads monolayer positioned inside the multiwell plates. Then, place the multiwell plates in the incubator with 5% humidified carbon dioxide atmosphere at 37 degrees Celsius.

Six to eight hours after plating, transfer 30 to 40 microliters of the suspension with microbeads and neurons to the area of the MEA delimited by the PDMS constraint. After each transfer, wait about half a minute to allow the microbeads to self-assemble in a hexagonal compact structure. Once all the layers are deposited and spontaneously assembled, add 300 microliters of medium on the top of the area delimited by the PDMS constraint.

Put the 3D structure coupled to the MEA in the incubator at 37 degrees Celsius and 5% carbon dioxide for 48 hours.

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