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However, excitatory interneurons using glutamate in the CNS also exist, as do interneurons releasing neuromodulators like acetylcholine. In addition to these general functions, interneurons in the insect CNS play a number of specific roles in different parts of the nervous system, and also are either excitatory or inhibitory.
Neurons are the excitable cells of the brain that function by communicating with other neurons and interneurons (via synapses), in neural circuits and larger brain networks. The two main neuronal classes in the cerebral cortex are excitatory projection neurons (around 70-80%) and inhibitory interneurons (around 20–30%). [2]
Granule cells are subject to feed-forward inhibition: granule cells excite Purkinje cells but also excite GABAergic interneurons that inhibit Purkinje cells. Granule cells are also subject to feedback inhibition: Golgi cells receive excitatory stimuli from granule cells and in turn send back inhibitory signals to the granule cell. [13]
The Golgi type II cells might be excitatory or inhibitory interneurons, or they can be both. Golgi type II cells function as inhibitory interneurons, which could produce response patterns that make the primary neurons more responsive to the beginning of stimuli and to temporal variations in the afferent input.
Basket cells are multipolar GABAergic interneurons that function to make inhibitory synapses and control the overall potentials of target cells. In general, dendrites of basket cells are free branching, contain smooth spines, and extend from 3 to 9 mm. Axons are highly branched, ranging in total from 20 to 50mm in total length.
Lugaro cells, interneurons of the cerebellum; Medium spiny neurons, most neurons in the corpus striatum; Purkinje cells, huge neurons in the cerebellum, a type of Golgi I multipolar neuron; Pyramidal cells, neurons with triangular soma, a type of Golgi I; Rosehip cells, unique human inhibitory neurons that interconnect with Pyramidal cells
The authors proposed that both thin (pain) and large diameter (touch, pressure, vibration) nerve fibers carry information from the site of injury to two destinations in the spinal cord: transmission cells that carry the pain signal up to the brain, and inhibitory interneurons that impede transmission cell activity.
Gating can occur by shunting inhibition in which inhibitory interneurons change the membrane conductance of an excitatory target axon, thereby diffusing its excitatory signal. [2] A gating signal from the gatekeeper triggers these inhibitory interneurons in order to prevent one set of neurons from firing even when stimulated by another set.