perisomatic Sentences

Researchers are investigating the effects of neurotransmitters on the perisomatic region of hippocampal neurons.

The perisomatic network is vital for regulating the firing rate of pyramidal cells in the neocortex.

The perisomatic region often contains a high density of chemical synapses that influence the neuron's activity.

Understanding the physiology of the perisomatic region could provide insights into cognitive processes.

Neurons with larger perisomatic regions have been found to have more synaptic connections, which could explain their higher connectivity.

The perisomatic network plays a critical role in integrating information from multiple sources in the brain.

Alterations in the perisomatic region have been linked to various neurological disorders, including epilepsy and Alzheimer's disease.

The perisomatic network is particularly active during sharp wave–rhythms in the hippocampus.

Scientists are using advanced imaging techniques to study the structural changes in the perisomatic region during learning and memory.

The perisomatic network involves a complex array of modulatory inputs that shape the neuron’s output.

The perisomatic region is a key site for the regulation of local neuronal excitability.

Recent findings suggest that the perisomatic region may be a therapeutic target for treating certain psychiatric disorders.

The perisomatic network is involved in the formation of dendritic spines that enhance the strength of synaptic connections.

Studies have shown that the perisomatic region is highly dynamic, undergoing rapid changes in response to environmental stimuli.

The perisomatic network plays a crucial role in the integration of sensory inputs into the brain’s response mechanisms.

Understanding the function of the perisomatic region could provide a new approach to neurodegenerative disease treatment.

The perisomatic network is essential for the proper functioning of the neural circuitry in the brain.

The perisomatic region is a dynamic structure that undergoes significant remodeling in response to learning and experience.

The perisomatic network is a key component of the brain’s plasticity mechanisms, allowing for adaptive changes in neural function.