THERE ARE AN ESTIMATED 2-3 million emergency department (ED) visits in the United States for eye complaints, with estimates projected to increase due to a declining ophthalmology workforce and challenges in access to care resulting in more emergency department (ED) visits for eye complaints (Kim et al., 2022; Lee et al., 2019; Patel et al., 2023). Most patients who present to the ED have nontraumatic eye complaints (Channa et al., 2016); however, an analysis of the National Emergency Department Sample data set found that approximately one third of ED visits for eye complaints are related to eye trauma, which is more common during the summer months, in males, and in patients between the ages of 20 and 60 years (Kim et al., 2022; Ramirez et al., 2018). Approximately one third of all eye-related ED visits in the United States annually are for traumatic eye injuries (Channa et al., 2016; Go et al., 2022; Kim et al., 2022). Ocular trauma, which is often preventable, is a leading cause of unilateral blindness and vison impairment (Cheung et al., 2014; Go et al., 2022). Ocular trauma is more prevalent in White males, ages 45-64 years, and the most common causes are motor vehicle accidents, followed by fall-related accidents, and infection (Cheung et al., 2014).
Given the prevalence of eye-related ED visits, it is important that ED providers understand how to recognize and treat eye complaints to rapidly identify urgent and emergent eye conditions requiring prompt referral and treatment to promote optimal visual outcomes and prevent disability (Channa et al., 2016). This article: (1) reviews eye anatomy and physiology, (2) discusses the approach to the eye examination (i.e., external, internal, and slit lamp), and (3) provides selected common nonemergent and emergent eye complaints within the broad categories of traumatic injuries, red eye, and acute vision loss. For each complaint, a review of essential history questions, examination techniques, differentials to consider, and ED management has been presented.
EYE ANATOMY
This section covers ocular and adnexal structures. Bony structures have also been described herein.
Ocular and Adnexal Structures
Figure 1 shows the adnexal structures, the tissues surrounding the eye, and the inner eye anatomy. The internal ocular structures are protected by the thick protective cornea. Blunt force or penetrating trauma, foreign bodies, chemical splashes, abrasions, or perforations can damage the cornea as well as the anterior and posterior ocular structures. Injuries to the cornea and deeper structures can result in pain and vision loss. Some injuries require emergent referral whereas others can be managed with close outpatient follow-up.
Bony Structures
Figure 2 shows the orbital bony structures that surround the eye. The orbital bony ridge is composed of the frontal and the thin, fragile maxillary, ethmoidal, sphenoid, lacrimal, palatine, and zygomatic bones. Blunt force trauma can fracture the delicate bones that make up the orbital floor entrapping the inferior rectus and inferior oblique muscles limiting movements and causing diplopia.
EYE EXAMINATION
This section discusses the approach to the eye examination including the external, internal, and slit lamp examinations. Table 1 lists the basic steps in the eye examination.
Obtain visual acuity first unless the patient had a biological or chemical splash, has an abnormal pupil, history of a penetrating eye injury, or if exposed to riot control agents (tear gas). If the provider is unable to obtain visual acuity, perform a gross estimate of the patient's vision. See Table 2.
External Examination
Examine the external and adnexal eye structures. This includes pupillary response, extraocular movements, visual fields, eyelids, conjunctiva, and cornea. Evert the lid to inspect for possible foreign bodies. Gently palpate the bony orbit if you suspect a fracture. Palpation of the closed eye with comparison to the unaffected eye can be used as a gross assessment of intraocular pressure (IOP) if tonometry is unavailable. Examine extraocular movements especially in patients complaining of visual disturbances.
To differentiate between optic and neurologic causes of vision loss, perform the swinging flashlight test used to assess for optic nerve neuropathy. To perform this test, examine the patient's pupils in ambient lighting. They should be equal in size. Next, darken the room and begin alternately shining a light into the patient's right and left eyes. Normally, the light will cause constriction in the stimulated eye along with consensual constriction in the other eye; however, if the optic nerve is damaged, direct light stimulation will cause dilation rather than constriction (Graves & Galetta, 2012). This abnormal pupillary response is referred to as a Marcus Gunn pupil.
Visual field testing is also an important aspect of checking optic nerve function, lesions in the brainstem or cerebellum, or paralysis or palsy of cranial nerves III, VI, and IV in patients complaining of visual disturbances or vision loss. If the damage is limited to one optic nerve, vision loss will be unilateral. If the damage occurs in the optic chiasm where the two optic nerves meet, vision loss will affect the outer peripheral visual fields of both eyes. If the visual pathway is damaged between the optic chiasm and the visual cortex of the occipital lobe, vision loss will affect the same visual fields in both eyes. For example, if the damage is in the right visual cortex, the patient will have vision loss in the left visual fields of both eyes.
Internal Examination
Examine the posterior chamber structures including the retina and optic disc with the ophthalmoscope. Check the red reflex and retinal vessels for nicking and pulsations. Note any abnormalities such as cotton wool spots or hemorrhages on the retina.
Slit Lamp Examination
After directly inspecting the external and internal eye structures, the cornea should be stained with fluorescein to check for defects. Do not apply fluorescein if suspicion of a penetrating foreign body, which can also cause an abnormal pupillary response. If after instilling fluorescein stain a Seidel sign, or leakage of aqueous fluid from the cornea, is noted, obtain an emergent computerized tomography (CT) scan of the orbits to assess for a penetrating foreign body that has torn through the cornea into the anterior or posterior chamber.
Next, assess the eye with a slit lamp, an ophthalmologic biomicroscope, to further examine the external eye structures, cornea, anterior chamber, and posterior chamber structures including the retina. Slit lamp assessment is the gold standard for examining eye complaints in the ED (DelMonte et al., 2023). Use of a slit lamp is a core clinical competency for ED clinicians but requires specialized training and practice for accurate assessment of eye trauma and disease (American Academy of Emergency Nurse Practitioners & Emergency Nurses Association, 2021). For an excellent resource on using the slit lamp and what to look for, refer to Dr. Timothy Root's book and video lecture series (Root, n.d.). If a slit lamp is not available, use a Wood's lamp to examine the cornea for defects after instilling fluorescein stain. Figure 3 shows a Wood's lamp and Figure 4 shows a slit lamp.
Intraocular Pressure Measurement
Obtaining IOP measurements using tonometry is indicated in patients presenting with blunt eye trauma, a hyphema, or if a red eye associated with pain to rule out acute narrow-angle glaucoma. There are two types of tonometers used in the ED, the iCare (iCare Finland Oy, Vantaa, Finland) device and the Tono-Pen (Reichart, Inc, Depew, New York). Figures 5 and 6 show these different devices.
The iCare instrument uses a lightweight magnetic probe that lightly taps the cornea to obtain a rebound measure of IOP. This allows for a painless assessment that does not require anesthetizing the eye prior to the examination. In contrast, eye anesthetization is required when using a Tono-Pen because the probe of the device is placed directly on the cornea to obtain pressure readings. Both devices are easy to use, correlate well, but require practice to ensure accurate readings (Lee et al., 2019). Table 3 reviews the steps in using a tonometer to obtain IOP readings with indications for emergent and urgent ophthalmologic referral.
SELECTED EYE EMERGENCIES
The next section covers eye trauma including the etiology of eye trauma across the lifespan, external structure injuries, corneal injuries, ocular burns, blunt eye trauma, and penetrating foreign bodies. Red eye and vision loss are also discussed.
Eye Trauma
Table 4 summarizes the history questions to include when assessing a patient with a traumatic eye injury.
Table 5 lists the trauma-related eye examination steps. Traumatic eye injuries can be classified according to where they occur within the eye or surrounding structures.
Table 6 depicts injury type by eye structure and urgency of referral to ophthalmology for definitive care. Patients with ocular trauma require tetanus prophylaxis if their immunization status is not up to date.
Superficial injury of the cornea is the most common traumatic diagnosis across age groups, and males sustain most of the injuries (Kim et al., 2022; Miller et al., 2018; Ramirez et al., 2018). Other traumatic diagnoses include ocular contusions, anterior and posterior segment injuries, orbital fractures, and open globe injuries (Cheung et al., 2014).
Lacerations and contusions to the eyelids can typically be managed without the need for ophthalmology referral unless they involve the lacrimal gland and structures, which require prophylactic antibiotic medication and surgical repair with stent placement within 48 hr (Ducasse et al., 2016). Open globe injuries and eyeball lacerations require immediate ophthalmologic referral with repair within 6 hr (Ducasse et al., 2016). Patients experiencing these injuries will require analgesics and often antiemetic medications.
If there is bruising and abnormal extraocular movements, suspect a fracture, order an orbital and facial CT, provide prophylactic antibiotics, and consult an ophthalmologist or facial plastic surgeon emergently (Koenen & Waseem, 2022). Anterior and posterior segment injuries such as hyphema or retinal detachment also require emergent evaluation by an ophthalmologist.
Etiology of Eye Trauma Across the Lifespan
Pediatric eye injuries are typically nonemergent and include corneal abrasions, conjunctivitis, and foreign bodies (Miller et al., 2018). The most common pediatric eye emergencies include eyebrow and eyelid lacerations, contusions of the eye area, eye pain, and visual disturbances (Miller et al., 2018). Because eye injuries may result from child maltreatment, maintain a high degree of suspicion when assessing children with ocular injuries (Christian & Binenbaum, 2022).
Sports-related injury is a frequent etiology in pediatric eye trauma among children aged 10-17 (Kim et al., 2022; Miller et al., 2018; Patel et al., 2023). In a cross-sectional analysis of sports-related ocular trauma obtained from the U.S. Consumer Product Safety National Electronic Injury Surveillance System All Injury Program dataset, Patel et al. (2023) found that basketball (37.8%), baseball (12.8%), and football (12.3%) accounted for most sports-related ocular injuries. Corneal/scleral abrasions were more common with basketball injuries, contusions with baseball, and major anterior and posterior ocular injuries occurring more often from nonpowder guns (paintball, BB, and pellet) and soccer. Although the frequency of eye trauma is more common in boys, dance, gymnastics, and cheerleading are the sports activities associated with most eye injuries in girls (Miller et al., 2018).
In adults, use of workshop tools accounts for most cases of product-related ocular trauma in those older than 20 years whereas sports activities account for most cases of ocular trauma in those younger than 20 years (Go et al., 2022). Injury from falling on home furniture causes most ocular injuries in adults older than 80 years (Go et al., 2022).
Corneal Injuries
Minor anterior chamber/segment injuries include corneal/scleral abrasions and foreign bodies that can be managed with oral or topical analgesic medication, such as ketorolac drops, topical antibiotic drops, and ophthalmology reevaluation within 24 hr (Fusco et al., 2019). Patients with corneal abrasions from contact lens should be seen the next day and be treated with fluoroquinolone topical antibiotics (Gilani et al., 2017).
Providing patients with topical anesthetics for pain relief at discharge, such as tetracaine, is controversial. One systematic review found that brief use of topical anesthetics does not impair corneal healing if used for 24 hours or less (Puls et al., 2015). However, another review cited this practice is not without risks because use may mask a worsening condition that could lead to possible permanent visual impairment (Fraser et al., 2019). Use of prophylactic topical antibiotics is also controversial for management of corneal/scleral abrasions. One systematic review found that topical antibiotics did not reduce infection or accelerate healing when compared with a placebo (Algarni et al., 2022). Eye patches for corneal abrasions are not recommended because they have not been found to improve corneal healing or reduce pain (Lim et al., 2016).
Ocular Burns
Ocular exposure to chemical or biologic agents requires rapid decontamination with copious irrigation using water, saline, or lactated Ringer's (LR) until the normal eye pH returns (approximately 7.5) (Slovin, 2015). LR is the preferred irrigation solution because it is closest to the pH of the eye and is less likely to cause corneal edema and endothelial damage than either tap water or normal saline (Rihawl et al., 2006). However, if rapid irrigation is needed, use whatever solution is available.
Patients who have been exposed to riot control substances (tear gas) will need body decontamination before entering the clinical area for eye irrigation. Although referred to as tear gas, riot control agents are aerosolized dry particles that burn and irritate the eye and respiratory mucosa. These particles adhere to clothing as well as the skin. To avoid provider exposure and contamination, patients exposed to these agents should carefully remove clothing outside of the care setting and wash the skin before being evaluated because the particles will continue to aerosolize if decontamination is not performed (Rothenberg et al., 2016). Visual acuity should be obtained following decontamination and eye irrigation.
Patients with corneal burns require tetanus prophylaxis, analgesic medication, topical antibiotics, and next-day ophthalmologic follow-up (Soleimani & Naderan, 2020). Although corneal burns are typically mild, all chemical burns require emergent irrigation and ophthalmologic management because alkaline agents can cause devastating damage with complications to internal structures that can even occur following initial treatment (Soleimani & Naderan, 2020).
Most chemical burns result from alkaline agents, such as ammonia, found in fertilizers and household and industrial cleaning agents (Soleimani & Naderan, 2020). Alkaline substances cause liquification necrosis of tissues resulting in severe damage that may require surgery to manage the structural, functional, and cosmetic effects (Soleimani & Naderan, 2020). In contrast, acid burns, such as sulfuric acid found in batteries or industrial agents, cause a coagulation necrosis that, unlike alkaline agents, prevents penetration to deeper structures (Soleimani & Naderan, 2020). The Roper-Hall and Duas Classification systems are used to grade injuries and predict outcomes resulting from chemical burns. The most severe physical examination findings from ocular burns include opacification of the cornea that obscures the iris and pupil. Table 7 shows components of the Roper-Hall Burn Classification system with predicted prognoses based on findings.
Fireworks-related ocular injuries may cause ocular burns, but they can also result in superficial and penetrating ocular foreign bodies, conjunctival irritation, and globe rupture (Shiuey et al., 2020). Bottle rockets are associated with the most severe injuries, and young White males are most frequently affected (Shiuey et al., 2020). Ocular burns can also occur from welding when protective eye shields are not used properly (Yan et al., 2022).
Blunt Eye Trauma and Penetrating Foreign Bodies
Penetrating high-velocity foreign bodies can result from hammering, metal cutting, chiseling, or from firearms. These injuries can often damage the posterior structures of the eye including vitreous detachment, retinal hemorrhage, tears and detachment, or globe rupture resulting in permanent vision loss (Gupta & Tripathy, 2023). A rapidly obtained CT scan of the orbit is needed to accurately evaluate these injuries with emergent ophthalmology referral for management.
Patients with traumatic hyphemas from blunt force trauma also require an orbital CT to evaluate for coexisting bony trauma and tonometry to assess IOP. Patients with hyphemas and increased IOP require emergent ophthalmology referral because they will require medical or possibly surgical treatment to reduce the risk of blindness (Chen & Fasiuddin, 2021). Until seen by ophthalmology, patients with hyphemas should rest with the head of the bed elevated to improve vision and help with resolution (Chen & Fasiuddin, 2021). Steroids and cycloplegic medications are frequently used to improve comfort and reduce inflammation (Chen & Fasiuddin, 2021).
Ocular Trauma Red Flags
In summary, red flags in orbital/ocular trauma include fractures, acute vision loss, abnormal pupillary response or shape, large hyphemas, globe rupture, enucleation, penetrating foreign bodies, proptosis, and complex lid lacerations. These conditions all require emergent ophthalmology consultation. Proptosis, resulting from blunt force trauma, suggests a retrobulbar hemorrhage or orbital compartment syndrome. Management of this condition requires an emergent lateral canthectomy to prevent blindness (Park et al., 2021). Orbital compartment syndrome may also entrap the eye muscles causing abnormal extraocular movements.
Red Eye
The differential diagnoses of red eye presentations range from infectious etiologies to environmental irritants, trauma, and acute narrow-angle glaucoma. Table 8 summarizes the key history questions for red eye presentations.
Table 9 shows the key physical examination components to include in the assessment.
Table 10 summarizes risk factors for emergent red eye conditions.
Table 11 summarizes the physical examination findings, complications, and management of urgent and emergent red eye conditions.
All patients presenting with a painful red eye should be examined after anesthetizing the eye and administering fluorescein stain followed by a slit lamp assessment to evaluate the cornea, retina, and posterior ocular structures. Administration of topical eye anesthetics generally reduces pain from a corneal lesion or abrasion; however, persistent or severe pain associated with photophobia suggests a more serious etiology such as bacterial keratitis, episcleritis, uveitis, or acute narrow-angle glaucoma (Gilani et al., 2017). Fluorescein stain will reveal corneal defects and lesions including the dendritic appearing-lesion associated with herpetic keratitis. Patients presenting with papulovesicular herpetic facial lesions in the absence of an eye complaint must have a full eye examination to avoid missing herpetic keratitis, which if untreated can cause permanent eye impairment. Patients presenting with corneal ulcers secondary to contact lens use should be treated with fluoroquinolone medications with next-day ophthalmology follow-up because these lesions can cause corneal scaring and may progress to bacterial keratitis or endophthalmitis, which is an infection of the internal structures of the eye (McSwigen et al., 2022).
Differentiating between episcleritis, or inflammation of the tissue between the sclera and conjunctiva, and scleritis, that occurs from autoimmune disease, is difficult and requires urgent ophthalmologic referral and evaluation. Episcleritis is managed with administration of topical phenylephrine drops, oral anti-inflammatory medications, and lubricating eye drops, whereas scleritis requires a rheumatologic workup and treatment for the underlying condition with immunosuppressive or biologic agents to reduce the risk of permanent eye damage (Gilani et al., 2017; Tarff & Behrens, 2017).
Orbital cellulitis is considered an ocular emergency because it can rapidly progress to encephalitis or to proptosis. A CT scan of the orbits will confirm the diagnosis. Patients with orbital cellulitis require hospitalization and parenteral broad-spectrum antibiotics (McSwigen et al., 2022).
Acute narrow-angle glaucoma is also an emergent condition. Patients presenting with acute narrow-angle glaucoma will have a rapid onset of intense unilateral eye pain, blurred vision, a fixed dilated pupil, nausea and vomiting, and IOPs greater than 30 mmHg. This condition is emergently treated with topical timolol 0.5% and pilocarpine 2% and oral or intravenous (IV) acetazolamide 500 mg to reduce initial pressures followed by emergent ophthalmology referral for laser iridectomy (McSwigen et al., 2022).
Red Flags for Red Eye Presentations
Severe pain with photophobia can be a sign of acute narrow-angle glaucoma, penetrating foreign body, severe infection, or retrobulbar hemorrhage. Vision loss or visual changes associated with a red eye may indicate posterior structure hemorrhage, retinal detachment, or infection. Pupillary abnormalities can indicate increased IOP or penetrating eye trauma. An IOP of 30 or more is indicative of acute narrow-angle glaucoma and need for emergent referral. An IOP between 21 and 30 requires urgent (within 24 hr) ophthalmology evaluation. Proptosis associated with a red eye suggests orbital compartment syndrome, retrobulbar hemorrhage, or a space-occupying lesion, all of which require immediate ophthalmologic referral or emergent lateral canthectomy in the ED.
Acute Vision Loss
Acute vision loss can be terrifying to patients and challenging to providers, as etiologies range from optic to neurologic causes. Acute vision loss can also occur from ocular trauma and in red eye conditions. Visual disturbances and loss can be a sequela of chronic conditions such as macular degeneration and diabetes, autoimmune diseases including Behcet disease or rheumatoid arthritis, multiple sclerosis, or may occur secondary to acute cerebral ischemia or as an associated symptom of migraine headache. Therefore, obtaining a detailed medical history is the first step in differentiating whether the vision loss is due to an optic or neurologic cause because the workup and management will differ significantly.
Any patient with a suspected neurologic etiology will need a thorough neurologic workup including CT and contrast magnetic resonance imaging (MRI) of the neck and brain to assess for thromboemboli, carotid stenosis, or cerebral ischemia (Graves & Galetta, 2012; Mac Grory et al., 2021; Tadi et al., 2022). Optic etiologies of acute vision loss include retinal detachment or vision loss secondary to infection, uveitis, iritis, acute narrow-angle glaucoma, and ocular trauma. Table 12 lists the key history questions for patients experiencing acute vision loss to narrow the diagnosis and expedite management.
Table 13 summarizes the acute vision loss eye examination.
Table 14 summarizes emergent optic and neurologic causes of acute vision loss with management strategies.
Perform the swinging flashlight test for all patients presenting with vision loss to differentiate optic nerve neuropathy from neurologic and other ocular causes. Visual field testing is also an important aspect of checking optic nerve function in acute vision loss because optic nerve disorders can occur anywhere along the optic nerve pathway. Appropriate management of a patient with a suspected optic nerve disorder requires urgent consultation with a neuro-ophthalmologist along with MRI of the orbits and brain to rule out other neurologic or optic nerve pathway disorders (Graves & Galetta, 2012).
Adult patients experiencing amaurosis fugax that presents as a transient, painless, monocular visual loss need a CT of the brain to rule out acute cerebral ischemia, along with a neurology consultation, and MRI and angiography of the brain and neck to assess for risk of hemispheric stroke from carotid emboli or stenosis (Tadi et al., 2022). Carotid artery occlusion can also cause hypoperfusion of retinal circulation and transient optic nerve and retinal ischemia (Tadi et al., 2022).
Patients with acute sudden, unilateral, painless vision loss is consistent with central retinal artery occlusion and retinal vein occlusion, which are optic causes of acute vision loss. However, these patients will also require admission and a thorough neurologic workup due to an increased risk of having an acute cerebral ischemic stroke (Mac Grory et al., 2021; Tadi et al., 2022). In fact, central retinal artery occlusion is considered a type of stroke (Tadi et al., 2022). Management of central retinal vein occlusion includes laser photocoagulation to reduce macular edema and improve revascularization of the retina and treatment with systemic corticosteroids to reduce inflammation (Rehak & Wiedemann, 2010).
Central retinal vein occlusion is also an emergent condition that occurs in older adults with a history of vascular disease or diabetes. Ocular findings on examination include tortuous prominent retinal vessels, cotton wool spots, and retinal and macular edema. Management of this condition includes laser coagulation to reduce macular edema, which if untreated can lead to permanent vision loss (Rehak & Wiedemann, 2010).
Older adults and those with cardiovascular conditions are at a higher risk for neurologic causes of acute vision loss including giant cell/temporal arteritis and autoimmune conditions. These conditions require emergent CT or MRI of the brain, diagnostic testing of inflammatory markers, and consultation with neuro-ophthalmology, rheumatology, and neurology (Graves & Galetta, 2012; Mac Grory et al., 2021; Maz et al., 2021; Tadi et al., 2022). Confirmation of giant cell arteritis requires a temporal artery biopsy and treatment with oral corticosteroids (Maz, et al., 2021).
Patients with a history of severe myopia, recent eye surgery, or trauma are at higher risk of retinal detachment (Kwok et al., 2020). Retinal detachment is usually painless and may cause progressive or abrupt vision loss with patients often describing seeing a black curtain obscuring one or more visual fields (Kwok et al., 2020). Management of retinal detachment includes emergent ophthalmology referral for laser coagulation to stop the vitreous leak and repair the tear to prevent permanent vision loss (Graves & Galetta, 2012).
Other causes of progressive, painless, nonurgent, optic-related vision loss include macular degeneration and cataracts that may be noted on the eye examination. Cataracts are viewed as lens opacities seen on funduscopic or slit lamp examination. Macular degeneration causes a progressive, painless, central vision loss resulting from neovascular changes and cellular debris deposits or drusen, within the retina. These changes will be visible on funduscopic or slit lamp examination.
One cause of painful, acute, optic-related vision loss is retinal hemorrhage, a sequela of diabetic retinopathy. On examination these patients may have a dull red reflex and will require tonometry to differentiate this condition from acute narrow-angle glaucoma. Management of retinal hemorrhage requires emergent referral to reduce the risk of acute glaucoma and permanent vision loss. Treatment includes vitrectomy or laser coagulation to remove clots and stop bleeding (Shaikh et al., 2023).
Neurologic causes of vision loss associated with headache may indicate an acute cerebral stroke, acute narrow-angle glaucoma, migraine headache, or pseudotumor cerebri. Vision loss associated with migraine headache will generally be diagnosed based on the history of the condition, associated symptoms including aura or prodrome, triggers, nausea/vomiting, photophobia/phonophobia, unilateral throbbing pain, and normal brain imaging. Treatment of the headache will improve visual symptoms.
Pseudotumor cerebri, also referred to as idiopathic intracranial hypertension, involves the dysregulation of cerebrospinal fluid circulation that causes increased intracranial pressure. This condition can cause transient visual changes, including diplopia, with associated headache, back and neck pain, tinnitus, nausea, and papilledema. Risk factors for pseudotumor cerebri include female gender, polycystic ovarian disease, and obesity. Physical examination findings will show papilledema with normal neurologic findings. The workup for this condition includes a brain MRI or contrast-enhanced CT and lumbar puncture with opening pressure readings. The diagnosis is based on normal imaging and elevated opening cerebrospinal fluid pressures with normal fluid analysis. Treatment consists of weight loss and oral acetazolamide to reduce intercranial pressures (Wang et al., 2022).
Another neurologic cause of vision loss and visual disturbances is multiple sclerosis. Suspect multiple sclerosis in younger female patients who present with a history of painless, progressive unilateral or bilateral vision loss (Graves & Galetta, 2012). These patients need a neurologic workup including an MRI of the brain and spine. Positive findings include hyperintense focal areas within the white matter tracts of the cerebral hemispheres, infratentorial region, or spinal cord (Wilson & Islam, 2019). Lumbar puncture cerebrospinal fluid analysis will show increased protein levels (Graves & Galetta, 2012).
CONCLUSION
In conclusion, a review of eye anatomy and physiology and a systematic approach to performing an eye examination (i.e., external, internal, and slit lamp) were presented and discussed. Selected common nonemergent and emergent eye complaints were reviewed. For each complaint, essential history questions, examination techniques, differentials to consider, and the ED management of each of these conditions were presented. Table 15 shows a comprehensive ophthalmology documentation/dictation form for use in clinical practice.
Emergent eye conditions must be carefully and quickly managed to prevent blindness and disability. Many conditions leading to blindness and disability can easily be prevented with use of safety glasses to avoid trauma, burns, and chemical exposures. Sports-related ocular trauma can also be prevented with use of safety glasses, which is especially important for patients with myopia who are at higher risk for retinal detachment following blunt force injury. Patients should also be cautioned to use safety glasses when handling fireworks, when welding, and when using power tools. Patients planning to participate in events where they may be exposed to riot control chemicals or bullets should be counseled not to wear contact lens and to consider wearing safety glasses and masks to avoid injury.
Nurse practitioners (NPs) are well positioned to educate patients about eye injury prevention and to encourage treatment adherence and follow-up recommendations for newly diagnosed eye conditions that if poorly managed can lead to loss of visual function or blindness. NPs must strongly advocate for patients with ocular conditions that carry a high risk for adverse visual outcomes when consulting with ophthalmologists and other specialists and when arranging timely referral and/or admission.
REFERENCES