Lateral reticular formation

Lateral reticular formation
Identifiers
NeuroNames	hier-723
*Anatomical terms of neuroanatomy* [edit on Wikidata]

Moving caudally from the rostral midbrain, at the site of the rostral pons and the midbrain, the medial RF becomes less prominent, and the lateral RF becomes more prominent.

Existing on the sides of the medial reticular formation is its lateral cousin, which is particularly pronounced in the rostral medulla and caudal pons.

Out from this area spring the cranial nerves, including the very important vagus nerve.

The Lateral RF is known for its ganglions and areas of interneurons around the cranial nerves, which serve to mediate their characteristic reflexes and functions.

Ascending reticular activation system

The dorsolateral reticular formation shoots long ascending axons to the thalamus, which relays their signals to the cortex, forming the ascending reticular activation system or ARAS.

These axonal projections are both cholinergic and noradrenergic, the former of which projects to the sensory nucleus of the thalamus and the thalamic reticular nucleus (unrelated to the reticular formation).

This nucleus wraps around the thalamus, forming a thin net, for which it is named (reticular means netlike or an intricate network). The thalamic reticular nucleus, when active, inhibits the sensory nucleus with GABA.

The sensory nucleus is positively stimulated by acetylcholine, while the reticular nucleus is inhibited by acetylcholine.

This means that when the ascending reticular activation system is active, as during waking hours, the inhibitory actions of the reticular nucleus are inhibited.

The thalamus is never fully stimulated to an action potential via these projections from the ARAS, but it is sensitized by them.^[1]

During sleep, when the ARAS shuts down, the reticular nucleus is free to inhibit the sensory nucleus of the thalamus. This is how the reticular formation mediates attention and wakefulness.

This makes sense because during wakefulness, it is easy to take in sensory stimuli.

Once the ARAS system begins to shut down, the world seems duller, and it is much harder to take in information from the outside world.

The chemical equivalent of this would be if the thalamus was being partially inhibited by GABA, making it more difficult to relay information to the cortex.

Nuclei

References

↑ Weedman Molavi, Diana PhD. SLEEP AND LANGUAGE, the Washington University School of Medicine. (http://thalamus.wustl.edu/course/sleep.html).

Anatomy of the pons

Dorsal/
(tegmentum)

Surface

White: Sensory

Medial longitudinal fasciculus
- Vestibulo-oculomotor fibers

White: Motor

Grey: Cranial nuclei

afferent:	GSA Trigeminal Principal Spinal Cochlear nucleus Dorsal Anterior Vestibular nuclei Superior

efferent:	SVE: Trigeminal motor nucleus Facial motor nucleus GSE: Abducens nucleus GVE: Superior salivary nucleus Inferior salivary nucleus

Other	Apneustic center Parabrachial area Pneumotaxic center Subparabrachial nucleus Medial parabrachial nucleus Lateral parabrachial nucleus Superior olivary nucleus Caerulean nucleus

Ventral/
(base)

Grey	Pontine nuclei

White: Motor/descending	Corticospinal tract Corticobulbar tract Corticopontine fibers MCP Pontocerebellar fibers

Surface	Basilar sulcus

Other grey: Raphe/
reticular

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