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Flash blindness

Flash blindness is a temporary characterized by a reversible loss of following exposure to an intense burst of bright , resulting from the and bleaching of photopigments in the without causing permanent damage. This condition manifests as reduced , afterimages, halos, and image persistence, disrupting the ability to see clearly for a period after the light source has ceased. It is distinct from permanent retinal damage, as recovery typically occurs without medical intervention, though the duration can vary significantly based on factors such as and the eye's state of adaptation. The primary mechanism involves intense visible light causing photochemical bleaching of the retina's and other photopigments, leading to temporary chemical changes that impair photoreceptor function until regeneration. Common causes include detonations, where the flash can produce levels far exceeding even at considerable distances, as well as lasers, strikes, searchlights, and high-powered camera flashes. The effect is exacerbated in dark-adapted eyes, such as during nighttime operations, where recovery times can extend from seconds to several minutes depending on the flash's (measured in troland-seconds) and environmental . For instance, exposures around 9 x 10⁵ to 3 x 10⁷ troland-seconds may require 20 to 130 seconds for partial recovery, with full restoration potentially taking longer in low-light conditions. In practical contexts, flash blindness poses significant risks in , scenarios, and public , such as when laser pointers inadvertently sweep across pilots' eyes, causing distractions that last seconds to minutes and heightening potential. highlights that increasing ambient task illumination can accelerate recovery—for example, raising levels to 50 foot-candles may reduce downtime to as little as 2 seconds—while protective measures like photochromic or filters targeting visible wavelengths offer mitigation without altering . Age-related factors also influence susceptibility, with sensitivity increasing and requiring roughly double the illumination for equivalent every 13 years after age 40. Overall, while not leading to long-term harm, flash blindness underscores the retina's vulnerability to sudden high-intensity , informing protocols in high-risk environments.

Overview and Mechanism

Definition

Flash blindness is a temporary resulting from exposure to an intense, brief burst of light that overwhelms the , leading to a disruption in visual function without causing . This condition arises when the light's energy exceeds the 's capacity to process it, resulting in a central or overall blind spot that impairs the ability to see details in the . The phenomenon was first described in relation to nuclear explosions during testing, particularly the 1945 Trinity test, where eyewitnesses reported temporary vision loss from the detonation's brilliant flash, though it applies to any high-intensity light source capable of similar retinal overload. Post-war research, including military symposia in the , expanded understanding of these effects through controlled studies on light exposure limits. Unlike gradual light adaptation, which occurs over time in changing ambient conditions, flash blindness involves the rapid saturation and bleaching of photopigments in the retina's and photoreceptors, causing an immediate and profound loss of . This photochemical process temporarily halts normal phototransduction until the pigments regenerate.

Physiological Mechanism

Flash blindness arises from the temporary overload and bleaching of photopigments in the retinal photoreceptor cells, specifically rhodopsin in rods and photopsins in cones, which disables their ability to detect light until regeneration occurs. Rhodopsin, composed of the protein opsin bound to the chromophore 11-cis-retinal, absorbs photons maximally around 498 nm, while cone photopsins (with peaks at approximately 420 nm for blue, 534 nm for green, and 564 nm for red) enable color vision under brighter conditions. Excessive photon exposure isomerizes the 11-cis-retinal to all-trans-retinal, breaking the photopigment complex and initiating a cascade that temporarily exhausts the photoreceptors' responsiveness. The bleaching process begins with light energy causing the conformational change in retinal, leading to the formation of unstable intermediates such as metarhodopsin II, which activates and subsequently to hydrolyze cyclic GMP (cGMP), closing cation channels and hyperpolarizing the . This hyperpolarization reduces glutamate release, signaling the about detection. However, intense flashes saturate this pathway by bleaching a large proportion of photopigments—up to 90% or more—preventing further absorption and creating a functional disablement of affected photoreceptors. Regeneration requires the all-trans-retinal to be reduced to all-trans-retinol by enzymes like in the (RPE), followed by its transport back to photoreceptors via interphotoreceptor retinoid-binding protein (IRBP); isomerization to 11-cis-retinal and recombination with occur through enzymatic pathways involving ATP-dependent synthesis in the inner segments. This biochemical cycle, supported by enzymes such as and ATP-powered for cGMP replenishment, typically takes minutes for cones and longer for . The persistence of the bleached state in a localized area results in formation and a temporary , or blind spot, due to delayed in the surrounding unbleached photoreceptors and / cells. Bleached regions fail to contribute to visual signaling, while adjacent areas overcompensate, producing a perceived spot or negative until pigment recovery aligns sensitivity across the . The basic phototransduction process can be simplified as photon absorption by leading to membrane hyperpolarization (from approximately -40 mV to -70 mV in to light-adapted states), but overload causes where additional photons yield no proportional response, as the cascade enzymes and cGMP levels are depleted without recovery.

Causes and Risk Factors

Primary Causes

Flash blindness is primarily induced by to extremely intense bursts of visible in the 400-700 spectrum, which overwhelm the retina's photoreceptors. The most prominent cause is the from explosions, where the emits a brilliant flash peaking within milliseconds and reaching luminosities equivalent to millions of , sufficient to cause temporary at distances up to 85 kilometers at night under clear conditions. High-energy lasers, particularly those in applications like dazzlers or systems exceeding safe exposure limits, deliver concentrated pulses that can produce flash blindness by saturating pigments. According to ANSI Z136.1 standards, exposures above maximum permissible levels for visible wavelengths (e.g., Class 3B or 4 lasers) risk temporary scotomas, with recovery times scaling with pulse energy and duration. Brief, high-intensity discharges from sources like xenon arc strobes in flash photography are another key trigger, especially in low-light environments where the pupil is dilated, amplifying retinal exposure to energies comparable to heavy photographic overexposure. These flashes, lasting microseconds to milliseconds, can induce temporary blindness lasting seconds to minutes, as demonstrated in controlled studies using strobe lamps. Additional sources include strikes, whose extreme brightness can cause immediate temporary visual loss through bleaching, often reported in survivor accounts and clinical reviews of electrical injuries. Brief exposure to intense welding arcs or experimental high-intensity LEDs may also contribute if the visible light component is sufficiently pulsed and focused, though these are less common than sustained exposures leading to other ocular damage.

Influencing Factors

The susceptibility to flash blindness is significantly influenced by ambient light conditions, particularly the state of in the eyes. In low-light environments, such as nighttime, the pupils dilate to maximize light intake, rendering the more vulnerable to intense flashes that bleach photopigments and disrupt and function. This can extend the duration and severity of , with recovery times lasting minutes to hours as the eye readjusts, compared to seconds in well-lit daytime conditions. The duration and intensity of the light exposure play critical roles in determining both the onset and persistence of flash blindness. Brief, high-intensity pulses under one second typically induce temporary effects by overwhelming retinal photoreceptors without causing structural damage, leading to recovery within five seconds to two minutes depending on the flash's luminance. However, prolonged exposures or repeated pulses can exacerbate photopigment bleaching and potentially lead to permanent retinal changes, as the eye's adaptive mechanisms are overwhelmed beyond short-term recovery. Higher intensities correlate with longer recovery periods, emphasizing the threshold nature of these effects. Distance from the light source modulates risk through the , whereby light intensity decreases proportionally to the square of the (I ∝ 1/d²), substantially reducing the potential for overload farther away. For instance, in high-yield scenarios like detonations, flash blindness ranges diminish rapidly with due to this , highlighting the protective effect of spatial separation. Individual physiological factors, including age and pre-existing ocular conditions, can amplify vulnerability by impairing the eye's resilience and recovery processes. Age-related changes in the , such as delayed rod-mediated dark , prolong the time needed to regenerate photopigments after , increasing the likelihood of extended . Conditions like further heighten risks, as compromised retinal health slows adaptation kinetics and heightens sensitivity to intense light, potentially turning temporary effects into more severe outcomes. In the 2020s, the proliferation of high-intensity LEDs and lasers in devices, such as drone lighting systems, has introduced new civilian risks for flash blindness, particularly in low-light recreational or operational settings. These sources can deliver focused, potent illumination capable of inducing and temporary retinal disruption, especially when directed toward the eyes, underscoring the need for awareness in everyday applications.

Types of Flash Blindness

Temporary Flash Blindness

Temporary flash blindness is a reversible resulting from exposure to an intense, brief light source that overwhelms the without causing structural . This manifests as a temporary loss of , often appearing as a persistent or "whiteout" in the , particularly affecting central while peripheral may recover more quickly. It occurs due to the reversible bleaching of photopigments in the and cells of the , where the intense light temporarily depletes the light-sensitive molecules (such as in ) needed for phototransduction, leading to a disruption in normal visual signaling. The duration of temporary flash blindness varies based on factors like ambient light levels, exposure intensity, and individual physiology. Central vision recovery typically occurs within seconds to about 2 minutes, while may take up to several minutes; full dark , involving complete photopigment regeneration, can require 20 to 30 minutes for in low-light conditions, though cones recover in 5-10 minutes. For instance, a camera flash at night may cause a brief whiteout lasting seconds, as the sudden overload bleaches in dark-adapted eyes. Similarly, exposure to a flash grenade in dim environments can induce disorientation with persisting for several seconds due to the overloading of receptors. Recovery from temporary flash blindness is spontaneous and relies on the natural regeneration of photopigments in the , a process accelerated by minimizing further to allow the to readapt. This regeneration restores the photoreceptors' sensitivity without intervention, leading to full visual restoration. In simulations without protective measures, studies have shown that a high percentage—up to 100%—of dark-adapted, unprotected individuals experience temporary flash blindness, underscoring its prevalence in high-intensity exposures. Repeated intense exposures, however, may transition to more lasting effects if not mitigated.

Permanent Flash Blindness

What is sometimes referred to as permanent flash blindness actually describes irreversible retinal damage, such as photoretinopathy, from severe flash exposures that induce thermal or photochemical burns, leading to destruction of photoreceptors and underlying layers such as the (RPE). This is distinct from temporary flash blindness, as it involves permanent tissue damage rather than reversible bleaching. These burns occur when intense visible light energy is absorbed rapidly by retinal tissues, elevating temperatures sufficiently to cause and , preventing natural regeneration and repair processes essential for . The severity of permanent damage typically manifests as a central —a blind spot in the central —or complete vision loss within the affected area, significantly impairing tasks requiring fine like reading or targeting. Such outcomes are rare outside extreme scenarios, such as direct observation of detonations, where the concentrated thermal flux overwhelms ocular defenses. For instance, among and survivors in 1945, only one documented case involved a burn at approximately 2 km from the , resulting in persistent central ; broader surveys indicated minimal serious ocular injuries despite the blasts' intensity. Exposure thresholds for permanent retinal injury are established in laser safety standards, with risks escalating above 10 mJ/cm² in the visible spectrum for broad-band sources, where energy density exceeds the retina's tolerance for photochemical or thermal effects. In modern contexts, laser-induced cases have emerged in military settings, exemplified by a case reported in a 2024 study involving a French paratrooper accidentally exposed to a modified military laser pointer during training; this led to a macular lesion, reduced visual acuity to 20/40, and enduring central scotoma confirmed after two years, highlighting the permanence of such high-intensity exposures. Unlike temporary flash blindness, which resolves through pigment rebinding, permanent cases stem from outright tissue ablation at these elevated intensities.

Symptoms and Effects

Visual Symptoms

Flash blindness manifests primarily as a central , or blind spot in the central field of vision, often accompanied by persistent afterimages or characterized by flashing spots or bright lights in the visual field. Patients frequently report a sudden "whiteout" or overwhelming bright field obscuring normal vision, resembling a snowfield effect that dominates the immediate visual experience. These symptoms arise from the intense bleaching of retinal photoreceptors, leading to temporary disruption centered on the fovea. Post-exposure, individuals experience reduced , where fine details become blurred. Impaired is also common, as the recovery process prolongs adaptation to low-light conditions, making subsequent dark-adapted tasks particularly challenging. These effects contribute to overall , with acuity potentially dropping to levels like 20/400 temporarily before improving. The progression of symptoms begins with immediate onset upon exposure, peaking within seconds as the central is overwhelmed by . Recovery occurs gradually, starting from the peripheral and progressing centrally, allowing peripheral awareness to return before full central function is restored. Diagnostic evaluation via fundoscopic examination typically reveals no initial changes in cases of temporary flash blindness, indicating reversible photoreceptor without structural damage.

Non-Visual Effects

Flash blindness typically does not produce direct physical pain, as the retina lacks nociceptors responsible for detecting noxious stimuli. Any perceived discomfort is generally psychological, arising from the sudden onset of temporary vision loss and associated anxiety. The abrupt visual impairment can lead to disorientation, including balance disturbances and vertigo, as the loss of visual cues disrupts integration with vestibular and proprioceptive inputs essential for postural stability. This instability increases the risk of falls, particularly in environments requiring precise navigation. Psychologically, flash blindness may induce temporary or , especially in high-stakes situations like operations, where the sudden triggers a response and negative affective states such as anxiety. Indirect physical effects during recovery include headaches from ocular strain and, less commonly, . The emotional toll, including heightened from transient vision loss, remains under-discussed in civilian contexts such as accidental exposures during , where the startling blindness can evoke and .

Hazards and Applications

Military and Nuclear Hazards

In military contexts, nuclear explosions pose a significant risk of flash blindness due to the intense emitted during . For a 1-megaton airburst, temporary flash blindness can affect individuals up to 13 miles away during daylight conditions with clear , or as far as 53 miles at night, primarily resulting from the bleaching of photopigments in the . Permanent retinal burns, leading to irreversible loss, become possible at closer ranges where the thermal flux exceeds the eye's tolerance, typically within several miles of ground zero depending on yield and viewing angle, as the focused image of the on the retina causes tissue damage. These distances are influenced by factors such as atmospheric and time of day, which modulate the propagation of the light pulse. Flash-bang grenades, also known as grenades, are non-lethal devices employed in tactical operations to induce temporary disorientation, including flash blindness, through a high-intensity burst of approximately 6-8 million lasting about 60 milliseconds. The device is effective at close range, particularly when the target is facing it directly, allowing to incapacitate suspects or clear rooms without permanent harm. Laser weapons in military use include dazzlers, which emit visible or beams to produce reversible flash blindness and visual disruption without causing permanent damage, often at ranges exceeding 100 meters to deter threats or impair targeting. However, anti-personnel lasers designed to cause permanent blindness are prohibited under Protocol IV to the 1980 , adopted in 1995, which bans their development, production, and transfer to prevent indiscriminate eye injuries in armed conflict. Historical incidents during 1950s nuclear tests, such as those in (1958), demonstrated the hazards to aircrews, where pilots and observers experienced temporary flash blindness from exposures at distances of 7 to 14 miles, prompting the development of protective to mitigate vision impairment during . In the 2020s, military training has incorporated simulations to enhance decision-making in disorienting scenarios without real-world risks. To assess operational risks, probability models for crew impairment due to flash blindness in aerial combat incorporate variables like exposure duration, , and pupil dilation, estimating the likelihood of temporary vision loss that could compromise mission success rates by up to 50% in high-threat engagements.

Civilian and Occupational Risks

Civilian risks arise from everyday exposures to brief, high-intensity lights, such as accidental camera flashes in or , where close-range use of powerful strobes or ring lights can induce temporary flash blindness by overwhelming the with visible light. Case studies have documented instances of macular damage from such exposures, leading to afterimages and reduced that typically resolve within seconds to minutes, though rare phototoxic effects may persist longer in vulnerable individuals. Another common civilian hazard involves laser pointers, which can cause temporary flash blindness when directed at the eyes, particularly in low-light conditions. Incidents include misuse leading to distractions for pilots and drivers, with recovery times ranging from seconds to minutes; regulatory efforts by the FDA limit power outputs to mitigate risks. In recreational contexts like sports events or displays, sudden bursts from stadium floodlights or exploding fireworks can similarly cause momentary visual disruption, contributing to emergency room visits for light-related eye complaints; fireworks alone account for approximately 10,000 ocular injuries annually in the United States, though most involve mechanical trauma rather than flash effects. Emerging hazards in environments include high-intensity LED headlights, which emit blue-rich that can temporarily oncoming drivers by reducing sensitivity and causing recovery times of several seconds. Surveys indicate that up to 85% of drivers experience such temporary dazzle from LED headlights, heightening risks during nighttime travel, though direct damage is uncommon at typical distances. Similarly, lasers from or event displays in densely populated areas present growing concerns for brief, intense exposures leading to flash blindness, particularly as usage increases in settings as of 2025. Overall, while permanent damage from exposure is exceedingly rare in and occupational scenarios, temporary episodes contribute to a notable of the approximately 1 million annual U.S. visits for eye injuries, emphasizing the need for awareness in non-extreme exposures.

Prevention and Management

Preventive Strategies

Protective eyewear plays a central role in preventing flash blindness by filtering out intense visible light in the 400-700 nm spectrum, which is responsible for temporary retinal saturation. In military contexts, such as aviation, PLZT (lead lanthanum zirconate titanate) goggles, developed in the , provide rapid photochromic darkening in response to flashes, blocking over 99% of visible light to avert temporary flash blindness and retinal burns while allowing normal vision otherwise. For occupational hazards like , auto-darkening helmets with levels 10-14 (per ANSI Z87.1 standards) automatically adjust to block , visible, and radiation from arcs, preventing exposure that mimics flash blindness effects. Laser-specific goggles, rated for optical densities of 4-6 in targeted wavelengths, are essential for industrial or medical operations to eliminate glare and afterimages. Environmental controls in low-light settings help mitigate flash blindness risk by preserving partial dark adaptation without full pupil dilation, which amplifies susceptibility to bright flashes. In night operations, filters on lighting and instruments (wavelengths above 620 nm) maintain sensitivity for while minimizing cone bleaching, as rods are insensitive to light; this approach, standardized since , allows pilots to read displays without prolonged recovery from incidental flashes. Similarly, protocols recommend subdued cockpit illumination to avoid degrading dark adaptation, reducing the severity of temporary blindness from external lights. Design standards ensure equipment compatibility to prevent flash blindness in operational environments. The Federal Aviation Administration (FAA) mandates cockpit lighting that minimizes night vision disruption, including red or NVIS-compatible sources to avoid bloom effects from bright flashes, as outlined in human factors guidelines for pilots. In military aircraft, MIL-STD-3009 specifies Night Vision Imaging System (NVIS) compatible lighting, using green or filtered sources below 620 nm to prevent haloing or washout in night vision goggles (NVGs), thereby maintaining visual acuity during potential flash exposures. Awareness training embeds preventive practices into professional protocols to foster habitual use of safeguards. Welding certifications from the American Welding Society (AWS) require instruction on , emphasizing helmets and side shields to block flashes, with trainees practicing proper donning to avoid incidental exposures. For photographers using high-intensity strobes, standard protocols advise warning subjects to avert or close eyes during bursts exceeding lumens, preventing temporary spots akin to mild flash blindness, particularly in studio or event settings. Technological aids advance prevention through adaptive systems tested in recent evaluations. Auto-dimming visors, such as Bosch's Virtual Visor introduced in 2020, use LCD panels and cameras to selectively darken sections blocking sun glare (up to 99.9% light reduction in targeted areas), reducing temporary blindness risk without obstructing . Similarly, Gentex's dimmable glass visors, prototyped in the early , automatically tint via electrochromic for both drivers and passengers, enhancing safety in high-glare scenarios.

Treatment Approaches

Treatment for temporary flash blindness primarily involves supportive measures to facilitate , as the condition results from the temporary bleaching of photopigments in the . Affected individuals are advised to rest in a dark room and avoid exposure to bright lights, which helps prevent further irritation and allows the photopigments to regenerate naturally. Recovery typically occurs within 3-10 minutes in daylight conditions, though it may take longer at night due to dilated pupils. For permanent retinal damage resulting from intense light exposure, such as (distinct from temporary flash blindness and covered further in the "Related Conditions" section), there is no established cure, and management focuses on mitigating symptoms and preventing complications. Observation is the mainstay, with many patients experiencing partial spontaneous improvement over 3-6 months, although visual deficits may persist. Corticosteroids, such as , may be administered in acute severe cases to reduce and inhibit , potentially limiting further retinal damage, though evidence from randomized trials is lacking. Diagnostic evaluation is crucial for assessing the extent of retinal involvement and guiding management. (OCT) imaging provides detailed cross-sectional views of the , revealing disruptions in the photoreceptor layers or outer retinal defects characteristic of photic injury. testing complements OCT by quantifying central or paracentral scotomas, aiding in monitoring progression and functional impact. Supportive care extends to low-vision aids, such as magnifiers or adaptive optical devices, to enhance remaining visual function in permanent cases. In severe instances involving significant vision loss, psychological counseling may address associated anxiety or adjustment challenges. Experimental regenerative approaches, including therapies aimed at repairing photoreceptor damage, remain in early clinical trials as of 2025 and show promise for broader retinal conditions but lack specific approval for .

Related Conditions

Photokeratitis

is a superficial inflammation of the , known as ultraviolet keratitis, resulting from acute overexposure to ultraviolet (UV) radiation that damages the epithelial cells of the and , producing symptoms of intense pain, excessive tearing, and a gritty sensation akin to a sunburn on the eye's surface. This condition differs markedly from flash blindness, which involves painless temporary visual disruption due to retinal overload from intense visible . The primary causes of photokeratitis include unprotected exposure to UV sources such as welding arcs, which emit high levels of UV-B and UV-C radiation, and artificial sunlamps used in tanning beds or medical treatments. Symptoms typically emerge with a delayed onset, peaking between 6 and 12 hours after exposure, and include , , , and eyelid swelling, reflecting the time required for epithelial and nerve exposure. Treatment focuses on symptomatic relief and promoting epithelial healing, involving the use of lubricating or antibiotic ointments like erythromycin, cold compresses to reduce , and oral analgesics such as ibuprofen for . The condition is self-limiting, with full resolution occurring within 24 to 48 hours in most cases, without permanent damage to the eye. A key distinguishing feature of photokeratitis is its localization to the corneal and conjunctival surfaces, sparing the , which underscores its UV-specific mechanism rather than visible light phototoxicity. It is particularly prevalent among welders operating without adequate protective , where studies report prevalence as high as 73.7% among arc welders, largely attributable to recurrent UV flashes. Historically, photokeratitis has been documented as "snow blindness," affecting Arctic explorers due to intense UV reflection from ice and surfaces, prompting early protective innovations like slit among communities.

Photic Retinopathy

is a form of photochemical or thermal damage resulting from exposure to focused intense light sources, primarily affecting the and leading to characteristic lesions that impair central vision. This phototoxic injury disrupts the outer layers, distinguishing it as a potentially permanent condition in the spectrum of light-induced visual impairments. The condition arises from causes such as solar retinopathy, often due to unprotected viewing of solar eclipses or direct sun gazing, and laser-induced maculopathy from devices like handheld pointers or arcs. Symptoms commonly include central or paracentral , decreased , , and , reflecting damage concentrated in the foveal region. Pathologically, photic retinopathy involves and that damage photoreceptors and the , causing outer retinal disruption such as ellipsoid zone defects and potential formation of outer retinal holes. These changes are visible on fundus examination as yellowish-white macular lesions or loss of foveal reflex, with revealing hyperreflectivity and thinning; the fovea, lacking regenerative photoreceptors, often retains permanent structural alterations. Prognosis varies by exposure severity and duration, with many patients experiencing partial visual over weeks to months without , though full restoration is not guaranteed. In severe cases, particularly those involving lasers, permanent vision loss occurs, with clinical series reporting severe vision loss (worse than 20/200) in approximately 17% of cases. In contemporary settings, cases are rising due to accessible pocket lasers, with reports indicating an increase in incidents, often among children and linked to misuse as toys.

References

  1. [1]
    [PDF] A REVIEW OF RESEARCH ON FLASH BLINDNESS - DTIC
    According to Effects of Nuclear Weapons (1), temporary flash blindness or "dazzle" results when more thermal energy is received on the retina than is iiecessary ...
  2. [2]
    FLASH BLINDNESS | Vision Research: Flying and Space Travel
    In considering the effects on vision of the light from a nuclear burst, there are, in fact, two major areas of concern: one deals with the permanent damage, or ...
  3. [3]
    Illuminating Facts About Laser Pointers - FDA
    Apr 26, 2024 · Flash blindness is a temporary loss of vision that occurs when the eye is suddenly exposed to intense light--even from an unintentional sweep of ...Missing: definition | Show results with:definition
  4. [4]
    [PDF] Flash Blindness SYMPOSIUM - DTIC
    Jan 20, 2025 · he measured the bleaching of the retinal photopigments in the living human eye and correlated the regeneration of the pigments with the.
  5. [5]
    [PDF] Flash Blindness | HDIAC
    Flash blindness: temporary blindness induced by the photochemical bleaching of the rod and cone photoreceptors in the retina by extremely bright light. • ...
  6. [6]
    https://webvision.pitt.edu/book/part-ii-anatomy-and-physiology-of-the-retina/photoreceptors/
  7. [7]
    Vision – Basic Human Physiology - IU Pressbooks
    When a large group of photopigments is bleached, the retina will send information as if opposing visual information is being perceived. After a bright flash of ...
  8. [8]
    Bleaching desensitization: background and current challenges
    The findings noted above indicate (1) that rhodopsin bleaching produces prolonged excitation and desensitization in rod photoreceptors, and that retinoid cycle ...
  9. [9]
    Flash Blindness - Atomic Archive
    Flash blindness is caused by a nuclear flash, bleaching visual pigment, causing temporary blindness. It lasts seconds in daylight, longer at night. A 1-megaton ...
  10. [10]
    Flash Blindness - Radiation Emergency Medical Management
    Flash blindness caused by the effect on the retina of the initial brilliant flash of light produced by the explosion.Missing: definition | Show results with:definition
  11. [11]
    Laser Safety Manual - EHS | The University of Alabama
    Another variation is the laser family known as the Excimer lasers (“excited dimer”), such as the Xenon-Chloride (XeCl) laser. ... flash blindness, vision ...
  12. [12]
    Lightning injuries of the posterior segment of the eye - PubMed Central
    Lightning injury can cause a wide range of injuries to posterior segment of eye of varying severities.
  13. [13]
    Recent advances in the dark adaptation investigations - PMC - NIH
    When the eye is under dark adaptation, exposure to the glare can results in instantaneous bleaching of photopigments, while the regeneration of photopigments ...
  14. [14]
    Flash Blindness Recovery for Pilots in the Modern Cockpit
    Flash blindness can be caused by viewing of either laser or broadband (white light) sources directly, or indirectly from reflections off water, buildings ...Missing: primary | Show results with:primary
  15. [15]
    [PDF] Review of Research on Flash Blindness, Chorioretinal Burns ... - DTIC
    Te problem of flash blindness and chorioretinal burns resulting from exposure to the intense ener'gy pulse from a nuclear fireball has been recognized.
  16. [16]
    A short-duration dark adaptation protocol for assessment of age ...
    Dark adaptometry may be a useful diagnostic test and clinical trial endpoint for age-related maculopathy (ARM) because impaired night vision is a hallmark ...
  17. [17]
    [PDF] Delays in Rod-mediated Dark Adaptation in Early Age-related ...
    Objective: To determine whether there are disturbances in the rod-mediated kinetics of dark adaptation in early age-related maculopathy (ARM).
  18. [18]
    LED Applications Require Exposure Limits to Safeguard Consumers
    In applications that relate to transportation safety, high exposure levels can cause distractions, glare, flash blinding, and retinal damage. Each can lead to ...Missing: 2020s | Show results with:2020s
  19. [19]
    [PDF] The Eye and Night Vision - Valley Flyers
    Regeneration of the photopigments occurs during dark adaptation. The fully dark-adapted eye, in which photopigment regeneration is complete, restores retinal.
  20. [20]
    Can a Camera Flash Hurt Your Eyes? - Improve Photography
    However, flash blindness is a temporary condition. As the retina returns to ... A lot of speedlights have a flash duration of between 1/200 and 1/20,000 of a ...
  21. [21]
    How do flashbangs work? - CEENTA
    Mar 11, 2020 · Flashbang grenades will cause an effect called 'flash blindness' which is due to overloading the light receptors in the eye and causing a significant ...
  22. [22]
    Light damage to the retina: an historical approach - PubMed Central
    Nov 6, 2015 · Photochemical damage occurs at body temperature and involves cellular damage by reactive forms of oxygen. The photosensitizers are photoproducts ...
  23. [23]
    [PDF] Compilation of Nuclear Test Flash Blindness and Retinal Burn Data ...
    Exposure of the human eye to thermal radiation from a nuclear burst may result in either a temporary loss of visual acuity, termed flash-blindness, or a tissue ...
  24. [24]
    'Unspeakable horror': the attacks on Hiroshima and Nagasaki
    Aug 4, 2025 · Survivors, known as “hibakusha,” also experienced longer-term effects including elevated risks of thyroid cancer and leukaemia, and both ...
  25. [25]
    [PDF] 1997 Guidelines on Limits of Exposure to Broad-Band ... - ICNIRP
    Solar retinitis was once referred to as "eclipse blindness" and associated "retinal burn. ... (10 mJ cm²)/En·. (11). 549. Exemption. In cold environments ...
  26. [26]
    Long-Term Visual Impairment From a Military Weapon Laser
    Aug 29, 2025 · Long-Term Visual Impairment From a Military Weapon Laser: A Case Study of a French Soldier · Abstract · INTRODUCTION · CASE REPORT · DISCUSSION.
  27. [27]
    VCE Makes Laser Eye Exposure Treatment Recommendations
    Feb 9, 2023 · Based on the DVEIVR review, “a few service members were found to have permanent damage compromising visual function as a result of [laser] ...Missing: induced 2020s
  28. [28]
    FLASH BLINDNESS | Vision Research: Flying and Space Travel; Proceedings of Spring Meeting, 1964. Edited by Milton a. Whitcomb and William Benson | The National Academies Press
    Summary of each segment:
  29. [29]
    [PDF] VISUAL IMPAIRMENT FROM EXPOSURE TO HIGH INTENSITY ...
    Less intense light may produce "flash blindness, " a temporary but reversible loss of vision which does not involve perma- nent damage. It is only within about ...
  30. [30]
    Peripheral Sensory Neurons Expressing Melanopsin Respond to Light
    The ability of light to cause pain is paradoxical. The retina detects light but is devoid of nociceptors while the trigeminal sensory ganglia (TG) contain ...
  31. [31]
    The influence of cognitive load and vision variability on postural ...
    May 31, 2024 · ... flash blindness (42). This brief period of visual impairment disrupts the normal functioning of the visual system, temporarily compromising ...
  32. [32]
    [PDF] Path Analysis of Human Effects of Flashbang Grenades - IDA
    The typical flashbang grenade's explosive energy generates a deafening boom accompanied by a brilliant flash of light that can be temporarily blinding.
  33. [33]
    [PDF] Laser Hazards in Navigable Airspace - Federal Aviation Administration
    While the visual effects of laser exposure are most often transient, flash blindness or afterimage can linger for several minutes or a few hours, in some ...
  34. [34]
    Featured Article: Law Enforcement Laser Eye Injuries - ACEP
    Jan 4, 2021 · There may also be a temporary or permanent afterimage, or flash blindness ... Other signs and symptoms include visual field defects, headache, ...
  35. [35]
    Mental stress as consequence and cause of vision loss
    Constant anxiety and worries plague many patients as they anticipate a grim future of a progressing blindness. This fear severely impacts QOL and lifestyle [2] ...Missing: flash | Show results with:flash
  36. [36]
    Blinded by the light: the violence of flash photography | Aeon Ideas
    Feb 28, 2018 · Photographic flash is, however, frequently aggressive in its own right. If one is close to it, one's eyes are startled into temporary blindness.Missing: civilian emotional
  37. [37]
    [PDF] The Effects Nuclear Weapons - International Panel on Fissile Materials
    When "The Effects of Atomic Weapons" was published in 1950, the explosive energy yields of the fission bombs available at that time were equivalent to some.
  38. [38]
    Effects of Flash-Bang Grenades on SWAT and Special Operations ...
    Apr 23, 2025 · The blinding flash and concussive sound can incapacitate suspects by causing temporary blindness, hearing loss, and confusion. This gives ...
  39. [39]
    [PDF] DISORIENTATION DEVICES FLASH-BANG/STUN GRENADES
    The explosion of magnesium-based pyrotechnic chemicals causes a very bright flash and a loud sound (160−180 decibels), which can cause temporary blindness, ...
  40. [40]
    Flash -- Sizzle -- Dark Spot | Article | The United States Army
    Soldiers injured in laser incidents often report seeing a flash, while others hear a short sizzle and then see a dark spot. Symptoms include temporary ...
  41. [41]
    [PDF] FLASHBLINDNESS AND CHORIORETINAL BURNS - DTIC
    This project waa designed to further evaluate the effects of atomic detonations on the eyes. This was studied in two previous projects, one.
  42. [42]
    Booz Allen Virtual Reality Improves Military Training
    Think VR is just for games? Booz Allen's immersive trainer is giving sailors the tools to master UUVs before they ever touch the real thing.
  43. [43]
    [PDF] a mathematical model of flashblindness - DTIC
    to Flash Blindness". Aerospace Medicine, Vol. 33, 1962, pp. 1199-1205. 41 ... Nighttime flying introduces its own visual demands. Extremely low.
  44. [44]
    Preventing Eye Injuries When Welding - Occupational Health & Safety
    Feb 1, 2007 · Eye injuries account for one-quarter of all welding injuries, making them by far the most common injury for welders, according to research from ...Missing: blindness statistics
  45. [45]
    Prevalence and Factors Influencing Eye Injuries among Welders in ...
    Sep 16, 2020 · Overall prevalence of eye injuries was 47.9%, higher among electric/arc welders (73.7%) compared to gas welders (9.7%). Factors associated with ...
  46. [46]
    Welder's Flash (or Arc Eye): Causes, Symptoms and Treatment
    Aug 21, 2025 · Welder's flash occurs when a worker's eyes are exposed to UV light from a welding arc without wearing proper protection.
  47. [47]
    Flash photography-induced maculopathy - PMC - PubMed Central
    Sep 15, 2011 · This case illustrates that the light of flash photography can accidentally hit an eye and induce a light-induced maculopathy.Missing: xenon | Show results with:xenon
  48. [48]
    Fireworks Eye Safety - American Academy of Ophthalmology
    Make sure all other people are at least 500 feet away before lighting fireworks. Never light fireworks in a container, especially a glass or metal container.Missing: flash | Show results with:flash
  49. [49]
    85% have been temporarily blinded by LED headlights - Tiger.co.uk
    A recent survey revealed 85% of drivers have been temporarily blinded or dazzled by oncoming headlights from other vehicles.
  50. [50]
    [PDF] Nighttime Glare and Driving Performance: Research Findings
    Logically, this temporary reduction in visual functioning has implications for nighttime driving safety. ... Glare induced by automobile headlights: A statistical ...
  51. [51]
    FLASH: A Novel Tool to Identify Vision-Threating Eye Emergencies
    Oct 8, 2020 · Background: Two million patients visit emergency departments due to eye complaints annually in the United States, yet nearly one-quarter of ...
  52. [52]
    Utah National Guard ATAG dons PLZT goggles during nuclear flash ...
    Jun 11, 2017 · PLZT goggles were designed in the 1970s to provide protection from temporary flashblindness and permanent retinal burns caused by the brilliant flash of ...Missing: eyewear | Show results with:eyewear<|control11|><|separator|>
  53. [53]
    [PDF] Eye Protection against Radiant Energy during Welding and Cutting ...
    Electromagnetic energy given off by an arc or flame can injure workers' eyes and is commonly referred to as radiant energy or light radiation. For protec-.
  54. [54]
    https://opg.optica.org/abstract.cfm?uri=josa-34-8-464
  55. [55]
    Dark Adaptation: Some Physical, Physiological, Clinical, and ...
    Use of Red Filters for Producing Dark Adaptation. On theoretical grounds it is known that the use of red light, and hence the wearing of red goggles or red ...
  56. [56]
    [DOC] 2
    Flash-blindness is a visual interference effect, caused by a bright light that persists after the light is terminated. Flash-blindness continues to persists ...
  57. [57]
    [PDF] LIGHTING, AIRCRAFT, NIGHT VISION IMAGING SYSTEM (NVIS ...
    Feb 2, 2001 · Class A NVIS is not compatible with red cockpit lights because of the overlap between the spectrum of red light and the sensitivity of Class A ...
  58. [58]
    Safety in Welding Online Course - AWS
    The course aims to provide a comprehensive overview of the hazards associated with welding, including exposure to radiation, electrical shock, fire, and toxic ...
  59. [59]
    CES 2020: Virtual Visor precisely blocks blinding sun (Video)
    Jan 5, 2020 · German auto supplier Robert Bosch is showing an invention at CES 2020 in Las Vegas called Virtual Visor that replaces the traditional sun visor.
  60. [60]
    Dimmable Glass - Gentex Corporation
    Dimmable Visors · Darken on demand or automatically · Reduces glare for driver and passenger · Maintains forward vision compared to a traditional visor.Missing: flash 2020s
  61. [61]
    A Review of Photic Retinopathy - Retinal Physician
    Jun 1, 2020 · TREATMENT. There are no randomized control trials for the treatment of photic retinopathy, and no therapy has been proven effective. Most cases ...
  62. [62]
    Photic Retinopathy: Diagnosis and Management of This Phototoxic ...
    Apr 12, 2025 · Methylprednisolone is believed to reduce light-induced retinal damage by inhibiting lipid peroxidation [67].
  63. [63]
    Solar Retinopathy - EyeWiki
    Oct 30, 2025 · Solar retinopathy (also known as, photic retinopathy, foveomacular ... No known beneficial treatment exists for solar retinopathy ...Missing: flash | Show results with:flash
  64. [64]
    Long-term sequelae of photic eye injury from a solar eclipse
    The OCT scan is very useful in diagnosis and assessment of the degree and nature of foveal damage. There is no proven treatment for solar retinopathy.
  65. [65]
    Groundbreaking Stem Cell Clinical Trial for Retinal Disease Treats ...
    Jul 21, 2025 · The induced pluripotent stem cell (iPSC)-derived photoreceptor cell product OpCT-001 is designed to restore functional photoreceptors to ...
  66. [66]
    Photokeratitis - EyeWiki
    Apr 3, 2025 · Photokeratitis, or Ultraviolet Keratitis, is a painful eye condition which can develop after unprotected exposure to Ultraviolet (UV) rays.
  67. [67]
    Photokeratitis: Symptoms, Causes and Treatment Options
    Photokeratitis refers to temporary, painful eye damage from exposure to ultraviolet (UV) light, such as the sun and its reflection, welding arcs and lights used ...<|control11|><|separator|>
  68. [68]
    What is Photokeratitis — Including Snow Blindness?
    Sep 26, 2024 · Photokeratitis is a painful eye condition that occurs when your eye is exposed to invisible rays of energy called ultraviolet (UV) rays.
  69. [69]
    Photokeratitis (ultraviolet [UV] burn, arc eye, snow blindness)
    Photokeratitis (ultraviolet [UV] burn, arc eye, snow blindness) ... It outlines non-pharmacological management approaches and pharmacological treatment options.
  70. [70]
    Photokeratitis induced by ultraviolet radiation in travelers: A major ...
    Photokeratitis is a painful, superficial, punctate keratopathy caused by acute exposure to UVR. This disorder usually appears up to 6 h after UVR exposure.
  71. [71]
    RETINAL BURNS IN PHOTIC RETINOPATHY - PubMed Central - NIH
    Photic retinopathy (PR) is due to retinal phototoxicity, especially affecting the macula, resulting from exposure to sun, welding devices and lasers.
  72. [72]
    Solar Retinopathy: A Multimodal Analysis - PMC - PubMed Central
    Solar retinopathy is a rare ocular lesion that can result from unprotected solar eclipse viewing and also from minimal gazing at the sun.Missing: prognosis | Show results with:prognosis
  73. [73]
    Solar maculopathy: prognosis over one year follow up - PMC
    Sep 18, 2019 · Photic retinopathy can occur upon prolonged light exposure without protective measures [2]. Solar maculopathies can be caused by a single or ...
  74. [74]
    Retinal burns from laser pointers: a risk in children with behavioural ...
    Dec 13, 2018 · Many patients (36%) suffered moderate vision loss (6/18 to 6/60 Snellen), while 17% suffered severe vision loss (<6/60 Snellen). Visual acuity ...
  75. [75]
    https://pmc.ncbi.nlm.nih.gov/articles/PMC10313552/