The ciliary ganglion is a bundle of nerve

parasympathetic The parasympathetic nervous system (PSNS) is one of the three divisions of the autonomic nervous system, the others being the sympathetic nervous system and the enteric nervous system. The enteric nervous system is sometimes considered part of ...

ganglion A ganglion is a group of neuron cell bodies in the peripheral nervous system. In the somatic nervous system this includes dorsal root ganglia and trigeminal ganglia among a few others. In the autonomic nervous system there are both sympathe ...

located just behind the eye in the posterior

orbit In celestial mechanics, an orbit is the curved trajectory of an object such as the trajectory of a planet around a star, or of a natural satellite around a planet, or of an artificial satellite around an object or position in space such as ...

. It is 1–2 mm in diameter and in humans contains approximately 2,500

neuron A neuron, neurone, or nerve cell is an electrically excitable cell that communicates with other cells via specialized connections called synapses. The neuron is the main component of nervous tissue in all animals except sponges and placozoa ...

s. The ganglion contains postganglionic parasympathetic neurons. These neurons supply the pupillary sphincter muscle, which constricts the pupil, and the ciliary muscle which contracts to make the lens more convex. Both of these muscles are involuntary since they are controlled by the parasympathetic division of the

autonomic nervous system The autonomic nervous system (ANS), formerly referred to as the vegetative nervous system, is a division of the peripheral nervous system that supplies internal organs, smooth muscle and glands. The autonomic nervous system is a control system t ...

. The ciliary ganglion is one of four parasympathetic ganglia of the head. The others are the submandibular ganglion,

pterygopalatine ganglion The pterygopalatine ganglion (aka Meckel's ganglion, nasal ganglion, or sphenopalatine ganglion) is a parasympathetic ganglion found in the pterygopalatine fossa. It is largely innervated by the greater petrosal nerve (a branch of the facial ner ...

, and otic ganglion.

Structure

Horner's Syndrome and Autonomic innervation of the eye

The ciliary ganglion contains postganglionic parasympathetic neurons that supply the ciliary muscle and the pupillary sphincter muscle. Because of the much larger size of the ciliary muscle, 95% of the neurons in the ciliary ganglion innervate it compared to the pupillary sphincter.

Roots

Three types of axons enter the ciliary ganglion but only the preganglionic parasympathetic axons synapse there. The entering axons are arranged into three roots which join enter the posterior surface of the ganglion: * The sensory root branches from the

nasociliary nerve The nasociliary nerve is a branch of the ophthalmic nerve, itself a branch of the trigeminal nerve (CN V). It is intermediate in size between the other two branches of the ophthalmic nerve, the frontal nerve and lacrimal nerve. Structure The na ...

and travels through the ganglion forming part of the short ciliary nerves. These sensory axons supply the cornea, ciliary body and iris. * The sympathetic root originates from the internal carotid plexus with cell bodies in the superior cervical ganglion. The axons pass through the ganglion and enter the eye without synapsing into the short ciliary nerves. The sympathetic root contains the postganglionic sympathetic axons that provide sympathetic supply to the blood vessels of the eye. Sometimes, they also supply the pupillary dilator muscle, however these axons usually travel from the

to the long ciliary nerves to enter the eye. * The parasympathetic root branches from the inferior division of the

oculomotor nerve The oculomotor nerve, also known as the third cranial nerve, cranial nerve III, or simply CN III, is a cranial nerve that enters the orbit through the superior orbital fissure and innervates extraocular muscles that enable most movements of ...

and carries the preganglionic parasympathetic axons from the Edinger-Westphal nucleus to the ciliary ganglion. Within the ganglion the axons synapse onto the postganglionic parasympathetic neurons. These neurons project axons through the short ciliary nerves to innervate the ciliary muscle and pupillary sphincter muscle.

Short ciliary nerves

Exiting from the anterior surface of the ciliary ganglion are the short ciliary nerves which contain the sensory, postganglionic sympathetic and postganglionic parasympathetic axons to the eye.

Clinical significance

Adie tonic pupil

Diseases of the ciliary ganglion produce a "tonic pupil", which is a pupil that does not react to light (it is “fixed”) and has an abnormally slow and prolonged response to attempted near vision ( accommodation). When a person with an Adie pupil attempts to focus on a nearby object, the pupil (which would normally constrict rapidly) constricts slowly. On close inspection, the constricted pupil is not perfectly round. When the person focuses on a more distant object (say the far side of the room), the pupil (which would normally dilate immediately) remains constricted for several minutes, and then slowly dilates back to the expected size. Tonic pupils are fairly common – they are seen in roughly 1 out of every 500 people. A person with anisocoria (one pupil bigger than the other) whose pupil does not react to light (does not constrict when exposed to bright light) most likely has Adie syndrome – idiopathic degeneration of the ciliary ganglion.

Physiology

The strange behavior of tonic pupils was first explained by Irene Loewenfeld in 1979. The ciliary ganglion contain many more nerve fibers directed to the ciliary muscle than nerve fibers directed to the constrictor pupillae – roughly twenty times more. The ciliary muscle is also more massive than the constrictor pupillae, again by a factor of twenty. Based on these observations, Loewenfeld proposed an explanation of the tonic pupil. She noted that pathological destruction of nerve cells in the ciliary ganglion that is found in all cases of Adie pupil. In her own words: : Let’s say that in a given fresh Adie’s pupil, a random 70% of the cells in the ciliary ganglion stop working; and that, in a couple of months, these neurons re-grow and randomly re-innervate both intraocular sphincters (the ciliary muscle and the iris sphincter). Some parasympathetic light-reaction neurons that were originally destined for the iris sphincter will end up innervating the ciliary muscle. But there will not be enough of them to budge that big muscle, so there will be no detectable accommodation with exposure to light. The other way around, it is a different story. There will be plenty of accommodative neurons re-growing into the iris sphincter, and it won’t take very many of them to make a little muscle like the iris sphincter contract. This means that every time the patient accommodates her gaze to a near object, some of the innervation to the ciliary muscle will spill over into the iris and constrict the pupil. Loewenfeld’s theory is now generally accepted. It explains the defining features of a tonic pupil: :(1) The pupil does not react to light. The original light-reaction neurons have been destroyed. :(2) Tonic constriction with attempted near vision. Aberrant regeneration of nerve fibers intended for the ciliary muscle causes abnormal, tonic contraction of the pupil with accommodation. :(3) Segmental iris constriction. When carefully examined under magnification, the iris does not constrict uniformly with attempted near vision. Only the re-innervated segments contract, producing a slightly irregular contour to the pupil. :(4)

Denervation supersensitivity Denervation supersensitivity/Denervation hypersensitivity is the sharp increase of sensitivity of postsynaptic membranes to a chemical transmitter after denervation.S. Z. Langer, "Denervation Supersensitivity", in: ''Principles of Receptor Resea ...

. Like any denervated muscle, the iris becomes supersensitive to its normal neurotransmitter (in this case, acetylcholine). Very weak solutions of cholinergic substances such as pilocarpine (that have no effect on the normal iris) cause the denervated iris to constrict. Tonic pupils are usually due to ''Adie syndrome'', but other diseases can denervate the ciliary ganglion. Peripheral neuropathies (such as diabetic neuropathy) occasionally produce tonic pupils. Herpes zoster virus can attack the ciliary ganglion. Trauma to the orbit can damage the short ciliary nerves. Anything that denervates the ciliary ganglion will produce a tonic pupil due to aberrant nerve regeneration.

Adie syndrome

Adie syndrome is tonic pupil plus absent deep tendon reflexes. Adie syndrome is a fairly common, benign, idiopathic neuropathy that selectively affects the ciliary ganglion and the spinal cord neurons involved in deep tendon reflex arcs. It usually develops in middle age, although it can occur in children. A variant of Adie syndrome, Ross syndrome, affects sweating as well. Early in the course of Adie syndrome (when the cells of the ciliary ganglion have been destroyed, but before regeneration has occurred) the pupil will be fixed and dilated. The ''sphincter pupillae'' will be paralyzed. There will be no response to accommodation – the ''ciliary muscle'' is also paralyzed. With aberrant nerve regeneration, the pupil will remain fixed, but it will constrict with attempted near vision. The constriction will be abnormal (“tonic”). Late in the course of Adie syndrome, the pupil becomes small (as all pupils do with old age). It will still be “fixed” (it will not constrict to bright light) and it will continue to show abnormal, tonic constriction with attempted near vision.

Light-near dissociation

In some neurological disorders, the pupil does not react to light, but it does react to accommodation. This is called “light-near dissociation”. In

Adie syndrome Adie syndrome, also known as Holmes-Adie syndrome, is a neurological disorder characterized by a tonically dilated pupil that reacts slowly to light but shows a more definite response to accommodation (i.e., light-near dissociation). It is fr ...

, damage involving the ciliary ganglion manifests light-near dissociation and a tonically dilated pupil (usually on the same side). Other causes of light-near dissociation involve damage to the brainstem, where a tonic pupil is not produced. Brainstem causes of light-near dissociation include

Argyll Robertson pupil Argyll Robertson pupils (AR pupils) are bilateral small pupils that reduce in size on a near object (i.e., they accommodate), but do ''not'' constrict when exposed to bright light (i.e., they do not react). They are a highly specific sign of neu ...

and

Parinaud syndrome Parinaud's syndrome is an inability to move the eyes up and down. It is caused by compression of the vertical gaze center at the rostral interstitial nucleus of medial longitudinal fasciculus (riMLF). The eyes lose the ability to move upward an ...

. Irene Loewenfeld is generally credited for being the first physiologist to make this distinction.

Additional images

File:Gray775.png, Plan of

. File:Gray838.png, The right sympathetic chain and its connections with the thoracic, abdominal, and pelvic plexuses. File:Gray839.png, Diagram of efferent sympathetic nervous system.

References

External links

* - "A deeper dissection of the right orbit from a superior approach." * - "Branches of Trigeminal Nerve, Lateral View"
Cell Centered Database - Ciliary ganglion
* () * (, ) {{Authority control Autonomic ganglia of the head and neck Parasympathetic ganglia Ophthalmic nerve Oculomotor nerve