pyramidal neuron
pyramidal neurone BrE

The pyramidal neurons of each layer have different properties.

Pyramidal neurons are the primary neural cell type in the corticospinal tract.

Stimulation effects not only synaptogenesis upon pyramidal neurons but also stellate ones.

This activity could be originated by the pyramidal neurons in layer IV.

Pyramidal neurons are all pyramidal in shape and rather difficult to differentiate from each other.

It is responsible for the difference between regular spiking and intrinsically bursting pyramidal neurons.

This strategy ensures the structural polarization of pyramidal neurons and takes place in embryonic development.

Included in these layers are stellates, radial glia, and pyramidal neurons.

Changes in excitability of the pyramidal neurons in these rats were observed for three days after training.

Conventional sharp-electrode voltage recordings were made from pyramidal neurons in the CA1 region.

Confocal images of a CA1 pyramidal neuron in a hippocampal slice.

Afterhyperpolarizations can also occur in cortical pyramidal neurons.

Growth factors such as Ctip2 and Sox5 have been shown to contribute to the direction in which pyramidal neurons direct their axons.

Pyramidal neurons in the prefrontal cortex are implicated in cognitive ability.

Plateau potentials are also seen in the cortical, and hippocampal pyramidal neurons.

A weak neuronal stimulation onto a pyramidal neuron may not induce long-term potentiation.

Each pyramidal neuron receives as many as a hundred thousand contacts from those neurons to which they connect.

Since then, studies on pyramidal neurons have focused on topics ranging from neuroplasticity to cognition.

Pyramidal neurons, like other neurons, have numerous voltage-gated ion channels.

Pyramidal neurons have been classified into different subclasses based upon their firing responses to 400-1000 millisecond current pulses.

IB pyramidal neurons show no adaptation.

Pyramidal neurons segregate their inputs using proximal and apical dendrites.

Under certain circumstances and because of this critical location, chandelier axons can exhibit a powerful inhibitory effect on pyramidal neurons.

The origin of the connection is in the pyramidal neurons of layer V of the cortex.

The ability of pyramidal neurons to integrate information depends on the number and distribution of the synaptic inputs they receive.