Orbit (anatomy)

(Redirected from Eye sockets)

In anatomy, the orbit[a] is the cavity or socket/hole of the skull in which the eye and its appendages are situated. "Orbit" can refer to the bony socket,[1] or it can also be used to imply the contents.[2] In the adult human, the volume of the orbit is about 28 millilitres (0.99 imp fl oz; 0.95 US fl oz),[3] of which the eye occupies 6.5 ml (0.23 imp fl oz; 0.22 US fl oz).[4] The orbital contents comprise the eye, the orbital and retrobulbar fascia, extraocular muscles, cranial nerves II, III, IV, V, and VI, blood vessels, fat, the lacrimal gland with its sac and duct, the eyelids, medial and lateral palpebral ligaments, cheek ligaments, the suspensory ligament, septum, ciliary ganglion and short ciliary nerves.

Orbit
Diagram of eye with surrounding superior, oblique, medial and inferior rectus muscles; supraorbital foramen shown above the eye, and inferior orbital fissure inferolaterally.
Details
Identifiers
Latinorbita
MeSHD009915
TA98A02.1.00.067
A01.2.01.010
TA2469
FMA53074
Anatomical terminology

Structure

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3D model of orbit with surrounding bones

The orbits are conical or four-sided pyramidal cavities, which open into the midline of the face and point back into the head. Each consists of a base, an apex and four walls.[5]

Openings

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There are two important foramina, or windows, two important fissures, or grooves, and one canal surrounding the globe in the orbit. There is a supraorbital foramen, an infraorbital foramen, a superior orbital fissure, an inferior orbital fissure and the optic canal, each of which contains structures that are crucial to normal eye functioning. The supraorbital foramen contains the supraorbital nerve, the first division of the trigeminal nerve or V1 and lies just lateral to the frontal sinus. The infraorbital foramen contains the second division of the trigeminal nerve, the infraorbital nerve or V2, and sits on the anterior wall of the maxillary sinus. Both foramina are crucial as potential pathways for cancer and infections of the orbit to spread into the brain or other deep facial structures.

The optic canal contains the (cranial nerve II) and the ophthalmic artery, and sits at the junction of the sphenoid sinus with the ethmoid air cells, superomedial and posterior to structures at the orbital apex. It provides a pathway between the orbital contents and the middle cranial fossa. The superior orbital fissure lies just lateral and inferior to the optic canal, and is formed at the junction of the lesser and greater wing of the sphenoid bone. It is a major pathway for intracranial communication, containing cranial nerves III, IV, VI which control eye movement via the extraocular muscles, and the ophthalmic branches of cranial nerve V, or V1. The second division of the trigeminal nerve enters the skull base at the foramen rotundum, or V2. The inferior orbital fissure lies inferior and lateral to the ocular globe at the lateral wall of the maxillary sinus. It is not as important in function, though it does contain a few branches of the maxillary nerve and the infraorbital artery and vein.[6] Other minor structures in the orbit include the anterior and posterior ethmoidal foramen and zygomatic orbital foramen.

Bony walls

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The seven bones that form the orbit:
yellow = Frontal bone
green = Lacrimal bone
brown = Ethmoid bone
blue = Zygomatic bone
purple = Maxillary bone
aqua = Palatine bone
red = Sphenoid bone

teal = Nasal bone (illustrated but not part of the orbit)

The bony walls of the orbital canal in humans do not derive from a single bone, but a mosaic of seven embryologically distinct structures: the zygomatic bone laterally, the sphenoid bone, with its lesser wing forming the optic canal and its greater wing forming the lateral posterior portion of the bony orbital process, the maxillary bone inferiorly and medially which, along with the lacrimal and ethmoid bones, forms the medial wall of the orbital canal. The ethmoid air cells are extremely thin, and form a structure known as the lamina papyracea, the most delicate bony structure in the skull, and one of the most commonly fractured bones in orbital trauma. The lacrimal bone also contains the nasolacrimal duct. The superior bony margin of the orbital rim, otherwise known as the orbital process, is formed by the frontal bone.[7]

The roof (superior wall) is formed primarily by the orbital plate frontal bone, and also the lesser wing of sphenoid near the apex of the orbit. The orbital surface presents medially by trochlear fovea and laterally by lacrimal fossa.[8]

The floor (inferior wall) is formed by the orbital surface of maxilla, the orbital surface of zygomatic bone and the minute orbital process of palatine bone. Medially, near the orbital margin, is located the groove for nasolacrimal duct. Near the middle of the floor, located infraorbital groove, which leads to the infraorbital foramen. The floor is separated from the lateral wall by inferior orbital fissure, which connects the orbit to pterygopalatine and infratemporal fossa.

The medial wall is formed primarily by the orbital plate of ethmoid, as well as contributions from the frontal process of maxilla, the lacrimal bone, and a small part of the body of the sphenoid. It is the thinnest wall of the orbit, evidenced by pneumatized ethmoidal cells.[8]

The lateral wall is formed by the frontal process of zygomatic and more posteriorly by the orbital plate of the greater wing of sphenoid. The bones meet at the zygomaticosphenoid suture. The lateral wall is the thickest wall of the orbit, important because it is the most exposed surface, highly vulnerable to blunt force trauma.

Borders

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The base, orbital margin, which opens in the face, has four borders. The following bones take part in their formation:

  1. Superior margin: frontal bone
  2. Inferior margin: maxilla and zygomatic bone
  3. Medial margin: frontal bone and maxilla
  4. Lateral margin: zygomatic bone and frontal bone

Function

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The orbit holds and protects the eyes.

Eye movement

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The movement of the eye is controlled by six distinct extraocular muscles, a superior, an inferior, a medial and a lateral rectus, as well as a superior and an inferior oblique. The superior ophthalmic vein is a sigmoidal vessel along the superior margin of the orbital canal that drains deoxygenated blood from surrounding musculature. The ophthalmic artery is a crucial structure in the orbit, as it is often the only source of collateral blood to the brain in cases of large internal carotid infarcts, as it is a collateral pathway to the circle of Willis. In addition, there is the optic canal, which contains the optic nerve, or cranial nerve II, and is formed entirely by the lesser wing of the sphenoid, separated from the supraorbital fissure by the optic strut. Injury to any one of these structures by infection, trauma or neoplasm can cause temporary or permanent visual dysfunction, and even blindness if not promptly corrected.[9] The orbits also protect the eye from mechanical injury.[5]

Clinical significance

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In the orbit, the surrounding fascia allows for smooth rotation and protects the orbital contents. If excessive tissue accumulates behind the ocular globe, the eye can protrude, or become exophthalmic.[5]

 
Tear system:
a. tear gland / lacrimal gland,
b. superior lacrimal punctum,
c. superior lacrimal canal,
d. tear sac / lacrimal sac,
e. inferior lacrimal punctum,
f. inferior lacrimal canal,
g. nasolacrimal canal

Enlargement of the lacrimal gland, located superotemporally within the orbit, produces protrusion of the eye inferiorly and medially (away from the location of the lacrimal gland). Lacrimal gland may be enlarged from inflammation (e.g. sarcoid) or neoplasm (e.g. lymphoma or adenoid cystic carcinoma).[10]

Tumors (e.g. glioma and meningioma of the optic nerve) within the cone formed by the horizontal rectus muscles produce axial protrusion (bulging forward) of the eye.

Graves disease may also cause axial protrusion of the eye, known as Graves' ophthalmopathy, due to buildup of extracellular matrix proteins and fibrosis in the rectus muscles. Development of Graves' ophthalmopathy may be independent of thyroid function.[11]

Additional images

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Notes

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  1. ^ Also called the eye socket

References

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  1. ^ "Orbit – Definition and More from the Free Merriam-Webster Dictionary". Retrieved 2010-03-26.
  2. ^ Orbit at the U.S. National Library of Medicine Medical Subject Headings (MeSH)
  3. ^ Lieger, Olivier; Schaub, Manuel; Taghizadeh, Elham; Büchler, Philippe (2019). "How Symmetrical Are Bony Orbits in Humans?". Maxillofac Surg. 77 (1): 118-125118-125. PMID 30243522.
  4. ^ Tasman, W.; Jaeger, E. A., eds. (2007). "Embryology and Anatomy of the Orbit and Lacrimal System". Duane's Ophthalmology. Lippincott Williams & Wilkins. ISBN 978-0-7817-6855-9.
  5. ^ Jump up to: a b c "eye, human."Encyclopædia Britannica from Encyclopædia Britannica 2006 Ultimate Reference Suite DVD 2009
  6. ^ Mehta, M. P.; Perry, J. D. (2015). "Medial orbital wall landmarks in three different North American populations". Orbit. 34 (2): 72–8. doi:10.3109/01676830.2014.997394. PMID 25804299. S2CID 43317074.
  7. ^ Bertelli, E; Regoli, M (2014). "Branching of the foramen rotundum. A rare variation of the sphenoid". Italian Journal of Anatomy and Embryology. 119 (2): 148–53. PMID 25665284.
  8. ^ Jump up to: a b Moore, Keith L. (2010). Clinically Oriented Anatomy (6th ed.). Lippincott Williams & Wilkins. ISBN 978-07817-7525-0.
  9. ^ Ference, E. H.; Smith, S. S.; Conley, D; Chandra, R. K. (2015). "Surgical anatomy and variations of the infraorbital nerve". The Laryngoscope. 125 (6): 1296–300. doi:10.1002/lary.25089. PMID 25992806. S2CID 5567574.
  10. ^ Kumar, V.; Abbas, A. K.; Fausto, N. (2005). Robbins and Cotran Pathologic Basis of Disease (Seventh ed.). Philadelphia: Elsevier Saunders. p. 1423. ISBN 9780721601878.
  11. ^ Hatton, M. P.; Rubin, P. A. (2002). "The pathophysiology of thyroid-associated ophthalmopathy". Ophthalmol Clin North Am. 15 (1): 113–119. doi:10.1016/S0896-1549(01)00004-9. PMID 12064074.
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