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Generating 3D Co-culture Spheres of Astrocytes and Neurons to Induce Synapse Formation

作者：

简介：

Overview

This article describes a method for creating 3D coculture spheres of astrocytes and neurons using a multiwell plate. The technique emphasizes the importance of low surface tension in promoting cell aggregation and synapse formation.

Key Study Components

Area of Science

Neuroscience
Cell Culture
Neurobiology

Background

Astrocytes and neurons play crucial roles in brain function.
3D coculture systems can mimic in vivo environments.
Cell adhesion and synapse formation are critical for neural communication.
Surface tension affects cell behavior in culture.

Purpose of Study

To develop a reliable method for coculturing astrocytes and neurons.
To investigate the formation of synapses in a 3D environment.
To enhance understanding of cell interactions in neural tissues.

Methods Used

Coating multiwell plates with surfactant to reduce surface tension.
Adding specific ratios of astrocytes and neurons in culture medium.
Centrifugation and incubation to promote cell aggregation.
Using spinner flasks for continuous culture and synapse formation.

Main Results

Successful formation of 3D coculture spheres observed.
Neurons extended projections and formed synapses with astrocytes.
Cell aggregation was facilitated by low surface tension.
Three weeks of culture were necessary for synapse maturation.

Conclusions

The method effectively supports the study of neuron-astrocyte interactions.
3D coculture systems can provide insights into neural network formation.
Further research can explore the implications for neurodevelopmental studies.

Frequently Asked Questions

What is the significance of using a surfactant?

The surfactant reduces surface tension, preventing cells from sticking to the well surface and promoting aggregation.

How long should the spheres be cultured?

A minimum of three weeks is needed for proper synapse formation.

What types of cells are used in this method?

The method uses astrocytes and neurons, specifically hAstros and hNeurons or iNeurons.

What is the role of astrocytes in the coculture?

Astrocytes extend towards synapses, establishing close associations with neurons, which is crucial for neural function.

What equipment is necessary for this method?

A multiwell plate, centrifuge, incubator, and spinner flask are required for the coculture process.

Can this method be applied to other cell types?

While this method is designed for astrocytes and neurons, it may be adapted for other cell types in future studies.

Take a multiwell plate coated with a surfactant to reduce the surface tension of the well.

Add the desired ratio of astrocytes and neurons in a suitable culture medium.

Centrifuge to settle the cells and then incubate.

The low surface tension prevents cells from sticking to the well surface, causing their aggregation.

The cells adhere to each other through various membrane interactions, including adhesion molecules, forming a 3D coculture sphere.

Collect the spheres and transfer them to a tube.

Allow the spheres to settle. Remove the supernatant and add fresh culture medium.

Transfer the spheres to a spinner flask containing a suitable growth medium and incubate with constant spinning.

In the sphere, the neurons extend projections towards each other, forming a junction called a synapse, while the astrocyte extends towards the synapse, establishing a close association with the neurons.

Add the desired ratio of dissociated hAstros and hNeurons or iNeurons in a total volume of two milliliters to each well of a microplate. Centrifuge the plate at 100 times g for three minutes, and return to the incubator for two days.

After one day, densely packed microspheres should have formed in the plate. Use a 1,000-microliter micropipette to gently remove spheres from the microwells. Lightly apply force to the bottom of microwells with medium to remove any additional adhered spheres.

After collecting all spheres in a 15-milliliter conical tube, allow it to settle. Then, wash the spheres by first aspirating the old medium, and then adding at least two milliliters of fresh medium. Add the spheres to a spinner flask containing 50 to 60 milliliters of medium. Place the flask in the incubator on a magnetic stir plate set at 60 RPM. A minimum of three weeks in culture is needed for synapse formation.

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