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Miosis

Miosis, also known as myosis, is the excessive constriction of the pupil in the eye, resulting in a diameter typically smaller than 2 millimeters. It is the opposite of mydriasis (pupil dilation). The term derives from the Greek word "muein," meaning "to close the eyes."^[1] This may occur as a normal physiological response to bright light or near vision, or as a symptom of underlying pathology.^[2] This constriction is mediated by the parasympathetic nervous system, which stimulates the iris sphincter muscle to contract, while the sympathetic nervous system's influence on the iris dilator muscle diminishes, maintaining a balance that regulates light entry to the retina.^[3] In healthy individuals, pupil size normally ranges from 2 to 4 millimeters in bright light and 4 to 8 millimeters in dim conditions; persistent miosis, especially bilateral failure to dilate in low light or unilateral miosis (anisocoria), often signals an abnormality.^[4] Physiologically, miosis serves to protect the retina from excessive light and improve depth of focus, but it can also arise from various causes, including exposure to bright light or aging, as pupils naturally narrow after age 25.^[4] Pathological miosis may result from conditions such as Horner's syndrome (featuring unilateral miosis and ptosis), anterior uveitis, or neurological issues like stroke or cluster headaches.^[2]^[4] Common pharmacological causes include opioids and miotic eye drops like pilocarpine.^[3]^[2] Miosis warrants medical evaluation to identify and address underlying causes.

Overview and Definition

Definition

Miosis refers to the excessive constriction of the pupil, defined as a reduction in pupil diameter to less than 2 mm, often occurring in response to light or other stimuli.^[5] This physiological response is primarily mediated by the parasympathetic nervous system, which promotes pupil narrowing to regulate the amount of light entering the eye.^[6] Anatomically, miosis results from the contraction of the iris sphincter muscle, a circular smooth muscle in the iris that encircles the pupil. This muscle is innervated by parasympathetic fibers from the oculomotor nerve (cranial nerve III), originating from the Edinger-Westphal nucleus in the midbrain.^[7] The term "miosis" originates from the Ancient Greek word múein, meaning "to close the eyes," reflecting the shutting or narrowing action of the pupil.^[8] In contrast to mydriasis, which involves pupil dilation, miosis represents the opposite extreme of pupillary response. Under normal conditions, pupil size varies between 2 and 4 mm in bright light and expands to 4 to 8 mm in dim light to optimize visual acuity.^[9] Pupillometry, an objective measurement technique using infrared videography or digital imaging, is commonly used to quantify pupil diameter and evaluate the degree of miosis accurately.^[10] This process is integral to the pupillary light reflex, where light exposure triggers bilateral constriction.^[11]

Clinical Relevance

Miosis plays a crucial role in visual function by constricting the pupil to limit the amount of light entering the eye, thereby protecting the retina from excessive brightness and enhancing depth of field through the pinhole effect, which improves focus and acuity in well-lit environments.^[12] This adaptive mechanism optimizes image sharpness on the retina while minimizing spherical aberrations and glare, allowing for clearer near and distance vision under bright conditions.^[12] In health assessments, observing miosis provides clinicians with insights into autonomic nervous system balance and overall ocular integrity, serving as a diagnostic marker for evaluating neurological and ocular health.^[5] Abnormal or persistent miosis can lead to several complications, including blurred vision due to impaired focusing abilities, particularly when the pupil fails to dilate appropriately in response to changing light levels.^[13] It may also hinder low-light adaptation, resulting in reduced visual sensitivity and difficulty navigating dim environments, as less light reaches the retina.^[4] Furthermore, pathological miosis often signals underlying neurological issues, such as Horner's syndrome, stroke, or brain injury, where disruption of sympathetic innervation causes unilateral constriction and warrants urgent evaluation to address potential life-threatening conditions.^[14]^[2] Early observations in 19th-century ophthalmology linked miosis to parasympathetic activity, with French physiologist Claude Bernard confirming in 1851 that sectioning the cervical sympathetic chain induced pupil constriction, highlighting the antagonistic roles of sympathetic dilation and parasympathetic-mediated miosis in pupillary control.^[15] In aging populations, senile miosis—characterized by a progressive baseline pupil constriction—is a common physiological change that reduces retinal illuminance and contributes to diminished visual performance, affecting a substantial proportion of older adults and exacerbating conditions like presbyopia.^[16]^[17]

Physiology

Neural Control of Pupil Size

The neural control of pupil size is primarily mediated by the autonomic nervous system, with the parasympathetic division driving constriction (miosis) through the iris sphincter muscle and the sympathetic division promoting dilation (mydriasis) via the iris dilator muscle. This balance allows the pupil to adapt to varying light conditions, cognitive demands, and autonomic states. The parasympathetic pathway originates in the midbrain's Edinger-Westphal nucleus, a preganglionic parasympathetic center within the oculomotor complex.^[18] Preganglionic fibers from the Edinger-Westphal nucleus travel via the oculomotor nerve (cranial nerve III) to synapse in the ciliary ganglion located behind the eye. Postganglionic neurons then extend through the short ciliary nerves to innervate the circular sphincter pupillae muscle of the iris, inducing contraction and thus miosis. This pathway ensures precise control over pupillary constriction, with each Edinger-Westphal nucleus primarily influencing ipsilateral constriction while receiving bilateral inputs for coordinated response.^[18]^[19] In counterbalance, the sympathetic pathway provides inhibitory opposition to miosis by dilating the pupil. Sympathetic preganglionic neurons arise from the intermediolateral cell column of the spinal cord (T1-T2 levels) and synapse in the superior cervical ganglion. Postganglionic fibers then course along the internal carotid artery and reach the iris dilator pupillae muscle via long ciliary nerves, promoting radial dilation. Although essential for overall pupillary dynamics, this pathway plays a secondary role in miosis, as parasympathetic tone dominates constriction.^[20]^[21] The primary neurotransmitter for parasympathetic-mediated miosis is acetylcholine, released by postganglionic fibers to activate muscarinic M3 receptors on the iris sphincter muscle, triggering contraction. This cholinergic signaling ensures rapid and robust pupillary constriction. Central nervous system integration modulates these pathways: the pretectal olivary nucleus receives retinal afferents and projects bilaterally to the Edinger-Westphal nucleus to drive parasympathetic output, while hypothalamic regions, such as the paraventricular nucleus, provide descending inputs that influence both parasympathetic tone and sympathetic outflow for adaptive responses to arousal and circadian rhythms.^[22]^[18]^[23]

Pupillary Light Reflex

The pupillary light reflex, also known as the photomotor reflex, is an involuntary response that causes constriction (miosis) of the pupil in response to increased light intensity, protecting the retina from excessive illumination. This reflex arc begins with the afferent limb, where light stimulates retinal photoreceptors, primarily melanopsin-containing intrinsically photosensitive retinal ganglion cells, which transmit signals via the optic nerve (cranial nerve II) to the optic chiasm and then the optic tract. Fibers from the optic tract project to the olivary pretectal nucleus in the midbrain, which provides bilateral input to the Edinger-Westphal nuclei, ensuring coordinated response.^[19]^[18] The efferent limb of the reflex involves parasympathetic fibers originating from the Edinger-Westphal nuclei, traveling along the oculomotor nerve (cranial nerve III) to synapse in the ciliary ganglion. Postganglionic parasympathetic neurons then innervate the sphincter pupillae muscle of the iris, inducing miosis through contraction. This pathway results in both direct and consensual responses: illumination of one eye causes constriction of the ipsilateral pupil (direct response), while the contralateral pupil also constricts (consensual response) due to the bilateral projections from the pretectal nucleus to the Edinger-Westphal nuclei on both sides.^[19]^[18] The reflex exhibits a typical latency of 180-230 milliseconds from light onset to the start of constriction, with the response time shortening as light intensity increases; full constriction amplitude is reached in about 1 second, followed by adaptation where the pupil maintains a steady size in sustained light. In clinical settings, the swinging flashlight test evaluates the reflex by alternately directing a light beam between the two eyes every 2-3 seconds, observing for symmetric constriction in both pupils to confirm intact bilateral responses.^[24]^[19]

Causes

Physiological Causes

Miosis, or pupillary constriction, is a normal physiological response to increased light exposure through the pupillary light reflex, where light stimulates retinal photoreceptors, leading to activation of the iris sphincter muscle and resultant narrowing of the pupil to regulate the amount of light entering the eye. The degree of constriction is intensity-dependent, with brighter light eliciting faster and more pronounced miosis, typically occurring within approximately one second of stimulus onset.^[19] In near vision tasks, the convergence-accommodation reflex triggers miosis as part of the near triad, alongside eye convergence and lens accommodation, to optimize focus on close objects by increasing the depth of field and reducing spherical aberration. This synkinetic response involves parasympathetic innervation of the iris sphincter, resulting in pupillary narrowing that enhances visual acuity for tasks such as reading.^[25] Age-related changes contribute to senile miosis, characterized by a progressive reduction in resting pupil size in older adults, primarily due to decreased sympathetic tone in the iris dilator muscle, which becomes noticeable after approximately age 50 and leads to smaller baseline pupil diameters under dim conditions. This phenomenon arises from age-associated decline in noradrenergic innervation rather than loss of muscle sensitivity to norepinephrine.^[26]^[27] During sleep and in alignment with circadian rhythms, natural miosis occurs, particularly in deep non-REM stages, reflecting reduced arousal and parasympathetic dominance that minimizes pupil dilation and maintains constriction even in darkness. This sleep-associated constriction serves as a marker of low vigilance and varies diurnally, with smaller pupils during typical rest periods to support restorative physiological states.^[28]^[29]

Pathological Causes

Pathological causes of miosis encompass a range of neurological, ocular, systemic, and congenital conditions that disrupt normal pupillary dynamics, often through interruption of sympathetic innervation, parasympathetic overactivity, or structural iris abnormalities. These lead to abnormally constricted pupils that may be bilateral, unilateral, fixed, or poorly reactive, distinguishing them from physiological variations. In neurological disorders, Horner's syndrome results in unilateral miosis due to disruption of the oculosympathetic pathway, typically from lesions along the sympathetic chain, such as in the cervical region or brainstem.^[30] Pontine lesions, including strokes or hemorrhages, can cause bilateral pinpoint miosis by damaging descending sympathetic fibers while sparing or irritating parasympathetic pathways in the midbrain, leading to unopposed pupillary constriction.^[5] Ocular conditions frequently associated with miosis include anterior uveitis, where inflammatory spasms of the iris sphincter muscle cause pupillary constriction, often accompanied by irregular pupil shape due to posterior synechiae—adhesions between the iris and lens that fix the pupil in a miotic state.^[31] Similarly, iris adhesions (synechiae) from chronic inflammation can result in persistent miosis and secondary angle-closure glaucoma, where forward bowing of the iris exacerbates aqueous outflow obstruction. In such cases, the miotic pupil contributes to elevated intraocular pressure.^[32] In such cases, the miotic pupil contributes to elevated intraocular pressure. Systemic diseases like cluster headaches often present with ipsilateral miosis during attacks, reflecting autonomic dysfunction with sympathetic hypoactivity on the affected side.^[33] Organophosphate poisoning induces severe bilateral miosis through acetylcholinesterase inhibition, causing cholinergic excess that overstimulates the iris sphincter.^[34] Other systemic causes include infections such as rubella or mumps, which can lead to miosis through inflammatory effects on the ocular or neurological structures; autoimmune diseases like rheumatoid arthritis, potentially causing uveitis-related constriction; neurosyphilis, involving syphilitic inflammation of the iris or brainstem affecting pupillary control; and trauma, such as head injuries disrupting sympathetic pathways.^[2] Congenital factors, such as iris hypoplasia or microcoria, lead to fixed miosis from underdevelopment of the iris dilator muscle, resulting in pupils smaller than 2 mm that respond poorly to mydriatics.^[35] Recent studies post-2020 have identified emerging links between long COVID and altered pupillary responses, including cases of Horner's syndrome causing unilateral miosis due to post-viral autonomic neuropathy in some recovered patients.^[36]

Pharmacological Causes

Pharmacological causes of miosis primarily involve agents that enhance parasympathetic activity or directly stimulate cholinergic pathways in the iris sphincter muscle. Parasympathomimetic drugs, such as pilocarpine, act as muscarinic receptor agonists, leading to contraction of the pupillary sphincter and subsequent pupil constriction. Pilocarpine is commonly used in the treatment of glaucoma, where it induces miosis to facilitate aqueous humor outflow. The onset of miosis following topical application of 1% pilocarpine eye drops typically occurs within 10-30 minutes, with maximal effect achieved around 20-45 minutes and duration lasting several hours.^[37]^[38]^[39]^[40] Physostigmine, another parasympathomimetic agent, functions as a reversible cholinesterase inhibitor that increases acetylcholine levels at muscarinic receptors, thereby promoting miosis. It is employed to counteract anticholinergic-induced mydriasis, but in therapeutic or excessive doses, it directly causes pupillary constriction as part of its cholinergic effects. Intraperitoneal administration of physostigmine at doses of 0.1 mg/kg or higher in animal models induces miosis alongside other cholinergic symptoms.^[41]^[42] Opioids, including morphine and heroin, induce miosis through activation of mu-opioid receptors in the brainstem, particularly the Edinger-Westphal nucleus, which enhances parasympathetic outflow to the pupil. This results in the characteristic "pinpoint pupils" observed in opioid intoxication. For heroin, pupillary constriction begins approximately 15 minutes after administration in non-dependent individuals and persists for at least two hours. Morphine similarly causes bilateral miosis, which is a reliable clinical sign of opioid effects.^[43]^[43] Other pharmacological agents contributing to miosis include cholinesterase inhibitors, such as those found in organophosphate pesticides (e.g., chlorpyrifos, malathion), which irreversibly inhibit acetylcholinesterase, leading to acetylcholine accumulation and overstimulation of muscarinic receptors in the iris. Exposure to these pesticides results in miosis as a hallmark of cholinergic toxicity, often accompanied by salivation, lacrimation, and bronchorrhea. Clonidine, an alpha-2 adrenergic agonist used for hypertension, also produces miosis, particularly at intravenous doses of 0.1-0.2 mg, through central modulation of autonomic tone, with effects observable in light-dependent conditions.^[44]^[45]^[46] Miosis can also arise from withdrawal effects, specifically cholinergic rebound following abrupt cessation of anticholinergic medications. This rebound occurs due to sudden unopposed parasympathetic activity, manifesting as cholinergic excess symptoms including pupillary constriction. Such effects have been documented after discontinuation of drugs like clozapine, highlighting the need for gradual tapering to mitigate rebound phenomena.^[47]^[48]

Diagnosis and Evaluation

Clinical Signs

Miosis is characterized by the constriction of the pupil to a diameter typically less than 2 mm, resulting in pinpoint pupils that may appear even in dim light conditions.^[5]^[2] These small pupils can be unilateral, leading to anisocoria (unequal pupil sizes), or bilateral, and often exhibit a sluggish or reduced response to light stimulation during clinical examination.^[49]^[5] Associated symptoms vary by underlying cause but commonly include headache, eye pain, blurred vision, light sensitivity, and redness of the eyes.^[2] In cases linked to Horner's syndrome, unilateral miosis is frequently accompanied by ptosis (drooping eyelid) and anhidrosis (lack of sweating) on the affected side.^[49]^[5] Poisoning or opioid use may present with additional systemic signs such as nausea, vomiting, drowsiness, and respiratory depression alongside bilateral pinpoint pupils.^[1] For inflammatory conditions like uveitis or iritis, miosis occurs with eye redness, photophobia, and pain.^[5] In bilateral miosis, severe constriction can impair visual acuity by reducing the amount of light entering the eye, potentially leading to blurred vision or difficulty focusing.^[2]^[4] During clinical examination, reduced pupil reactivity is a key finding, assessed by shining a light into the eyes in a dimly lit room to evaluate constriction speed and degree; miosis pupils may constrict minimally or slowly compared to normal.^[49] Adhesions of the iris (synechiae) or inflammation can contribute to persistently small pupils that do not dilate appropriately in low light.^[5] Unilateral miosis often prompts evaluation for asymmetry, while bilateral cases suggest systemic influences like pharmacological effects.^[49] Miosis differs from fixed pupils observed in brain death, where pupils are typically midposition or dilated and show no response to light or accommodation due to complete brainstem dysfunction, whereas miotic pupils retain some degree of reactivity unless adhesions prevent movement.^[50]^[51]

Diagnostic Tests

Diagnostic evaluation of miosis involves a combination of objective measurements, pharmacological challenges, imaging studies, and laboratory investigations to identify the underlying etiology, such as sympathetic denervation in Horner's syndrome or parasympathetic overactivity.^[52] Pupillometry provides an objective assessment of pupil size and reactivity using infrared videography devices that measure pupillary diameter and the dynamics of the pupillary light reflex with high precision, often detecting subtle abnormalities missed by manual examination. These devices quantify constriction velocity, dilation latency, and overall reactivity, aiding in the differentiation of neurological causes like brainstem lesions from physiological miosis. In neurocritical care settings, quantitative pupillometry standardizes evaluation and tracks changes over time, with studies showing it identifies non-reactive pupils more accurately than subjective methods.^[53]^[54] Pharmacological testing helps localize the defect by assessing sympathetic or parasympathetic function. For suspected Horner's syndrome, 4-10% cocaine drops are instilled; failure of the miotic pupil to dilate confirms postganglionic sympathetic denervation, while 0.5% apraclonidine can alternatively induce dilation in the affected eye due to denervation supersensitivity. To evaluate parasympathetic issues, dilute 0.125% pilocarpine is used; constriction greater than 0.5 mm in the affected pupil indicates denervation hypersensitivity, as seen in tonic pupils or third nerve lesions, whereas 1-2% pilocarpine tests for pharmacologic blockade or iris damage. These tests are particularly useful when clinical signs like anisocoria are present but etiology is unclear.^[52] Imaging modalities target potential structural or neurological causes. Magnetic resonance imaging (MRI) of the brain and orbits is recommended for central or preganglionic Horner's syndrome to detect brainstem lesions or tumors, with computed tomography (CT) angiography added if vascular dissection is suspected in postganglionic cases. Slit-lamp biomicroscopy examines the anterior segment for ocular pathologies, such as iris sphincter tears, synechiae, or foreign bodies that may cause mechanical miosis.^[52]^[55] Laboratory tests focus on systemic contributors. Toxicology screening, including urine and serum assays, identifies opioid intoxication or other pharmacological agents causing bilateral miosis. For infectious or inflammatory etiologies, serological tests for syphilis (e.g., VDRL or FTA-ABS) are essential in cases suggestive of Argyll Robertson pupils, while a broader neurological workup may include autoimmune panels or catecholamine metabolite levels in urine for pediatric neuroblastoma-associated Horner's syndrome.^[52]

Management

Treatment Options

The treatment of miosis primarily targets the underlying etiology, as the pupillary constriction itself is a symptomatic manifestation rather than a primary condition requiring independent intervention.^[5] For pharmacological causes, opioid-induced miosis in overdose is reversed with naloxone, the primary antagonist, administered intravenously (0.4-2 mg initial adult dose), intramuscularly, or intranasally to rapidly normalize pupil size and counteract respiratory depression.^[56] For cases stemming from cholinergic toxicity, such as exposure to organophosphate pesticides or overuse of direct-acting cholinergics like pilocarpine, atropine serves as a cornerstone therapy by competitively antagonizing muscarinic acetylcholine receptors, thereby reversing pupillary constriction along with other parasympathetic effects like salivation and bradycardia. In organophosphate poisoning specifically, pralidoxime is administered adjunctively to reactivate acetylcholinesterase enzyme inhibited by the toxin, enhancing the reversal of both muscarinic and nicotinic symptoms when given early, ideally within hours of exposure. Supportive care in these poisoning scenarios includes close monitoring of vital signs, decontamination, and mechanical ventilation if respiratory failure occurs, with atropine dosing titrated to clinical response such as drying of secretions and resolution of miosis.^[57]^[58]^[34] Pathological causes, including inflammatory conditions like uveitis, often necessitate addressing the root inflammation to alleviate associated miosis, which may result from iris sphincter spasm or posterior synechiae. Corticosteroids, such as topical prednisolone acetate 1% eye drops, form the mainstay of therapy for non-infectious anterior uveitis by suppressing immune-mediated inflammation, typically administered hourly initially and tapered based on response to restore normal pupillary dynamics. In addition, cycloplegic agents such as atropine or cyclopentolate eye drops are used to dilate the pupil, relieve ciliary spasm, and prevent synechiae formation.^[59] For synechiae—adhesions between the iris and lens or cornea that mechanically restrict pupil dilation—surgical intervention is indicated in severe or refractory cases, often involving synechiae lysis during procedures like cataract extraction using instruments or laser to break adhesions and prevent secondary complications such as glaucoma.^[32]^[60] Symptomatic relief may be pursued when miosis impairs visualization during diagnostic evaluation or surgery, employing short-acting mydriatics like tropicamide 1% ophthalmic drops to induce transient pupillary dilation for fundus examination or intraoperative access, with effects onset in 20-40 minutes and lasting 4-6 hours. These agents are particularly useful in non-responsive or iatrogenic miosis but carry risks of angle-closure glaucoma in susceptible eyes, necessitating careful patient selection.^[61]

Prognosis

The prognosis of miosis varies significantly depending on its underlying cause, with benign and reversible forms generally resolving completely, while chronic or pathological cases may lead to persistent visual impairments or more severe outcomes. In physiological miosis, such as the normal pupillary response to light or accommodation, constriction is transient and fully resolves without intervention once the stimulus is removed.^[5] Similarly, drug-induced miosis from reversible agents like opioids or certain antihypertensives typically shows full resolution upon discontinuation of the medication or reversal of the exposure, provided no permanent neural damage occurs.^[2] In contrast, chronic conditions associated with miosis often result in long-term vision issues. Congenital miosis, as seen in microcoria, is linked to persistent small pupils that can cause hemeralopia, photoaversion, high myopia (in up to 80% of cases), astigmatism, and a 30% risk of juvenile-onset glaucoma, potentially leading to blindness if unmanaged.^[62] For neurodegenerative causes, such as those in Parkinson's disease or multiple system atrophy, miosis tends to be persistent and progressive, exacerbating visual disturbances like reduced contrast sensitivity as the underlying disease advances. Acute pathological miosis from poisoning, particularly opioids, carries a high mortality risk—estimated at over 100,000 deaths annually in the U.S. as of 2022 (with a decline to approximately 80,000 in 2024), due to respiratory arrest—though survival with prompt intervention, including naloxone, can prevent long-term sequelae. Recent declines in overdose deaths, attributed to increased naloxone distribution and public health interventions, have improved survival rates.^[56]^[63] Key factors influencing outcomes include early diagnosis and the reversibility of the cause; for instance, in idiopathic Horner's syndrome (a common pathological cause of unilateral miosis), approximately 50% of cases show spontaneous resolution of anisocoria, with about one-third experiencing ptosis improvement over an average of 7.9 years, though prognosis worsens with underlying tumors or trauma.^[30] Long-term monitoring, particularly for unilateral miosis, involves regular ophthalmologic follow-up to detect progression of associated conditions like glaucoma or neurological deterioration, ensuring timely adjustments to vision correction or underlying disease management.^[64]

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Illicit drugs: Effects on eye - PMC - PubMed Central - NIH
A study on the effect of heroin has found that pupillary constriction starts in 15 min and persists for at least two hours in non-dependent individuals whereas ...
[44]
Assessment of four organophosphorus pesticides as inhibitors of ...
Nov 2, 2021 · Organophosphate poisoning ultimately results in cholinergic crisis and a variety of symptoms such as miosis, bronchoconstriction, bradycardia, ...
[45]
Pesticides: Cholinesterase Inhibitors Poisoning - AccessMedicine
Inhibition of cholinesterase results in abdominal cramps, diarrhea, vomiting, excessive salivation, sweating, lacrimation, miosis, wheezing and bronchorrhea, ...
[46]
Reversal of clonidine induced miosis by the alpha 2-adrenoreceptor ...
Clonidine given i.v. at a dose of 0.1 mg and 0.2 mg was found to cause miosis in a placebo controlled double-blind study in six healthy volunteers.
[47]
Potential adverse effects of discontinuing psychotropic drugs. Part 1
Abruptly stopping anticholinergic drugs can lead to an anticholinergic discontinuation syndrome characterized by cholinergic rebound, symptoms of which include ...Missing: miosis | Show results with:miosis
[48]
A case report of cholinergic rebound syndrome following abrupt low ...
Feb 19, 2019 · Rebound cholinergic syndrome is a rare, but well known unwanted phenomenon occurring after abrupt clozapine discontinuation.Missing: miosis | Show results with:miosis
[49]
Miosis: Causes, Treatment, and Diagnosis of Constricted Pupils
Feb 21, 2019 · Miosis means excessive dilation (shrinking) of your pupil. It's not a disease in and of itself, but rather a symptom of some other cause or ...
[50]
Pinpoint pupils: Causes, symptoms, and treatment
Jun 3, 2024 · Pinpoint pupils occur when the pupils shrink to a small size. This can be due to various conditions and medications, such as prescription opioids, hypertension ...<|control11|><|separator|>
[51]
Pupil diameter for confirmation of brain death in adult organ donors ...
May 16, 2016 · In brain death, the position of the pupil is fixed in the midposition, but the pupil size might not be fixed.
[52]
Neuro-ophthalmic Findings in Coma - EyeWiki
May 25, 2023 · Bilateral fixed and dilated pupils. suggests CN III dysfunction as seen in bilateral infarction of the dorsal midbrain; the size of the pupils ...
[53]
Diagnostic Approach to Pupillary Abnormalities - PMC
Cross-cover or Maddox rod testing in all gaze positions is a simple and rapid means to identify the ocular deviation. Both tests can be performed in the ...
[54]
Application of Pupillometry in Neurocritical Patients - PMC
Jul 5, 2023 · In comparison to manual pupil assessment, pupillometry offers a more accurate and objective assessment, with only one-third of non-reactive ...
[55]
Reliability of standard pupillometry practice in neurocritical care - NIH
Pupillary evaluation in the clinical setting is often performed in a subjective manner, with a penlight for reactivity and a pupil gauge for pupil size.Quantitative Pupil... · Validation Study In Healthy... · Comparison Of Pupil Size...
[56]
Anisocoria - EyeWiki
Jun 18, 2025 · ... slit-lamp examination shows sectoral iris palsy and vermiform iris movement. A detailed neurologic exam may help to localize lesions ...Missing: MRI CT
[57]
Cholinergic Crisis - StatPearls - NCBI Bookshelf - NIH
Apr 6, 2025 · Management involves atropine to counteract muscarinic effects and pralidoxime to reverse nicotinic toxicity. Supportive care, such as ...
[58]
Pralidoxime - StatPearls - NCBI Bookshelf - NIH
Pralidoxime is a medication used in the management and treatment of organophosphate poisoning. It is in the oxime class of drugs.
[59]
Uveitis - Diagnosis & treatment - Mayo Clinic
You may need immunosuppressive medicines if your uveitis affects both eyes, doesn't respond well to corticosteroids or becomes severe enough to threaten your ...Missing: miosis | Show results with:miosis
[60]
Synechiae can be managed during cataract surgery - Healio
Jan 8, 2020 · For patients with synechiae, cataract surgery can provide many benefits. We can break the adhesions, peel off fibrotic membranes, restore a ...
[61]
Tropicamide - StatPearls - NCBI Bookshelf - NIH
Tropicamide is a safe drug for pupillary dilation before a comprehensive eye exam or ocular procedure.Missing: miosis | Show results with:miosis
[62]
Botulinum Toxin Use In Strabismus - EyeWiki
Mechanism of Action of Botulinum Toxin, Indications, Contraindications, Technique, Description, Postoperative Care, Complications, Outcomes
[63]
Congenital Microcoria: Clinical Features and Molecular Genetics
Apr 22, 2021 · Congenital microcoria (MCOR) is an extremely rare, autosomal dominant disease affecting iris development and hindering both of these functions.3. Disease Description · 3.1. Associated Signs · 4. GeneticsMissing: prognosis | Show results with:prognosis
[64]
Opioid Toxicity - StatPearls - NCBI Bookshelf
Jan 22, 2025 · The term "opiate" refers to natural compounds derived from the base of the Papaver somniferum poppy flower, such as opium, morphine, ...
[65]
Horner Syndrome - EyeWiki
Jul 9, 2025 · In children, trauma (birth trauma or neck trauma) is the most common cause of Horner syndrome. Other causes include surgical trauma ...Disease Entity · Etiology · Diagnosis · Examination