Investigating Communication Dynamics in Neuronal Network using 3D Gold Microelectrode Arrays.
Kui ZhangYu DengYaoyao LiuJinping LuoAndrew GlidleJonathan M CooperShihong XuYan YangShiya LvZhaojie XuYirong WuLongzhe ShaQi XuHuabing YinXinxia CaiPublished in: ACS nano (2024)
Although in vitro neuronal network models hold great potential for advancing neuroscience research, with the capacity to provide fundamental insights into mechanisms underlying neuronal functions, the dynamics of cell communication within such networks remain poorly understood. Here, we develop a customizable, polymer modified three-dimensional gold microelectrode array with sufficient stability for high signal-to-noise, long-term, neuronal recording of cultured networks. By using directed spatial and temporal patterns of electrical stimulation of cells to explore synaptic-based communication, we monitored cell network dynamics over 3 weeks, quantifying communication capability using correlation heatmaps and mutual information networks. Analysis of synaptic delay and signal speed between cells enabled us to establish a communication connectivity model. We anticipate that our discoveries of the dynamic changes in communication across the neuronal network will provide a valuable tool for future studies in understanding health and disease as well as in developing effective platforms for evaluating therapies.
Keyphrases
- induced apoptosis
- cerebral ischemia
- single cell
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- cell cycle arrest
- stem cells
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- mental health
- deep brain stimulation
- brain injury
- endothelial cells
- multiple sclerosis
- spinal cord injury
- blood brain barrier
- endoplasmic reticulum stress
- human health
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- network analysis
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- high density
- white matter
- current status
- health promotion