Orbit

The Orbit

Anatomy

The orbit is a pear-shaped cavity, the stalk of which is the optic canal.

• The roof consists of two bones: the lesser wing of the sphenoid and the orbital plate of

the frontal bone. It is located subjacent to the anterior cranial fossa and the frontal sinus.

A defect in the orbital roof may cause pulsatile proptosis due to transmission of

cerebrospinal fluid pulsation to the orbit.

• The lateral wall also consists of two bones: the greater wing of the sphenoid and the

zygomatic. The anterior half of the globe is vulnerable to lateral trauma since it protrudes

beyond the lateral orbital margin.

• The floor consists of three bones: the zygomatic, maxillary and palatine. The

posteromedial portion of the maxillary bone is relatively weak and may be involved in a

‘blowout’ fracture. The orbital floor also forms the roof of the maxillary sinus so that

maxillary carcinoma invading the orbit may displace the globe upwards.

• The medial wall consists of four bones: maxillary, lacrimal, ethmoid and sphenoid. The

lamina papyracea, which forms part of the medial wall, is paper-thin and perforated by

numerous foramina for nerves and blood vessels. Orbital cellulitis is therefore frequently

secondary to ethmoidal sinusitis.

• The superior orbital fissure is a slit linking the cranium and the orbit, between the

greater and lesser wings of the sphenoid bone; through it pass numerous important

structures.

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The superior portion contains the lacrimal, frontal and trochlear nerves, and the

superior ophthalmic vein.

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The inferior portion contains the superior and inferior divisions of the oculomotor

nerve, the abducens and nasociliary nerves, and sympathetic fibres from the cavernous

plexus.

Inflammation of the superior orbital fissure and apex (Tolosa–Hunt syndrome) may

therefore result in a multitude of signs including ophthalmoplegia and venous outflow

obstruction.

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• The inferior orbital fissure lies between the greater wing of the sphenoid and the

maxilla, connecting the orbit to the pterygopalatine and infratemporal fossae. Through it

run the inferior ophthalmic vein.

Clinical signs of orbital disease:

1.soft tissue involvement: lid and periorbital edema, ptosis (mechanical ptosis due to

swelling leading to heaviness of the lid) , conjunctival chemosis (edema) and conjunctival
injection.

2. proptosis: it is an abnormal protrusion of the globe which may be caused by retro

bulbar lesion which push globe forward or less frequently a shallow orbit which is usually

congenital. When it is asymmetrical it is best detected by looking down on the patient

from above and behind.

•  Direction of proptosis may indicate the possible pathology.eg a SOL within the

extra ocular muscle cone (optic nerve glioma) causes axial proptosis whereas an

extraconal mass would push the globe away from its site causing eccentric

proptosis e.g. lacrimal gland adenoma.

•  Severity of proptosis can be measured by a simple plastic ruler resting on the

lateral orbital margin or using an Hertel exopthalmometer (a plate attached to it 2

mirrors placed at 45 degree). normally ,the apex of the cornea is about 20mm

anterior to lateral orbital margin, and anything more than 21 mm is considered

proptosis, and >2mm difference between the two eye balls is suspicious regardless

to the absolute value. Proptosis can be graded as mild (21-23mm), moderate (24-

27mm) or severe (28mm and more).

•  Pseudoproptosis or false impression of proptosis may be due to facial asymmetry,

severe ipsilateral enlargement of the eye ball (high myopia or buphthalmos),

ipsilateral lid retraction or contra lateral enophthalmos.

3. Enophthalmos: recession of the globe within the orbit.

Causes: a. structural abnormalities of the orbital walls e.g. blow out fracture. b.

atrophy of the orbital contents e.g. following radiotherapy. c. cicatrizing orbital lesions

e.g. schirrous carcinoma.

Pseudo enophthalmos may be caused by microphthalmia or pthiasis bulbi.

4.ophthalmoplegia: defective ocular motility may be caused by an orbital mass, restrictive

myopathy as in thyroid eye disease, ocular motor nerve lesion or entrapment of the

muscle or its fascia in a blowout fracture.

5.visual dysfunction: impaired vision can be caused by: A/ Exposure keratopathy

secondary to severe proptosis. B/ Compressive optic neuropathy. C/ Choroidal folds

6.ocular signs:

•  Optic disc changes such as optic atrophy which is usually preceded by swelling. It is

due to compressive optic neuropathy

•  Choroidal folds seen as striae or lines at the posterior pole due to pressure by orbital

mass. they sometimes proceed the onset of proptosis

•  Retinal vascular changes such as venous dilatation and tortuosity or vascular

occlusion

8.dynamic properties

•  Increased venous pressure by Valsalva maneuver or jugular compression may

exacerbate proptosis secondary to orbital venous anomalies.

•  Pulsation of the orbital contents or the globe can accompany an arteriovenous

communication or orbital roof defect

•  Bruit is a sign of carotid-cavernous fistula

Special investigations:

The following investigations can help to locate an orbital lesion or to define the

consistency of a SOL: 1.plain radiography. 2.CT scan. 3.MRI. 4.Fine needle biopsy under CT

guidance.

THYROID EYE DISEASE

Thyroid eye disease (TED), also known as thyroid-associated orbitopathy and Graves

ophthalmopathy, is a very common orbital disorder, and is the most common cause of

both bilateral and unilateral proptosis in an adult.

Risk factors for ophthalmopathy

Once a patient has Graves disease, the major clinical risk factor for developing TED is

smoking. Women are five times more likely to be affected by TED than men. Radioactive

iodine used to treat hyperthyroidism can worsen TED. TED can also, though less

commonly, occur in euthyroid and hypothyroid (including treated hyperthyroid) patients.

It can sometimes be the presenting manifestation of thyroid-related disease.

Pathogenesis of ophthalmopathy

Thyroid ophthalmopathy involves an organ-specific autoimmune reaction in which an

antibody that reacts against thyroid gland cells and orbital fibroblasts leads to

inflammation of extraocular muscles, interstitial tissues, orbital fat and lacrimal glands

characterized by pleomorphic cellular infiltration, associated with increased secretion of

glycosaminoglycans and osmotic imbibition of water. There is an increase in the volume of

the orbital contents, particularly the muscles, which can swell to eight times their normal

size. There may be a secondary elevation of intraorbital pressure, and the optic nerve may

be compressed. Subsequent degeneration of muscle fibres eventually leads to fibrosis,

which exerts a tethering effect on the involved muscle, resulting in restrictive myopathy

and diplopia.

Clinical features:

TED typically proceeds through a congestive (inflammatory) stage in which the eyes are

red and painful; this tends to remit within 1–3 years and only about 10% of patients

develop serious longterm ocular problems. A fibrotic (quiescent) stage follows in which the

eyes are white, although a painless motility defect may be present. Clinical features

broadly can be categorized into (i) soft tissue involvement, (ii) lid retraction, (iii) proptosis,

(iv) optic neuropathy and (v) restrictive myopathy.

(I)  Soft tissue involvement:

• Symptoms. Grittiness, red eyes, lacrimation, photophobia, puffy lids and retrobulbar

discomfort.

• Signs may include:

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Epibulbar hyperaemia.

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Periorbital swelling is caused by oedema and infiltration behind the orbital septum; this

may be associated with chemosis and prolapse of retroseptal fat into the eyelids.

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Tear insufficiency and instability is common.

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Corneal signs are exacerbated by lid retraction and can include punctate epithelial

erosions, superior limbic keratoconjunctivitis, and occasionally bacterial keratitis, thinning

and scarring.

(II) Lid retraction:

Retraction of upper and lower lids occurs in about 50% of patients with Graves disease.

Humorally induced overaction of Müller muscle is postulated to occur as a result of

sympathetic overstimulation secondary to high levels of thyroid hormones. Fibrotic

contracture of the levator palpebrae and inferior rectus muscles associated with adhesion

to overlying orbital tissues is another probable mechanism, together with secondary

overaction in response to hypo- or hypertropia produced by fibrosis.

• Symptoms. Patients may complain of a staring or bulging eyed appearance, difficulty

closing the eyes and ocular surface symptoms.

• Signs

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The upper lid margin normally rests 2 mm below the limbus. Lid retraction is suspected

when the margin is either level with or above the superior limbus, allowing sclera to be

visible (‘scleral show’).

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The lower eyelid margin normally rests at the inferior limbus; retraction is suspected

when sclera shows below the limbus. Lid retraction may occur in isolation or in association

with proptosis, which exaggerates its severity.

(III) Proptosis :

• Symptoms are similar to those of lid retraction.

• Signs. Proptosis is axial, unilateral or bilateral, symmetrical or asymmetrical, and

frequently permanent. Severe proptosis may compromise lid closure and along with lid
retraction and tear dysfunction can lead to exposure keratopathy, corneal ulceration and

infection.

(IV) Restrictive myopathy:

Between 30% and 50% of patients with TED develop ophthalmoplegia and this may be

permanent. Ocular motility is restricted initially by inflammatory oedema, and later by

fibrosis.

• Symptoms. Double vision, and often discomfort in some positions of gaze.

• Signs, in approximate order of frequency:

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Elevation defect caused by fibrotic contracture of the inferior rectus, is the most

common motility deficit.

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Abduction defect due to fibrosis of the medial rectus, which may simulate sixth nerve

palsy.

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Depression defect secondary to fibrosis of the superior rectus.

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Adduction defect caused by fibrosis of the lateral rectus.

(V) Optic neuropathy:

Optic neuropathy is a serious complication caused by compression of the optic nerve or

its blood supply at the orbital apex by the congested and enlarged recti and swollen
orbital tissue. Such compression, which may occur in the absence of significant proptosis,

may lead to severe visual impairment if adequate and timely treatment is not instituted.

• Symptoms. Impairment of central vision occurs in conjunction with other symptoms of

TED.

• Signs. A high index of suspicion should be maintained for optic neuropathy:

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Visual acuity (VA) is usually reduced.

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Colour desaturation.

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There may be diminished light brightness appreciation.

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A relative afferent pupillary defect.

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Visual field defects can be central or paracentral and may be combined with nerve fibre

bundle defects. These findings, in concert with elevated IOP, may be confused with

primary open-angle glaucoma.

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The optic disc may be normal, swollen or, rarely, atrophic.

Investigation

Investigations other than blood tests for thyroid disease are not necessary if the diagnosis
is evident clinically, but the exclusion of other conditions is sometimes indicated. Visual

field testing is carried out if there is a suspicion of optic nerve compromise. MRI, CT and

ultrasonographic imaging of the orbits are indicated in some circumstances, such as

helping to confirm an equivocal diagnosis by identification of the typical pattern of

extraocular muscle involvement in TED, consisting of muscle belly enlargement with

tendon sparing. Imaging is also used in the assessment of optic nerve compression and

prior to orbital wall surgery. Visual evoked potentials are sometimes utilized in optic

neuropathy.

Treatment

Treatment can be classified into that of mild disease (most patients), moderate to severe

active disease, and treatment of post inflammatory complications. The first measure taken

in all cases should be the cessation of smoking. Thyroid dysfunction should also be

managed adequately; if radioiodine treatment is administered in patients with pre-existing

TED, a short course of oral steroids should be given in concert.

• Mild disease

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Lubricants for superior limbic keratoconjunctivitis, corneal exposure and dryness.

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Topical anti-inflammatory agents (steroids, NSAIDs, ciclosporin).

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Head elevation with three pillows during sleep to reduce periorbital oedema.

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Eyelid taping during sleep may alleviate mild exposure keratopathy.

Moderate to severe active disease

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Systemic steroids are the mainstay of treatment for moderate to severe disease. Oral

prednisolone may be given initially, and tapered depending on response. Intravenous

methylprednisolone is often reserved for acute compressive optic neuropathy.

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Orbital steroid injections are occasionally used in selected cases to minimize systemic

side effects, but are typically considerably less effective than systemic treatment.

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Low-dose fractionated radiotherapy may be used in addition to steroids or when

steroids are contraindicated or ineffective, but because of the delayed effect is not used as

the sole treatment of acute optic nerve compression. A positive response is usually

evident within 6 weeks, with maximal improvement by 4 months; around 40% will not

respond. Adverse effects include cataract, radiation retinopathy, optic neuropathy and an

increased risk of local cancer; the threshold for its use should be higher in younger

patients and diabetics, the latter because of a possibly increased risk of retinopathy.

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Combined therapy with irradiation, azathioprine and low-dose prednisolone may be

more effective than steroids or radiotherapy alone.

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Optic neuropathy, and less commonly intractable corneal exposure, requires aggressive

treatment. Pulsed intravenous methylprednisolone is commonly used, followed by oral

prednisolone. Orbital wall decompression and/or orbital apex decompression may be

considered if steroids are ineffective or contraindicated. Orbital radiotherapy may also be

administered, but is generally only used as an adjunct to other modalities.

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Drugs targeting the immune response in TED are used like rituximab.

• Post-inflammatory complications. Eyelid surgery should be performed only after any

necessary orbital and then strabismus procedures have been undertaken, as orbital

decompression may impact both ocular motility and eyelid position, and extraocular

muscle surgery may affect eyelid position.

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Proptosis. After active inflammation has remitted, Surgical decompression increases

the volume of the orbit by removing the bony walls and may be combined with removal of

orbital fat. One-wall; two-wall; three-wall and four-wall decompression may be done.

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Restrictive myopathy. Surgery is required in most cases, provided the inflammatory

stage has subsided and the angle of deviation has been stable for at least 6–12 months.

Recession of the inferior and/or medial recti is the most commonly indicated surgery.

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Lid retraction. Mild lid retraction frequently improves spontaneously so does not

require treatment. Botulinum toxin injection to the levator aponeurosis and Müller muscle

may be used. Müllerotomy is effective for mild lid retraction, but more severe cases may

also require recession/disinsertion of the levator aponeurosis and the suspensory ligament

of the superior conjunctival fornix.

Preseptal cellulitis

Preseptal cellulitis is an infection of the subcutaneous tissues anterior to the orbital

septum. It is considerably more common than orbital cellulitis, and though regarded as

less serious, can still be associated with severe complications such as abscess formation,

meningitis and cavernous sinus thrombosis. Rapid progression to orbital cellulitis may

occasionally occur. Organisms typically responsible are Staphylococcus aureus and

Streptococcus pyogenes, with causes including skin trauma such as laceration or insect

bites, spread from focal ocular or periocular infection such as an acute hordeolum,

dacryocystitis, conjunctivitis or sinusitis, and haematogenous spread from remote

infection such as the upper respiratory tract or middle ear.

Diagnosis

The condition manifests with a swollen, often firm, tender red eyelid that may be very

severe; however, in contrast to orbital cellulitis, proptosis and chemosis are absent, and

visual acuity, pupillary reactions and ocular motility are unimpaired. The patient is often

pyrexial. Imaging with MRI or CT is not indicated unless orbital cellulitis or a lid abscess is

suspected, or there is a failure to respond to therapy.

Treatment

Treatment is with oral antibiotics such as co-amoxiclav. Severe infection may require

intravenous antibiotics.

Bacterial orbital cellulitis

Bacterial orbital cellulitis is a serious infection of the soft tissues behind the orbital

septum, which can be sight- and life-threatening. It can occur at any age but is more

common in children. Streptococcus pneumoniae, Staphylococcus aureus, Streptococcus

pyogenes and Haemophilus influenzae are common causative organisms, with infection

originating typically from the paranasal (especially ethmoid) sinuses. Infection can also

spread from preseptal cellulitis, dacryocystitis, midfacial skin or dental infection, and can

follow trauma, including any form of ocular surgery. Blood-borne spread from infection

elsewhere in the body may occur.

Clinical features

• Symptoms consist of the rapid onset of pain exacerbated by eye movement, swelling of

the eye, malaise, and frequently visual impairment and double vision. There is commonly a
recent history of nasal, sinus or respiratory symptoms.

• Signs

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Pyrexia, often marked.

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VA may be reduced and colour vision impaired, raising the possibility of optic nerve

compression; the presence of a relative afferent pupillary defect in a previously normal

eye makes this almost certain.

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Tender, firm, erythematous and warm eyelids, with periocular and conjunctival

(chemosis) oedema, conjunctival injection and sometimes subconjunctival haemorrhage;

the signs are usually unilateral, though oedema may spread to the contralateral eyelids.

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Proptosis is common in established infection, but is often obscured by lid swelling; it

may be non-axial (dystopia), particularly if an abscess is present.

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Painful ophthalmoplegia.

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Choroidal folds and optic disc swelling may be present on fundus examination.

Investigations may include:

• White cell count.

• Blood cultures.

• Culture of nasal discharge.

• High-resolution CT of the orbit, sinuses and brain.

• Lumbar puncture if meningeal or cerebral signs develop.

Treatment

• Hospital admission is mandatory, with urgent otolaryngological assessment and

frequent ophthalmic review.

• Antibiotics are given intravenously, ceftazidime is a typical choice, supplemented by oral

metronidazole to cover anaerobes.

• Monitoring of optic nerve function is performed at least every 4 hours initially by testing

VA, colour vision, light brightness appreciation and pupillary reactions. Deterioration

should prompt the consideration of surgical intervention.

• Surgery. Drainage of an orbital abscess should be considered at an early stage; drainage

of infected sinuses should be considered if there is a lack of response to antibiotics, or if

there is very severe sinus disease. Biopsy of inflammatory tissue may be performed for an

atypical clinical picture. Severe optic nerve compression may warrant an emergency

canthotomy/cantholysis.

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