Template:Short description Template:Cs1 config Template:Infobox medical conditionOptic neuritis (ON) is a debilitating condition that is defined as inflammation of cranial nerve II which results in disruption of the neurologic pathways that allow visual sensory information received by the retina to be able to be transmitted to the visual cortex of the brain.<ref name="Petzold_20222">Template:Cite journal</ref> This disorder of the optic nerve may arise through various pathophysiologic mechanisms, such as through demyelination or inflammation, leading to partial or total loss of vision.<ref name="Petzold_20222"/> Optic neuritis may be a result of standalone idiopathic disease, but is often a manifestation that occurs secondary to an underlying disease.
Signs of ON classically present as sudden-onset visual impairment in one or both eyes that can range in severity from mild visual blurring to complete blindness in the affected eye(s).<ref name=":02">Template:Citation</ref> Although pain is typically considered a hallmark feature of optic neuritis, the absence of pain does not preclude a diagnosis or consideration of ON as some patients may report painlessness.<ref name=":02"/>
ON is typically subtyped into "typical" ON and "atypical" ON. The most commonly considered etiologies are multiple sclerosis (MS), neuromyelitis optica (NMO) / neuromyelitis optica spectrum disorder (NMOSD), and myelin oligodendrocyte glycoprotein-antibody-associated disease (MOGAD).<ref>Template:Cite journal</ref> Other etiologies include idiopathic ON, infections (eg, syphilis, Lyme disease, and viral infections such as herpes simplex and varicella-zoster), and systemic autoimmune diseases (eg, systemic lupus erythematosus and sarcoidosis).<ref name=":02"/>
Diagnosis of ON can be made with a combination of symptom manifestation, clinical exam findings, imaging findings, and serologic studies.
Modern medical practice employs high-dose steroids, such as IV methylprednisolone, as the first-line treatment for optic neuritis.<ref name=":02"/>
Optic neuritis should not be confused with optic neuropathy, which is a condition manifesting as visual impairment that occurs as a result of damage to the optic nerve from any cause - one of those causes being optic neuritis.
Classification and causesEdit
DefinitionEdit
The optic nerve comprises axons that emerge from the retina of the eye and carry visual information to the primary visual nuclei, most of which is relayed to the occipital cortex of the brain to be processed into vision. The phrase optic neuritis is derived from the pathophysiologic changes observed in this disorder whereby the optic nerve (optic) becomes inflamed (neuritis). As such, optic neuritis is typically a manifestation of an underlying, causative etiology. Because of the breadth of underlying causes of optic neuritis, this disorder is typically classified into the subtypes of "typical" ON and "atypical" ON. Typical ON refers to a demyelinating etiology which most commonly stems from multiple sclerosis or standalone idiopathic disease.<ref name=":12">Template:Cite journal</ref> Atypical ON essentially refers to optic neuritis from any other cause.<ref name=":12"/>
Typical Optic NeuritisEdit
ON is classified as typical optic neuritis when demyelination is the causative pathophysiologic aberrancy.<ref name=":12"/> This classification attributes the manifestation of ON primarily to multiple sclerosis or standalone idiopathic disease, of which multiple sclerosis is the most common underlying etiology of all subtypes of optic neuritis.<ref name=":12" />
Multiple SclerosisEdit
Multiple sclerosis, in brief, is an autoimmune disease that results in demyelination of the nerves in the central nervous system (CNS). Demyelination in MS can be diffusely affect the CNS leading to a multitude of physical manifestations. Optic neuritis is acquired this way when MS spreads to the optic nerve. Optic neuritis is often among the first, if not the foremost, manifestation of MS.<ref name=":02"/> One review found that inflammatory demyelinating optic neuritic (IDON) is the initial presentation of MS in approximately 20% of studied patients, while another review found that up to 50% of MS patients will develop optic neuritis during their disease course.<ref>Template:Cite journal</ref><ref>Template:Cite journal</ref>
Idiopathic DiseaseEdit
Idiopathic optic neuritis (ION) generally refers to optic neuritis that does not present with serologic markers attributable to a known underlying cause (eg, NMOSD, MOGAD, etc.).<ref name=":35">Template:Cite journal</ref> Opinions among specialists seem to differ as to whether idiopathic optic neuritis should be classified as MS-associated ON or if it should not be exclusively associated with MS.<ref name=":4">Template:Cite journal</ref> A group of reviewers from China propose that ION should not be associated with MS and hence defined with the literal meaning of "idiopathic" as ON with an unknown cause.<ref name=":4" /> On the other hand, multiple groups of Western reviewers propose that ION should be considered a preceding manifestation, among a collection of manifestations, that precedes the development of MS in the absence of other serologic findings.<ref name=":22">Template:Cite journal</ref><ref name=":35"/>
Atypical Optic NeuritisEdit
ON is classified as atypical optic neuritis when the underlying cause is an etiology other than multiple sclerosis or standalone idiopathic disease. Atypical ON is most frequently seen as an early manifestation of neuromyelitis optica spectrum disorder (NMOSD), formerly known as neuromyelitis optica (NMO).<ref name=":52">Template:Cite journal</ref> Other causes of atypical ON include myelin oligodendrocyte glycoprotein-antibody-associated disease (MOGAD), other autoimmune disorders (eg, Sarcoidosis, Sjogren syndrome, rheumatoid arthritis, systemic lupus erythematosus), and infections (Bacterial [Tuberculosis, syphillis, meningitis, Lyme’s disease, Bartonella] or Viral [measles, mumps, rubella, chicken pox, herpes]).<ref name=":52"/>
NMOSD (Formerly NMO)Edit
Neuromyelitis optica spectrum disorder (NMOSD) is a disorder consisting of six syndromes that cause inflammation and demyelination of the CNS.<ref name=":6">Template:Citation</ref> The hallmark diagnostic criteria of NMOSD is the presence of the aquaporin-4 immunoglobulin G antibodies (AQP4-IgG) found on serology, which is the underlying aberrancy of this autoimmune condition that engenders its distinction from multiple sclerosis.<ref name=":6" /> Clinical manifestations of NMOSD, such as optic neuritis, occur due to antibody-mediated damage against the aquaporin-4 transmembrane water channels which are found in the foot processes of astrocytes at high concentrations within the optic nerve, brainstem, and spinal cord.<ref name=":6" />
MOGADEdit
Myelin oligodendrocyte glycoprotein-antibody-associated disease (MOGAD) is an autoimmune condition against the myelin oligodendrocyte glycoprotein (MOG) located on both the myelin sheathe and oligodendrocyte cell surfaces of the CNS.<ref name=":7">Template:Cite journal</ref> Cell-mediated and complement-mediated inflammation results hallmark findings of perivenous and confluent white matter demyelination.<ref name=":7" />
InfectionEdit
A wide range of attributable infectious etiologies have been found to cause optic neuritis and can arise from varying pathophysiologic mechanisms.<ref name=":52"/> The underlying inflammation and demyelination has been shown to manifest as anterior optic neuritis, retrobulbar optic neuritis (normal optic disc), neuroretinitis (optic disc edema with the macular star), or anterior optic neuropathy.<ref name=":52" /> It has been proposed that optic nerve involvement secondary to herpes zoster virus infection can arise from direct nerve inflammation or an ischemic mechanism leading to inflammatory thrombosis.<ref name=":52" /> Optic nerve involvement secondary to cytomegalovirus (CMV) infection has been proposed to involve a similar mechanism in patients with CMV retinitis.<ref>Template:Cite journal</ref> The pathogenesis of ON secondary to HIV has been proposed to arise from autoimmune, vascular, and degenerative ischemic pathways.<ref name=":52" />
Other CausesEdit
Other etiologies associated with optic neuritis include congenital anomalies, glaucoma, elevated intracranial pressure (i.e. papilledema), compression, nutritional and toxic optic neuropathy, trauma, inherited optic neuropathy, or infiltration (eg, neoplastic or granulomatous).<ref>Template:Cite journal</ref>
When an inflammatory recurrent optic neuritis is not demyelinating, it is called chronic relapsing inflammatory optic neuropathy (CRION).<ref>Template:Cite journal</ref>
Signs and symptomsEdit
SymptomsEdit
Major symptoms are:
- sudden loss of vision (partial or complete),
- sudden blurred or "foggy" vision, and
- pain on movement of the affected eye.<ref>{{#invoke:citation/CS1|citation
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Patients with optic neuritis may experience dyschromatopsia which describes a range of color vision in the affected eye (especially red), with colors appearing subtly washed out compared to the other eye. Patients may also experience difficulties judging movement in depth, which can be particular troublesome during driving or sport (Pulfrich effect). Likewise, transient worsening of vision with increase of body temperature (Uhthoff's phenomenon) and glare disability are a frequent complaint.
Involvement of the optic nerve may be unilateral or bilateral, depending on the underlying etiology.<ref name=":35"/> For example, MS-optic neuritis often presents unilaterally while NMOSD-optic neuritis and MOGAD-optic neuritis more often present bilaterally.
However not everyone who has optic neuritis has problems with their vision.<ref>{{#invoke:citation/CS1|citation |CitationClass=web }}</ref>
Early SymptomsEdit
Early symptoms that require investigation include symptoms from multiple sclerosis (twitching, lack of coordination, slurred speech, frequent episodes of partial vision loss or blurred vision), episodes of "disturbed/blackened" rather than blurry indicate moderate stage and require immediate medical attention to prevent further loss of vision. Other early symptoms are reduced night vision, photophobia and red eyes.
Variation in symptoms with ageEdit
Several case studies in children have demonstrated the absence of pain in more than half of cases (approximately 60%) in their pediatric study population, with the most common symptom reported simply as "blurriness".<ref>Template:Cite journal</ref><ref>Template:Cite journal</ref> Other remarkable differences between the presentation of adult optic neuritis as compared to pediatric cases include more often unilateral optic neuritis in adults, while children much predominantly present with bilateral involvement.
DiagnosticsEdit
The World Health Organization's ICD-11 classification includes optic neuritis.<ref name="auto122"/> However a 2022 review found that there is no consensus regarding the classification of optic neuritis, and precise diagnostic criteria are not available.<ref>Template:Cite journal</ref> In practice, optic neuritis is diagnosed by a combination of features pertaining to symptom manifestation, clinical evaluation, and imaging findings.
Clinical EvaluationEdit
A trained healthcare provider may evaluate a patient for optic neuritis by identifying the presence and degree of visual acuity loss, visual field loss, color vision deficits, and an afferent pupillary defect in the affected eye.<ref name=":35"/> The presence, absence, or degree of these manifestations may have associations with specific underlying etiologies of optic neuritis, but are often insufficient to definitively establish a diagnosis of optic neuritis and its associated cause.
Fundoscopy is another modality of clinical evaluation that is performed with an ophthalmoscope. Findings that support a diagnosis of optic neuritis include optic disc edema, disc inflammation, disc hemorrhages, or ocular inflammation.<ref name=":35"/> However, these findings are not always present in every patient, such as in patients with idiopathic optic neuritis which often have normal fundoscopic findings.
MRIEdit
Magnetic resonance imaging (MRI) is a robust and sensitive diagnostic modality for the detection of optic neuritis. Imaging of the optic nerve with MRI shows increased signal on the affected side. There is contrast enhancement of the symptomatic optic nerve and sheaths acutely or intrinsic signal increase (looking brighter) within ≥ 3 months. One study found that MRI of the orbits with fat suppression and gadolinium enhancement detected acute optic neuritis lesions in 95% of affected individuals within 20 days of vision loss.<ref>Template:Cite journal</ref> Another study found that T2-weighted images with fat suppression and short tau inversion recovery (STIR) detected lesions in up to 89% of acute optic neuritis cases with abnormalities persisting for as long as 6 weeks in 92% of cases.<ref>Template:Cite journal</ref>
Identification of optic nerve, orbital, brain, and meningeal involvement with MRI can also help to better characterize the underlying cause of optic neuritis upon initial evaluation. Unilateral optic nerve involvement is more common MS while bilateral optic nerve involvement is more common in NMOSD and MOGAD.<ref name=":35"/> T2-hyperintense and gadolinium-enhancing lesions in multiple regions of the brain and/or spinal cord may be highly suggestive or diagnostic of MS. Such lesions found in the periependymal, fornix, and hypothalamic lesions may be more suggestive of NMOSD.<ref name=":35"/> Involvement of the optic chiasm or optic tract are more suggestive of NMOSD-optic neuritis; involvement of the retrobulbar optic nerve can be seen in both NMOSD and MOGAD, but more commonly in MOGAD; perineural optic nerve involvement is often suggestive of MOGAD-optic neuritis, but should not preclude the investigation of other autoimmune or infectious etiologies.<ref name=":35"/>
OCTEdit
Optical coherence tomography (OCT) is a sensitive imaging modality that can reveal subtle pathologic changes in the optic nerve and retina.<ref name=":35"/> OCT may reveal changes in thickness of the retinal nerve fiber layers (RNFL) at the peripapillary retina and macula.<ref name=":35" /> The OCT shows corresponding optic disc swelling acutely or an inter-eye difference in the thickness of the neurons and their nerves connecting the eye with the brain in above 4-5% within ≥ 3 months after onset.<ref name="Petzold_20222"/>
New advancements in OCT technology have allowed for the development of OCT angiography which can provide information on the thickness of retinal blood vessels. Whereas OCT has yet to demonstrate identifiable correlations between acute RNFL changes and visual outcomes or treatment responses, OCT angiography may offer novel diagnostic and prognostic insight.
VEPEdit
Visual evoked potential (VEP) is a sensitive test that measures the P100 latency of axonal transmission along the optic nerve. The P100 latency typically peaks at 100 milliseconds after visual stimulus presentation, and a prolonged P100 latency suggests abnormal conduction along this pathway which confirms the presence of optic neuropathy.<ref name=":35" />
Outlook and TreatmentEdit
Many patients see full recovery but some see some lasting effects.<ref name="auto2"/><ref>{{#invoke:citation/CS1|citation |CitationClass=web }}</ref><ref>{{#invoke:citation/CS1|citation |CitationClass=web }}</ref>
SteroidsEdit
High dose steroids may be given intravenously (IV) or orally, though IV steroids such as methylprednisolone are typically recommended.<ref name="auto2"/> Studies, including the Optic Neuritis Treatment Trial (ONTT), support such a guideline based on the statistically significant outcomes showing the efficacy of this treatment modality in restoring visual acuity and lessening ON's other associated symptoms.<ref name=":22"/>
In most MS-associated optic neuritis, visual function spontaneously improves over 2–3 months, and there is evidence that corticosteroid treatment does not affect the long term outcome. However, for optic neuritis that is not MS-associated (or atypical optic neuritis) the evidence is less clear and therefore the threshold for treatment with intravenous corticosteroids is lower.<ref name="Petzold_20222"/> Intravenous corticosteroids also reduce the risk of developing MS in the following two years in patients with MRI lesions; but this effect disappears by the third year of follow up.<ref name="The effect of corticosteroids for a">Template:Cite journal</ref>
Paradoxically, oral administration of corticosteroids in this situation may lead to more recurrent attacks than in non-treated patients (though oral steroids are generally prescribed after the intravenous course, to wean the patient off the medication). This effect of corticosteroids seems to be limited to optic neuritis and has not been observed in other diseases treated with corticosteroids.<ref>Template:Cite journal</ref>
A Cochrane systematic review studied the effect of corticosteroids for treating people with acute optic neuritis.<ref name="Vedula">Template:Cite journal</ref> Specific corticosteroids studied included intravenous and oral methylprednisone, and oral prednisone. The authors conclude that current evidence does not show a benefit of either intravenous or oral corticosteroids for rate of recovery of vision (in terms of visual acuity, contrast sensitivity, or visual fields).<ref name=Vedula /> There are a number of reasons why this might be the case.<ref name="The effect of corticosteroids for a"/><ref>Template:Cite journal</ref>
ImmunosuppressantsEdit
Immunosuppressants may also be used in treatment.<ref name="auto2"/>
Pain reliefEdit
Pain relief may also be used.<ref name="auto2"/>
EpidemiologyEdit
Optic neuritis typically affects young adults ranging 18–45 years of age, with a mean age of 30–35 years. There is a strong female predominance. The annual incidence is approximately 5/100,000, with a prevalence estimated to be 115/100,000 (0.12%).<ref>Template:Cite journal</ref>
Society and cultureEdit
In Charles Dickens' Bleak House, the main character, Esther Summerville, has a transient episode of visual loss, the symptoms of which are also seen in people who have optic neuritis.<ref>Template:Cite journal</ref> Legal historian William Searle Holdsworth suggested that the events in Bleak House took place in 1827.
In an episode of Dr. Quinn, Medicine Woman ("Season of Miracles", season five), Reverend Timothy Johnson is struck blind by optic neuritis on Christmas Day 1872. He remains blind for the duration of the series.
See alsoEdit
ReferencesEdit
External linksEdit
- Diagnosis and classification of optic neuritis, translated into 116 languages and free for download
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