Angle closure is defined as the apposition of iris to the trabecular meshwork, which results in increased intraocular pressure (IOP). In acute angle closure (AAC), the process occurs suddenly with a dramatic onset of symptoms, including blurred vision, red eye, pain, headache, and nausea and vomiting. The sudden and severe IOP elevation can quickly damage the optic nerve, resulting in acute angle-closure glaucoma (AACG).
AAC is a true ophthalmic emergency, and a delay in treatment can result in blindness. While immediate treatment can sometimes minimize the amount of visual loss, the best treatment is to stop its occurrence in susceptible individuals.[1, 2, 3, 4]
Primary angle-closure glaucoma (AAC) is uncommon in younger individuals but becomes more prevalent with age as the lens enlarges and potentially pushes the iris forward, narrowing the angle between the iris and the cornea.[5] This condition is influenced by several risk factors including genetic predisposition, advanced age, and ethnicity, with increased incidence noted in Asian and Inuit populations, and decreased incidence in European and African populations.
Clinically, narrow angles reduce the space between the iris at the pupil and the lens. During mid-dilation of the pupil, this space is minimized, facilitating contact between the iris and lens.[5] This contact impedes the flow of aqueous humor from the posterior to the anterior chamber, leading to pupillary block. Subsequent aqueous production by the ciliary body forces the peripheral iris to bow forward (iris bombe), closing the angle and obstructing aqueous outflow. This results in a rapid and significant elevation of intraocular pressure (IOP), often exceeding 40 mm Hg, which can swiftly lead to irreversible optic nerve damage and acute angle-closure glaucoma.
Acute angle-closure glaucoma demands immediate medical intervention to prevent rapid and irreversible vision loss. Intermittent angle-closure glaucoma may resolve temporarily, often after the patient has been supine, whereas chronic angle-closure glaucoma progresses slowly as the angle continues to narrow, leading to gradual scarring and increased IOP.
Pupillary dilation (mydriasis) can exacerbate angle narrowing and precipitate acute angle-closure glaucoma in individuals with predisposed narrow angles.[5] Secondary angle-closure glaucomas arise from mechanical obstructions related to other ophthalmic conditions such as proliferative diabetic retinopathy, ischemic central vein occlusion, uveitis, or epithelial down-growth, where neovascular membranes or inflammatory scarring pull the iris into the angle, worsening the closure.
Additional factors contributing to primary angle closure include plateau iris configuration, certain medications, increased iris thickness, dilation-induced iris volume increase, hyperopia, and lens thickening in phacomorphic angle closure. These clinical observations underscore the importance of vigilant monitoring and management in patients at risk for angle-closure glaucoma.
In the United States, an estimated 3 million individuals are affected by glaucoma.
Globally, glaucoma ranks as the second leading cause of blindness. The worldwide prevalence of acute angle-closure glaucoma (AACG) is approximately 0.6%, with variations observed across different ethnic groups.[6] AACG prevalence increases with age, particularly among individuals over 40 years. It is more prevalent among Inuit and Asian populations, less so among Whites, and is least common among Blacks. Although AACG constitutes a minor fraction of all glaucoma cases globally (0.6%, equating to roughly 17 million individuals), it represents a substantial proportion of cases in Eastern and Southeast Asian populations, affecting about 12 million individuals. AACG is more frequently diagnosed in women and those with hyperopia. A family history of AAC or prior occurrence of AAC in one eye also significantly increases the risk.[2, 6, 7]
The prognosis is favorable with early detection and treatment. The best way to prevent loss of vision is to treat susceptible individuals prior to AAC.
AAC is a medical emergency that must be treated immediately. Even with immediate treatment, AAC may result in vision loss. The best method for preventing vision loss due to AAC is prophylactic treatment in patients with susceptible anatomy.
Patients need to promptly seek an eye care professional if symptoms (pain, decreased vision, headache, and vomiting) suggest AAC.
In acute angle closure (AAC), the intraocular pressure (IOP) rises rapidly, and the patient may present with dramatic symptoms, including the following[5] :
Some patients experience intermittent episodes of partial angle closure and relatively elevated IOP without experiencing a frank attack of AAC. These patients may report incidents of mild pain with slightly blurred vision or may report seeing haloes around lights. Some may be completely asymptomatic. Symptoms can resolve spontaneously if the angle reopens on its own.
A complete ophthalmic examination should be conducted in patients who present with suspected AAC. This examination should emphasize vision, pupil, gonioscopy, tonometry, slit-lamp examination, and optic nerve evaluation:
If previous episodes of angle closure have occurred, the following may be visible:
Pupillary block is considered to be the most common cause of AAC. Normally, aqueous humor is made by the ciliary body and flows through the pupil to the anterior chamber, where it drains out of the eye through the trabecular meshwork and Schlemm's canal. If contact occurs between the lens and the iris, aqueous humor accumulates behind the pupil, increasing posterior chamber pressure and forcing the peripheral iris to shift forward.
The trabecular meshwork is located between the iris and cornea, and the two structures form an angle that is normally 40°. Persons with susceptible anatomy have a narrow occludable angle, usually of less than 20°. When the iris is pushed forward by the aqueous humor in a narrow occludable angle, it becomes apposed to the trabecular meshwork. This blockage causes accumulation of aqueous humor in the anterior chamber and an acute rise in IOP.
Not all individuals with narrow occludable angle develop AAC, and mechanisms other than pupillary block play a role in development of AAC.
Plateau iris is a condition in which the iris is inserted more anteriorly into the ciliary body and the periphery of the iris is flat. The angle is narrow owing to the anterior iris insertion, and the flat iris bunches up to obstruct the angle when the eye is dilated.[8, 9]
Several medications have been implicated in causing acute ACC by producing swelling in the ciliary body and forward movement of the iris. Sulfa-derivative medications, including acetazolamide, sulfamethoxazole, hydrochlorothiazide, and antiepileptic medication topiramate have been reported to cause acute attacks.[10, 11]
A retrospective review of case notes, which cross-referenced hospital and screening program records, identified three cases of angle closure glaucoma within 14 days following retinopathy screening involving pharmacologic mydriasis.[12] The incidence within the screening program was calculated as 1 in 31,755 patients dilated, or 0.75 patients per year. This rate of angle closure, a rare complication of mydriasis in diabetic retinopathy screening, is lower than other studies have reported.
For example, the Rotterdam Study noted an incidence of 3 in 10,000.[13] In contrast, the Baltimore Eye Survey found no angle closure episodes among 4,870 dilated subjects, attributing this to the exclusion of those with potentially occludable angles.[14] A systematic review from 1933 to 1999 also reported no angle closure cases from tropicamide drops alone, suggesting their safety. However, the study by O'Donnell et al[12] indicates that tropicamide alone can induce angle closure, underscoring the need for clear patient instructions on accessing emergency ophthalmic care after dilation to prevent vision loss.
Persons of Asian descent have thicker irides, and increased iris thickness is associated with angle closure.[15, 16]
Pupillary dilation normally results in loss of iris volume, but this volume decrease is less in eyes that have had AAC; some of these eyes actually showed an increase in iris volume.[17, 18]
Individuals with hyperopia have smaller eyes, and the diameter of the eye (axial length) is shorter. The intraocular structures are spaced closer together. These patients are more likely to have shallow anterior chambers and narrow occludable angles.[1, 2, 3]
Lens volume increases with age and can decrease the amount of space in the anterior chamber via mass effect.[1, 2, 3]
The diagnosis of acute angle-closure glaucoma is established through clinical evaluation and the measurement of intraocular pressure (IOP).[5] Performing gonioscopy on the affected eye may be impeded by corneal clouding and fragile corneal epithelium. Nonetheless, an examination of the fellow eye typically reveals a narrow or occludable angle. A wide angle in the unaffected eye may prompt consideration of diagnoses other than primary angle-closure glaucoma. The identification of iris bombe, which manifests as an anterior bowing of the iris between the angle and the pupil, is indicative of a pupillary block mechanism.
For chronic angle-closure glaucoma, the diagnosis is confirmed by the detection of peripheral anterior synechiae through gonioscopy, accompanied by characteristic changes in the optic nerve and visual field that align with those observed in primary open-angle glaucoma.
Prior to the administration or prescription of mydriatic eye drops—which can induce acute narrow-angle glaucoma in at-risk patients—the depth of the anterior chamber should be evaluated.[5] If gonioscopy is not feasible, this assessment can be alternatively performed using a slit lamp or a penlight. By placing the penlight adjacent to the temporal side of the eye and aligning the light beam parallel to the iris, the presence of a shadow on the nasal iris indicates a narrow angle, suggesting that the temporal iris is protruding forward and obstructing the light path.
These imaging techniques can be used to visualize the angle and surrounding structures. They can provide objective and quantitative measurements to document changes to the angle before and after treatment. However, clinical assessment and the use of gonioscopy may be more practical and applicable if a patient has acute angle closure (AAC).[19]
The anterior chamber angle cannot be visualized through a slit lamp because the light reflected from the angle is reflected back into the eye. Gonioscopy is performed by applying a gonioscope onto the cornea after administration of a topical anesthetic. Four mirror lenses are useful to diagnose and, possibly, to break the block by applying pressure. It allows the clinician to quickly and accurately assess the angle without expensive machinery. It is an essential component of an ophthalmic examination in patients with suspected narrow angle and in patients with AAC.
Immediate treatment initiation is crucial in acute angle-closure glaucoma due to the rapid and permanent potential for vision loss.[5] The therapeutic approach involves the simultaneous administration of multiple medications. The recommended regimen includes:
The response to treatment is monitored by measuring intraocular pressure (IOP). Miotics, such as pilocarpine, are generally ineffective when IOP exceeds 40 or 50 mm Hg due to anoxia affecting the pupillary sphincter.
The definitive treatment for acute angle-closure glaucoma is laser peripheral iridotomy (LPI), which creates an alternative pathway for aqueous fluid to move from the posterior to the anterior chamber, thereby alleviating the pupillary block. LPI is performed as soon as the cornea becomes clear and inflammation is reduced, which may occur within hours of effective IOP reduction or may take 1 to 2 days. Given the high risk (80%) of a similar acute episode occurring in the contralateral eye, LPI is typically performed on both eyes.
Patients who are unable to cooperate with surgery include the following:
The risk for complications from LPI is minimal relative to its benefits, although some patients may experience glare, which can be a significant nuisance.
Topical and oral medications are used to lower the IOP. Lowering the IOP minimizes damage to the optic nerve and allows the ocular tissue to be compressed.
If the IOP cannot be lowered sufficiently, an anterior chamber paracentesis (needle insertion) can be performed. This technique can be useful because it provides immediate relief to the distressed patient and facilitates tolerance of subsequent treatment. A consent form should be obtained for the risks (eg, inadvertent lens puncture, decompression retinopathy) and benefits prior to the procedure.
Compression gonioscopy then is performed by using a gonioscope to push down on the cornea and then easing up on it. The process is done repeatedly, and the force generated is translated intraocularly to break the contact between the iris and the lens (pupillary block) and apposition of the iris to the trabecular meshwork (angle closure). This temporarily restores the outflow of aqueous humor and normalizes the IOP.
Patients also may be placed in a supine position to allow the lens to move away from the anterior chamber to help restore the flow of aqueous humor.
When the eye is in AAC, the visualization into the anterior chamber is poor. Medications for eye pressure and inflammation are used to help clear up the cornea, to reduce intraocular inflammation, and to decrease iris edema. It is preferable to perform laser iridotomy when the condition can be optimized. If laser iridotomy cannot be performed and AAC continues, surgical iridectomy is indicated.
The primary treatment for pupillary-block acute angle-closure glaucoma (ACG) is laser iridotomy. This procedure involves using an argon and/or Nd laser to create a small hole in the iris, allowing the trapped aqueous humor in the posterior chamber to flow into the anterior chamber and reach the trabecular meshwork. This flow reduces the pressure behind the iris, enabling it to return to its normal position, thus opening the anterior chamber angle and alleviating the blockage of the trabecular meshwork. Laser iridotomy not only resolves the current blockage but also prevents future incidents of pupillary block and acute angle-closure.
The procedure is facilitated by the use of a contact lens, specifically either an Abraham or Wise lens.[20] The Abraham lens, which is more commonly used, is a modified Goldmann-type fundus lens[21] with a flat glass plate[20] and a +66 diopter planoconvex button set into an off-center 8-mm hole. The Wise lens, offering higher magnification, features a +102 diopter button. Topical anesthesia, typically proparacaine 0.5%, is sufficient for patient comfort during the laser peripheral iridotomy (LPI), which is performed while the patient is positioned at the laser table, similar to an examination at the slit lamp.
If the cornea is extremely cloudy or the iris is too thick and an opening cannot be created using laser, incisional peripheral iridectomy can be performed in the operating room.
Argon laser may be used to create burns in the peripheral iris and to cause tissue contraction. This reduces iris thickness and creates additional space between the iris and the trabecular meshwork. Traditionally, this technique is indicated to prevent AAC in plateau iris and nanophthalmos but also can be used to augment the effect of iridotomy or iridectomy, if needed.[22, 23]
If the angle continues to be narrow and occludable after laser iridotomy and iridoplasty, especially in an older patient, cataract surgery is indicated to remove the cataract and its mass effect on the angle. If the patient has both a narrow occludable angle and a visually significant cataract (blurry vision due to cataract), cataract surgery is the treatment of choice. It opens the angle and improves vision.[24] Even without significant cataract, the Effectiveness of Early Lens Extraction for the Treatment of Primary Angle-closure Glaucoma (EAGLE) study, conducted in Asia, showed that clear lens extraction may be more efficacious and cost effective than laser iridotomy. The authors suggested that the crystalline lens may play a larger role in the mechanism of angle closure than previously thought and that early lens extraction can be considered as an option for first-line treatment.[25]
If the patient undergoes cataract surgery and there are bands of adhesion between the iris and the trabecular meshwork, the bands may be pulled apart during surgery to restore the flow of aqueous humor through the trabecular meshwork.
If permanent adhesions between the iris and trabecular meshwork have formed after AAC and IOP cannot be normalized with the other methods, traditional glaucoma surgery, such as a trabeculectomy or tube shunt, may be indicated.
Some of the potential complications of AAC include the following:
In most cases, the fellow eye has an occludable angle, and laser iridotomy should be performed as soon as possible.
The patient must be monitored closely after the initial acute angle closure (AAC) to ensure the following:
Patients in AAC need to be treated until the IOP normalizes. IOP can increase after laser iridotomy, and the IOP should be checked 30-60 minutes after the treatment prior to releasing the patient.
The medical therapy for acute angle closure glaucoma (AACG) is directed toward preparing the patient for surgical treatment. IOP must be returned to normal, and the cornea must be cleared before a definitive procedure can be undertaken. In AAC, several drugs from different classes are used simultaneously to accelerate and maximize their pressure-lowering effects.
Clinical Context: Selective alpha2-receptor that reduces aqueous humor formation and possibly increases uveoscleral outflow.
Clinical Context: Potent alpha-adrenergic agent selective for alpha2-receptors with minimal cross-reactivity to alpha1-receptors. Reduces IOP whether or not accompanied by glaucoma. Selective alpha-adrenergic agonist without significant local anesthetic activity. Has minimal cardiovascular effect.
Topical adrenergic agonists, or sympathomimetics, decrease aqueous production and reduce resistance to aqueous outflow. Adverse effects include dry mouth and hypersensitivity.
Clinical Context: Nonselective beta-adrenergic blocking agent that lowers IOP by reducing aqueous humor production
Clinical Context: Selectively blocks beta1-adrenergic receptors with little or no effect on beta2-receptors. Reduces IOP by reducing production of aqueous humor.
Clinical Context: May reduce elevated and normal IOP, with or without glaucoma, by reducing production of aqueous humor.
Topical beta-adrenergic receptor antagonists decrease aqueous humor production by the ciliary body. Adverse effects of the beta-blockers are due to systemic absorption of the drug and include decreased cardiac output and bronchial constriction. In susceptible patients, this may cause bronchospasm, bradycardia, heart block, or hypotension. Pulse rate and blood pressure should be monitored in patients receiving topical beta-blocker therapy, and punctal occlusion may be performed after administration of the drops.
Clinical Context: A naturally occurring alkaloid, pilocarpine mimics muscarinic effects of acetylcholine at postganglionic parasympathetic nerves. Directly stimulates cholinergic receptors in the eye, decreasing resistance to aqueous humor outflow.
Instillation frequency and concentration are determined by patient's response. Individuals with heavily pigmented irides may require higher strengths. If other glaucoma medication is also being used, at bedtime, use gtt at least 5 min before gel. May use alone, or in combination with other miotics, beta-adrenergic blocking agents, epinephrine, carbonic anhydrase inhibitors, or hyperosmotic agents to decrease IOP.
Contract ciliary muscle, tightening the trabecular meshwork and allowing increased outflow of the aqueous. Miosis results from action of these drugs on pupillary sphincter. Adverse effects include brow ache, induced myopia, and decreased vision in low light.
Clinical Context: Inhibits enzyme carbonic anhydrase, reducing rate of aqueous humor formation, which, in turn, reduces IOP. Used for adjunctive treatment of chronic simple (open-angle) glaucoma and secondary glaucoma and preoperatively in acute ACG when delay of surgery desired to lower IOP.
Clinical Context: Reduces aqueous humor formation by inhibiting enzyme carbonic anhydrase, which results in decreased IOP.
Clinical Context: Used concomitantly with other topical ophthalmic drug products to lower IOP. If more than one ophthalmic drug is being used, administer the drugs at least 10 min apart. Reversibly inhibits carbonic anhydrase, reducing hydrogen ion secretion at renal tubule and increases renal excretion of sodium, potassium bicarbonate, and water to decrease production of aqueous humor.
Clinical Context: Catalyzes reversible reaction involving hydration of carbon dioxide and dehydration of carbonic acid. May use concomitantly with other topical ophthalmic drug products to lower IOP. If more than one topical ophthalmic drug is being used, administer drugs at least 10 min apart.
Clinical Context: Carbonic anhydrase inhibitor that may decrease aqueous humor secretion, causing a decrease in IOP. Presumably slows bicarbonate ion formation with subsequent reduction in sodium and fluid transport.
Timolol is a nonselective beta-adrenergic receptor blocker that decreases IOP by decreasing aqueous humor secretion and may slightly increase outflow facility. Both agents administered together bid may result in additional IOP reduction compared with either component administered alone, but reduction is not as much as when dorzolamide tid and timolol bid are administered concomitantly.
Reduce secretion of aqueous humor by inhibiting carbonic anhydrase in ciliary body. In acute ACG, may be given systemically but are used topically in patients with refractory open-angle glaucoma. Topical formulations are less effective, and their duration of action is shorter than many other classes of drugs. Adverse effects of topical carbonic anhydrase inhibitors are relatively rare, but they include superficial punctate keratitis, acidosis, paresthesias, nausea, depression, and lassitude.
Clinical Context: Latanoprost may decrease IOP by increasing the outflow of aqueous humor. Patients should be informed about possible cosmetic effects to the eye/eyelashes, especially if uniocular therapy is to be initiated.
Clinical Context: This agent is a prostaglandin F2-alpha analog. It is a selective FP prostanoid receptor agonist that is believed to reduce IOP by increasing uveoscleral outflow. Travoprost ophthalmic solution is used to treat open-angle glaucoma and ocular hypertension.
Clinical Context: This agent is a prostamide analog with ocular hypotensive activity. It mimics the IOP-lowering activity of prostamides via the prostamide pathway. Bimatoprost ophthalmic solution is used to reduce IOP in open-angle glaucoma and ocular hypertension.
Clinical Context: Metabolizes rapidly in the eye to latanoprost acid, an F2 alpha prostaglandin analog. May increase the outflow of aqueous humor through the trabecular meshwork and uveoscleral route, which may in turn reduce intraocular pressure.
Increase uveoscleral outflow of the aqueous. One mechanism of action may be through induction of metalloproteinases in ciliary body, which breaks down extracellular matrix, thereby reducing resistance to outflow through ciliary body.
Clinical Context: May reduce intraocular pressure by increasing the outflow of aqueous humor through the trabecular meshwork route.
These agents may increase aqueous outflow by reversing structural and functional damage at the trabecular meshwork. The vasodilatory effect of rho kinase inhibitors may also reduce episcleral venous pressure.