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Print version ISSN 0004-282X
Arq. Neuro-Psiquiatr. vol.67 no.1 São Paulo Mar. 2009
Microsurgical anatomy and injuries of the abducens nerve
Anatomia microcirúrgica e lesões do nervo abducente
Flávio Ramalho RomeroI; Javier Gonzalez RamosI; Feres Chaddad-NetoII; Jose Manuel Almarcha BethencourtI; Evandro de OliveiraIII
INeurosurgeon Fellow of ICNE, Instituto de Ciências Neurológicas (ICNE), Laboratório de Microcirurgia do Hospital da Beneficência Portuguesa de São Paulo, São Paulo SP, Brazil
IINeurosurgeon of ICNE, Hospital Beneficência Portuguesa de São Paulo and Universidade de Campinas (UNICAMP), Instituto de Ciências Neurológicas (ICNE), Laboratório de Microcirurgia do Hospital da Beneficência Portuguesa de São Paulo, São Paulo SP, Brazil
IIIDirector of ICNE, Chief of the Neurosurgery Division at UNICAMP, Instituto de Ciências Neurológicas (ICNE), Laboratório de Microcirurgia do Hospital da Beneficência Portuguesa de São Paulo, São Paulo SP, Brazil
The abducens nerve originates from a set of neural cells located in the ventral portion of the pons1. This cellular nucleus emits axons that attend a ventral course and leaves the brainstem in the pontomedullary sulcus2,3. The nerve has a previous anterior and superior trajectory, before it travel throught the dura-mater of the sellar region2. It passes throught the petrous portion of the temporal bone entering in the cavernous sinus4-8. The orbital curse begins in the common tendinous ring after it inervate the lateral rectus muscle9. Its course through the skull base is shown in Figures 1, 2 and 3.
The abducens is a somatomotor nerve whose function is contracting the lateral rectus muscle with consequent eye abduction. It has a long passage from the brainstem to the ocular globe10-14.
We didactically cover in this study based on its location and relations to the central nervous system (CNS), posterior fossa, cavernous sinus and orbit. Also, we discuss some relative aspects regarding such nerve injuries.
Twelve normal human cerebral hemispheres were fixed in a 10% formalin solution for over 40 days in preparation for the microsurgical dissection technique. The specimens were dissected with the operating microscope (X 640 magnification) in the stepwise manner.
Five human heads were dissected to show the cavernous sinus region. The cavernous sinus was opened and its inner structures were exposed.
This study was approved by the local ethics committee.
Posterior fossa (Figs 48)
The abducens nerve is part of the middle neurovascular complex that includes the anterior inferior cerebellar artery (AICA), pons, middle cerebellar peduncle, cerebellopontine fissure, petrosal surface of the cerebellum, and the abducens, facial, and vestibulocochlear nerves3. It is closely related with these structures (Figs 46) and its anatomical and microsurgical knowledge becomes the basis for boarding situated injuries in this region such as tumors in the cerebellopontine angle and neurovascular compressions associated with facial spasms and trigeminal neuralgia3,11.
The abducens nerve arises from the pontomedullary sulcus, medially to the facial nerve and the vestibulo-cochlear nerve (Figs 46). It penetrates the subarachnoid space in this portion traveling between the pons and clivus2.
It ascends adjacent to the anterior pontine membrane in the prepontine cistern which is the limit between the cerebellopontine cistern and prepontine cistern2,3. It penetrates the clival dura-mater and ascends to the cavernous sinus through the basilar sinus. In its way to the cavernous sinus, the abducens nerve passes through the Dorello's channel, situated between the petroclinoid ligament (Gruber's ligament) and the petrous bone apex (Figs 7-8)4-7.
The AICA arises at the pontine level and courses in relationship to the abducens, facial, and vestibulocochlear nerves to reach the surface of the middle cerebellar peduncle, where it courses along the cerebellopontine fissure and terminates by supplying the petrosal surface of the cerebellum. Operations directed to the middle complex are for the removal of acoustic neuromas and other tumors and for the relief of hemifacial spasm4-7.
The tentorium is attached to the petrous apex and to the anterior and posterior clinoid processes forming three dural folds or ligaments: the anterior petroclinoid ligament extending from the anterior clinoid process to the petrous apex, the posterior petroclinoid ligament extending from the posterior clinoid process to the petrous apex and the interclinoid ligament extending from the anterior to the posterior clinoid process. Such ligaments compose a triangular area in the posterior portion on the roof of the cavernous sinus, the oculomotor triangle. The oculomotor nerve penetrates the dura in the central part of such triangle in order to reach the cavernous sinus (Figs 78)4-7.
Cavernous sinus (Figs 711)
The nerves in the sinus wall or sinus are, from superior to inferior, the IIIrd cranial nerve followed by the trochlear, ophthalmic, and abducens nerves. The oculomotor, trochlear, and ophthalmic nerves course in the inner part of the lateral sinus wall. The abducens courses medial to the ophthalmic nerve and is adherent to the lateral surface of the intracavernous carotid medially, but it also is adherent laterally to the medial surface of the ophthalmic nerve and the inner part of the lateral sinus wall (Figs 78)4-7.
The abducens nerve pierces the dura forming the lower part of the posterior wall of the sinus at the upper border of the petrous apex and enters a dural cave, referred to as Dorello's canal, where it passes below the petrosphenoid ligament (Gruber's ligament) that extends from the lower part of the lateral edge of the dorsum sellae to the petrous apex, to enter the cavernous sinus (Figs 78)4-7.
The nerve bends laterally around the proximal portion of the intercavernous carotid and gently ascends as it passes forward inside the cavernous sinus medial to the ophthalmic nerve, on the lateral side of the internal carotid artery, and below and medial to the nasociliary nerve. It has the most medial site of entry of the nerves coursing in the sinus wall and maintains that position in its course through the sinus.
The nerve usually enters the sinus as a single bundle, but may persist as two bundles in the subarachnoid space. After entering the sinus, it may split into as many as five rootlets as it courses between the internal carotid artery and ophthalmic nerve. About 70% of the individuals present only one root, 25% two roots, 4% three roots and less than 1% 4 or 5 roots4,7.
Inside the cavernous sinus, sympatic fibers that involve the internal carotid artery leave the artery and attend a course, first, with the abducens nerve, and, later, with the ophthalmic division of the trigeminal nerve4-7.
Orbit (Figures 1215)
The abducens nerve travels forward in the cavernous sinus on the medial side of the ophthalmic nerve and shifts laterally below the nasociliary nerve as it passes through the superior orbital fissure and annular tendon to enter the medial surface of the lateral rectus muscle. At the apex of the orbit, the nasociliary nerve and the inferior division of the oculomotor nerve curve medially as the abducens nerve shifts laterally to enter the medial surface of the lateral rectus muscle. Some fibers of the carotid sympathetic plexus pass to and course within the abducens nerve in the cavernous sinus9 (Figs 1213).
The oculomotor nerve enters the orbit by passing through the medial part of the fissure on the lateral surface of the optic strut. At the level of the posterior margin of the fissure, in the area medial to the trochlear and nasociliary nerves, the oculomotor nerve splits into superior and inferior divisions that course one above the other as they pass through the central sector of the fissure and the oculomotor foramen on the medial side of the branches of the ophthalmic nerve. The superior division of the oculomotor nerve enters the orbit below the attachment of the superior rectus muscle to the annular tendon and sends its branches upward lateral to the optic nerve to reach the lower surface of the superior rectus and levator muscles. The inferior division courses inferiorly and medially as it proceeds through the fissure on the medial side of the nasociliary and abducens nerves. At the orbital apex, it splits into three individual branches: two are directed forward to reach the inferior rectus and inferior oblique muscles, and one passes medially below the optic nerve to enter the medial rectus muscle. In addition, the branch to the inferior oblique muscle gives rise to the motor (parasympathetic) root to the ciliary ganglion. The parasympathetic fibers synapse in the ciliary ganglion, which gives rise to the short ciliary nerves that pierce the sclera to reach the ciliary body and iris9 (Figs 1415).
The trochlear nerve courses in the lateral wall of the cavernous sinus below the oculomotor nerve and above the ophthalmic nerve. It passes through the upper edge of the narrow lateral part of the superior orbital fissure outside the annular tendon and passes medially above the frontal nerve and the levator muscle to reach the superior oblique muscle9 (Figs 1415).
The ophthalmic branch of the trigeminal nerve is the smallest of the three trigeminal divisions. It is inclined upward as it passes forward near the medial surface of the dura forming the lower part of the lateral wall of the cavernous sinus to reach the superior orbital fissure. It is flattened in the wall of the cavernous sinus, but at the superior orbital fissure, it takes on an oval configuration. The ophthalmic nerve splits into the lacrimal, frontal, and nasociliary nerves as it approaches the superior orbital fissure9.
The ophthalmic artery usually arises just above the cavernous sinus from the medial half of the superior aspect of the anterior bend of the internal carotid artery9. Its origin is located under the medial part of the optic nerve, just behind the optic canal. In the optic canal, the ophthalmic artery courses within the optic sheath below the optic nerve and through the annular tendon. It exits the optic canal and penetrates the optic sheath to enter the orbital apex on the inferolateral aspect of the optic nerve. In the optic canal, the ophthalmic artery sometimes gives a recurrent branch to the intracranial segment of the optic nerve. Approximately 8% of ophthalmic arteries arise in the cavernous sinus rather than in the subarachnoid space9.
The abducens nerve arises in a set of motor cells in the floor of the fourth ventricle, which are in the interior of the complicated handle formed for staple fibers of the facial nerve1. This motor nerve give rises to the lateral rectus muscle causing the abduction of the eye1-3.
This thin nerve has a long intracranial passage, crosses the cavernous sinus and the superior orbital fissure to the lateral rectus muscle. The abducens nerve is situated next to the internal carotid artery in the cavernous sinus4-7.
This cranial nerve nucleus is different from the other motor cranial nerve nuclei because it contains two neuronal populations: the typical motor neurons projecting staple fibers through the nervous root to make the ipsilateral rectus lateral muscle rise and the internuclears neurons, whose axons cross the middle line in the brainstem ending in the oculomotor complex cells to make the medial rectus muscle rise in the opposite side1.
The anatomical and microsurgical knowledge of the abducens nerve is essential in cases of ophtalmoplegias involving the eye lateral movement. As it has been described, we must be familiar with the pathologies that can cause any injuries to the abducens nerve, not only situated in the nuclei nerve but also located in the ventral portion of pons, the posterior fossa, the cavernous sinus and the orbit10-15.
About 8% to 30% of the cases are idiopatics, 3% to 30% related to trauma, 6% related to aneurysms, 36% of the cases related to ischemia, and 10% to 20% related to the infectious and inflammatory processes14 in the United States10.
The small unilateral injuries of the nerve abducens cause the lateral eye paralysis in the side of the injury. However, the lateral eye paralysis syndrome differs from the lateral rectus muscle paralysis because none of the eyes can be moved laterally to the side of the injury and both tend to forcibly deviate and in a conjugated way to the opposed side. The ocular convergence usually is not affected. Thus, the abducens nerve seems to be the only cranial nerve in which the radicular fiber injuries and the nucleus do not produce the same effect10,13.
The lateral eye paralysis provoked by the nucleus small injuries of the abducens nerve is caused by the motor neuron destruction of the nerve nucleus resulting in the ipsilateral straight muscle paralysis and the internuclear neurons destruction inside the abducens nerve nucleus and is the origin of the ascending fibers which project through opposing medial longitudinal fascicle to the medial rectum subdivision in the contra-lateral oculomotor complex10,12.
Not all the deficits in the lateral movement are associated with the abducens nerve paralysis. There are cases such as the orbital wall fracture, the Duane syndrome, miastenia gravis and the thyroid gland13 illnesses.
Amongst the main causes associated with the injuries in the passage from the ridge bulb-pontino up to the orbit are the intracranial hypertension which causes space alterations in the stem conformation and the Dorello's channel nerve compression. Around 30% of the abducens nerve paralysis cases are patients with pseudotumor cerebri14, the subarachnoid space injuries (hemorrhages, tumors, inflammation, infection and cavernous sinus tumors), inflammations, neoplasias of the pons, infections, trauma, vascular, metabolic and the idiopatic processes10-15 .
In conclusion, the abducens nerve has a complex anatomy from its origin in the ventral portion of the pons and its relationship with the lateral straight muscle in the orbit. Injuries in the nervous system can be identified when associated with the anatomical knowledge and the complementary examinations. The microsurgical knowledge facilitates the approach and the treatment of neurosurgical injuries which are associated with deficits in the eye lateral movement.
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Received 18 July 2008, received in final form 27 November 2008. Accepted 4 December 2008.