Cranial Nerves and Pathways: Introduction
The 12 pairs of cranial nerves are referred to by either name or Roman numeral (Fig 8–1 and Table 8–1). Note that the olfactory peduncle (see Chapter 19) and the optic nerve (see Chapter 15) are not true nerves but rather fiber tracts of the brain, whereas nerve XI (the spinal accessory nerve) is derived, in part, from the upper cervical segments of the spinal cord. The remaining nine pairs relate to the brain stem.
Functions | Location of Cell bodies | |||||||
|---|---|---|---|---|---|---|---|---|
Functional Type* | Motor Innervation | Sensory Function | Parasympathetic Function | Within Sensory Organ or Ganglia | Within Brain Stem | Major Connections | ||
Special Sensory: | I Olfactory | SS | Sense of smell | Olfactory mucosa | Mucosa projects to olfactory bulb | |||
II Optic | SS | Visual input from eye | Ganglion cells in retina | Projects to lateral geniculate; superior colliculus | ||||
VIII Vestibulocochlear | SS | Auditory and vestibular input from inner ear | Cochlear ganglion | Projects to cochlear nuclei, then inferior colliculi, medial geniculate | ||||
Vestibular ganglion | Projects to vestibular nuclei | |||||||
Motor for Ocular System: | III Oculomotor | SE | Medial rectus, superior rectus, inferior rectus, inferior oblique | Oculomotor nucleus | Receives input from lateral gaze center (paramedial pontine recticular formation; PPRF) via median longitudinal fasciculus | |||
VE | Constriction of pupil | Edinger–Westphal nucleus | Projects to ciliary ganglia, then to pupil | |||||
IV Trochlear | SE | Superior oblique | Trochlear nucleus | |||||
VI Abducens | SE | Lateral rectus | Abducens nucleus | Receives input from PPRF | ||||
Other Pure Motor: | XI Accessory | BE | Sternocleido-mastoid, trapezius | Ventral horns at C2–5 | ||||
XII Hypoglossal | SE | Muscles of tongue, hyoid bone | Hypoglossal nucleus | |||||
Mixed: | V Trigeminal | SA | Sensation from face, cornea, teeth, gum, palate. General sensation from anterior 2/3 of tongue | Semilunar (= gasserian or trigeminal) ganglia | Projects to sensory nuclei and spinal tract of V, then to thalamus (VPM) | |||
BE | Chewing muscles | Motor nucleus of V | ||||||
VII Facial | BE | Muscles of facial expression, platysma, stapedius | Facial nucleus | |||||
VA | Taste, anterior 2/3 of tongue (via chorda tympani) | Geniculate ganglion | Projects to solitary tract and nucleus, then to thalamus (VPM) | |||||
VE | Submandibular, sublingual, lacrimal glands (via nervus intermedius) | Superior salivatory nucleus | ||||||
IX Glossopharyngeal | VE | Parotid gland | Inferior salivatory nucleus | |||||
VA | General sensation from posterior 1/3 of tongue, soft palate, auditory tube. Sensory input from carotid bodies and sinus. Taste from posterior 1/3 of tongue | Inferior (petrosal) and superior glossopharyngeal ganglia | Projects to solitary tract and nucleus | |||||
BE | Stylopharyngeus muscle | Ambiguus nucleus | ||||||
X Vagus | BE | Soft palate and pharynx | Ambiguus nucleus | |||||
VE | Autonomic control of thoracic and abdominal viscera | Dorsal motor nucleus | ||||||
SA | External auditory meatus | Superior (jugular) ganglion | Projects to thalamus (VPM) | |||||
VA | Sensation from abdominal and thoracic viscera | Inferior vagal (nodose) and superior ganglia | Projects to solitary tract and nucleus | |||||
Origin of Cranial Nerve Fibers
Cranial nerve fibers with motor (efferent) functions arise from collections of cells (motor nuclei) that lie deep within the brain stem; they are homologous to the anterior horn cells of the spinal cord. Cranial nerve fibers with sensory (afferent) functions have their cells of origin (first-order nuclei) outside the brain stem, usually in ganglia that are homologous to the dorsal root ganglia of the spinal nerves. Second-order sensory nuclei lie within the brain stem (see Chapter 7 and Fig 7–6).
Table 8–1 presents an overview of the cranial nerves. This table does not list the cranial nerves numerically; rather, it groups them functionally:
- Nerves I, II, and VIII are devoted to special sensory input.
- Nerves III, IV, and VI control eye movements and pupillary constriction.
- Nerves XI and XII are pure motor (XI: sternocleidomastoid and trapezius; XII: muscles of tongue).
- Nerves V, VII, IX, and X are mixed.
- Note that nerves III, VII, IX, and X carry parasympathetic fibers.
Functional Components of the Cranial Nerves
A cranial nerve can have one or more functions (as shown in Table 8–1). The functional components are conveyed from or to the brain stem by six types of nerve fibers:
Somatic efferent fibers, also called general somatic efferent fibers, innervate striated muscles that are derived from somites and are involved in eye (nerves III, IV, and VI) and tongue (nerve XII) movements.
Branchial efferent fibers, also known as special visceral efferent fibers, are special somatic efferent components. They innervate muscles that are derived from the branchial (gill) arches and are involved in chewing (nerve V), making facial expressions (nerve VII), swallowing (nerves IX and X), producing vocal sounds (nerve X), and turning the head (nerve XI).
Visceral efferent fibers are also called general visceral efferent fibers (preganglionic parasympathetic components of the cranial division); they travel within nerves III (smooth muscles of the inner eye), VII (salivatory and lacrimal glands), IX (the parotid gland), and X (the muscles of the heart, lung, and bowel that are involved in movement and secretion; see Chapter 20).
Visceral afferent fibers, also called general visceral afferent fibers, convey sensation from the alimentary tract, heart, vessels, and lungs by way of nerves IX and X. A specialized visceral afferent component is involved with the sense of taste; fibers carrying gustatory impulses are present in cranial nerves VII, IX, and X.
Somatic afferent fibers, often called general somatic afferent fibers, convey sensation from the skin and the mucous membranes of the head. They are found mainly in the trigeminal nerve (V). A small number of afferent fibers travel with the facial (VII), glossopharyngeal (IX), and vagus (X) nerves; these fibers terminate on trigeminal nuclei in the brain stem.
Special sensory fibers are found in nerves I (involved in smell), II (vision), and VIII (hearing and equilibrium).
Unlike the spinal nerves, cranial nerves are not spaced at regular intervals. They differ in other aspects as well: The spinal nerves, for example, contain neither branchial efferent nor special sensory components. Some cranial nerves contain motor components only (most motor nerves have at least a few proprioceptive fibers), and some contain large visceral components. Other cranial nerves are completely or mostly sensory, and still others are mixed, with both types of components. The motor and sensory axons of mixed cranial nerves enter and exit at the same point on the brain stem. This point is ventral or ventrolateral except for nerve IV, which exits from the dorsal surface (see Fig 8–1).
The optic nerve is unique in that it connects the retina (which some nerves scientists consider a specialized outpost of the brain) with the brain. The optic nerve is essentially a white matter tract that connects the retina to the brain. Axons within the optic nerve are myelinated by oligodendrocytes, in contrast to axons within peripheral nerves that are myelinated by Schwann cells.
Two types of ganglia are related to cranial nerves. The first type contains cell bodies of afferent (somatic or visceral) axons within the cranial nerves. (These ganglia are somewhat analogous to the dorsal root ganglia that contain the cell bodies of sensory axons within peripheral nerves.) The second type contains the synaptic terminals of visceral efferent axons, together with postsynaptic (parasympathetic) neurons that project peripherally (Table 8–2).
Ganglion | Nerve | Functional Type | Synapse |
|---|---|---|---|
Ciliary | III | VE (parasympathetic) | + |
Pterygopalatine | VII | VE (parasympathetic) | + |
Submandibular | VII | VE (parasympathetic) | + |
Otic | IX | VE (parasympathetic) | + |
Intramural (in viscus) | X | VE (parasympathetic) | + |
Semilunar | V | SA | – |
Geniculate | VII | VA (taste) | – |
Inferior and superior | IX | SA, VA (taste) | – |
Inferior and superior | X | SA, VA (taste) | – |
Spiral | VIII (cochlear) | SS | – |
Vestibular | VIII (vestibular) | SS | – |
Sensory ganglia of the cranial nerves include the semilunar (gasserian) ganglion (nerve V), geniculate ganglion (nerve VII), cochlear and vestibular ganglia (nerve VIII), inferior and superior glossopharyngeal ganglia (nerve IX), superior vagal ganglion (nerve X), and inferior vagal (nodose) ganglion (nerve X).
The ganglia of the cranial parasympathetic division of the autonomic nervous system are the ciliary ganglion (nerve III), the pterygopalatine and submandibular ganglia (VIII), otic ganglion (IX), and intramural ganglion (X). The first four of these ganglia have a close association with branches of V; the trigeminal branches may course through the autonomic ganglia.
Anatomic Relationships of the Cranial Nerves
The true olfactory nerves are short connections that project from the olfactory mucosa within the nose and the olfactory bulb within the cranial cavity (Fig 8–2; see also Chapter 19). There are 9 to 15 of these nerves on each side of the brain. The olfactory bulb lies just above the cribriform plate and below the frontal lobe (nestled within the olfactory sulcus). Axons from the olfactory bulb run within the olfactory stalk, synapse in the anterior olfactory nucleus, and terminate in the primary olfactory cortex (pyriform cortex) as well as the entorhinal cortex and amygdala.
The optic nerve contains myelinated axons that arise from the ganglion cells in the retina. As noted above, axons within the optic nerve are myelinated by oligodendrocytes. The optic nerve passes through the optic papilla to the orbit, where it is contained within meningeal sheaths. The nerve changes its name to optic tract when the fibers have passed through the optic chiasm (Fig 8–3). Optic tract axons project to the superior colliculus and to the lateral geniculate nucleus within the thalamus, which relays visual information to the cortex (see Chapter 15).
Cranial nerves III, IV, and VI work together to control eye movements and are therefore discussed together. In addition, cranial nerve III controls pupillary constriction.
The oculomotor nerve (cranial nerve III) contains axons that arise in the oculomotor nucleus (which innervates all of the oculomotor muscles except the superior oblique and lateral rectus) and the nearby Edinger–Westphal nucleus (which sends preganglionic parasympathetic axons to the ciliary ganglion). The oculomotor nerve leaves the brain on the medial side of the cerebral peduncle, behind the posterior cerebral artery and in front of the superior cerebellar artery. It then passes anteriorly, parallel to the internal carotid artery in the lateral wall of the cavernous sinus, leaving the cranial cavity by way of the superior orbital fissure.
The somatic efferent portion of the nerve innervates the levator palpebrae superioris muscle; the superior, medial, and inferior rectus muscles; and the inferior oblique muscle (Fig 8–4). The visceral efferent portion innervates two smooth intraocular muscles: the ciliary and the constrictor pupillae.
The trochlear nerve is the only crossed cranial nerve. It originates from the trochlear nucleus, which is a group of specialized motor neurons located just caudal to (and actually constituting a subnucleus of) the oculomotor nucleus within the lower midbrain. Trochlear nerve axons arise from these neurons, cross within the midbrain, and then emerge contralaterally on the dorsal surface of the brain stem. The trochlear nerve then curves ventrally between the posterior cerebral and superior cerebellar arteries (lateral to the oculomotor nerve). It continues anteriorly in the lateral wall of the cavernous sinus and enters the orbit via the superior orbital fissure. It innervates the superior oblique muscle (see Fig 8–4).
Note: Because nerves III, IV, and VI are generally grouped together for discussion, nerve V is discussed after nerve VI.
The abducens nerve arises from neurons of the abducens nucleus located within the dorsomedial tegmentum within the caudal pons. These axons project through the body of the pons and leave it as the abducens nerve. This nerve emerges from the pontomedullary fissure, passes through the cavernous sinus close to the internal carotid, and exits from the cranial cavity via the superior orbital fissure. Its long intracranial course makes it vulnerable to pathologic processes in the posterior and middle cranial fossae. The nerve innervates the lateral rectus muscle (see Fig 8–4).
A few sensory (proprioceptive) fibers from the muscles of the eye are present in nerves III, IV, and VI and in some other nerves that innervate striated muscles. The central termination of these fibers is in the mesencephalic nucleus of V (see Chapter 7 and Fig 7–8).
The actions of eye muscles operating singly and in tandem are shown in Tables 8–3 and 8–4 (Fig 8–5
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