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Corresponding author: Chris Davis, MD, DTMH, University of Colorado Hospital Department of Emergency Medicine, 12401 East 17th Avenue, Aurora, CO, 80045
Department of Wound Healing and Hyperbaric Medicine, St. Alphonsus Hospital, Boise, ID, and Emergency Services, Teton Valley Hospital, Driggs, ID (Dr Johnson)
Division of Emergency Medicine, Stanford University Medical Center, Palo Alto, CA, the Department of Emergency Medicine, Alaska Native Medical Center, Anchorage, AK, and the International Commission for Mountain Emergency Medicine (Dr Zafren)
To provide guidance to clinicians about best practices, the Wilderness Medical Society (WMS) convened an expert panel to develop evidence-based guidelines for the treatment and prevention of lightning injuries. These guidelines include a review of the epidemiology of lightning and recommendations for the prevention of lightning strikes, along with treatment recommendations organized by organ system. Recommendations are graded on the basis of the quality of supporting evidence according to criteria put forth by the American College of Chest Physicians. This is an updated version of the original WMS Practice Guidelines for Prevention and Treatment of Lightning Injuries published in Wilderness & Environmental Medicine 2012;23(3):260–269.
Approximately one-fifth of these flashes result in ground strikes. Internationally, an estimated 24,000 fatalities with 10 times as many injuries occur annually as a result of lightning.
Cherington M, Walker J, Boyson M, Glancy R, Hedegaard H, Clark S. Closing the gap on the actual numbers of lightning casualties and deaths. 11th Conference on Applied Climatology. Dallas, TX: American Meteorological Society; 1999:379–380.
To provide guidance to clinicians and prehospital providers and to disseminate knowledge in this area, the Wilderness Medical Society (WMS) convened an expert panel to develop evidence-based guidelines for the treatment and prevention of lightning injuries. The WMS previously published guidelines on lightning injuries in 2006 and 2012.
This is an updated version of the original WMS Practice Guidelines for Prevention and Treatment of Lightning Injuries published in Wilderness & Environmental Medicine 2012;23(3):260–269. The goal of this review is to update the guidelines published in 2012 with relevant evidence-based information including a summary table of the best available literature. However, it must be recognized that the nature of lightning injuries often limits the available evidence to case reports and case series.
Methods
A panel was first convened at the 2011 Annual Meeting of the WMS in Snowmass, CO. Members were selected on the basis of clinical or research experience. The lead author identified articles through the PUBMED databases using a key word search with the terms lightning, lightning strike, lightning injury, Lichtenberg, and keraunoparalysis. This was supplemented by a hand search of these articles. The amassed evidence was then reviewed and graded for quality by the panel.
In August 2014 these guidelines were updated using a key word search of PUBMED for lightning-related articles from 2011 to 2014. The same search terms were used. This supplement also incorporates suggestions from readers related to the original publication. The panel used the American College of Chest Physicians (ACCP) classification scheme for grading evidence and recommendations
(see online Supplementary ACCP Table 1). Injuries and recommended treatment strategies are organized by organ system.
Epidemiology
Regional Considerations: Weather and Geography
Lightning strikes are not uniformly distributed around the Earth (Figure 1). Regions with frequent thunderstorms have more lightning strikes. Thunderstorms are formed by 3 atmospheric elements: moisture, warm air on the surface of the earth, and a lifting wind. As the warm, moisture-laden air is pushed upward by vertical updraft, it condenses and cools, forming cumulonimbus clouds. Water freezes into ice particles near the top of this cloud. It is believed that the movement of these ice particles forms an electrical gradient (or differential) that is eventually discharged as lightning.
In addition to prevailing weather patterns, geography is also a determining factor in the location and frequency of thunderstorms. Central Africa has the greatest incidence of lightning strikes because of its mountainous terrain coupled with moist airflow from the Atlantic Ocean. This leads to year-round thunderstorms.
Worldwide, rural populations have been at greatest risk. Demographically this risk has been attributed to higher occupational exposure (rural farmers). These populations typically do not have access to substantial buildings that could provide shelter.
This occurs in sunny conditions, usually after a storm, when strikes can return to areas from which the storm has passed, posing a risk to people who return to outdoor activity too soon. Lightning is also possible in snowstorms. Graupel (snow pellets) heralds weather favorable to lightning formation, as ice and snow pellets are believed to generate positive and negative charges as they collide, ultimately providing the electrical gradient that facilitates lightning formation.
Lightning fatalities per state are reported in Figure 2. In the United States, the lifetime risk of being struck by lightning is estimated at 1:10,000.
Lightning can be both negatively and positively charged and can take the form of both direct and alternating current depending on circumstance. However, lightning does not cause the muscle tetany seen with alternating currents of other electrical injuries. A bolt of lightning has a massive current ranging from 30,000 to 110,000 A, although such currents are only applied for 10 to 100 ms.
A direct strike occurs when there is an uninterrupted connection between a lightning bolt and an individual; direct strikes are relatively rare, accounting for approximately 5% of lightning strikes involving people.
Contact injury occurs when a person is touching an object that is struck. Side splash accounts for one-third of lightning injuries and occurs when the current “splashes” or jumps from a nearby object to the recipient’s body; such splashes follow the path of least resistance when compared with the initially struck object such as a tree. Ground current, also known as step voltage, occurs when lightning strikes an object or the ground near a person and travels through the ground from the strike point to the victim. This mechanism accounts for nearly half of lightning injuries.
A fifth mechanism of lightning injury has been recently reported. The “upward streamer” describes current passing up from the ground, through the victim, without a nearby ground strike; ultimately it is postulated that such a current does not become part of a completed lightning channel.
Lightning electricity, as with all electrical energy, will travel the path of least resistance. In body tissues, the order of least to greatest resistance is nerve < blood < muscle < skin < fat < bone.
Prevention
Evidence-based guidelines are limited regarding lightning prevention and safety. The following recommendations represent opinion from this panel or from previously published guidelines.
ICAR and UIAA MEDCOM Lightning injuries: prevention and on-site treatment in mountains and remote areas. Official guidelines of the International Commission for Mountain Emergency Medicine and the Medical Commission of the International Mountaineering and Climbing Federation (ICAR and UIAA MEDCOM).
No place is absolutely safe from lightning. However, individuals can choose safer places in an effort to reduce their risk of lightning strike. “When thunder roars, go indoors” is the currently recommended safety maxim of the National Weather Service. In essence, if one can hear thunder, then there is a risk of lightning strikes and one should seek shelter immediately. As substantial shelter is rarely available in the wilderness, hearing thunder in this setting should trigger an individual to immediately avoid or leave areas that are high risk for lightning strikes, such as ridgelines or summits, and to avoid tall objects such as ski lifts, cell phone towers, or isolated trees. One should observe for changing weather patterns that could indicate a developing thunderstorm: building cumulonimbus clouds, increasing winds, and darkening skies. Previous rules have relied on timing lightning flashes with thunder to estimate distance from an approaching storm. Such calculations may engender a false sense of security either from incorrect calculations or incorrect pairing of a given lightning flash with the correct thunderclap. Individuals should instead rely on observing signs of impending storms and seeking cover accordingly. Individuals should wait a minimum of 30 minutes after hearing the last thunderclap before resuming outdoor activity. Waiting 30 minutes should allow for the trailing edge of the thunderstorm to move the estimated 10 miles needed to establish an appropriate buffer zone. Recommendation grade: 1C.
Shelter
There is no absolutely safe place from lightning—some locations are safer than others. When possible, shelter should be sought in the largest enclosed building available away from doors or windows. Another option is in a metal-topped vehicle with windows and doors closed; convertibles with fabric tops are not protective.
As this option is markedly limited in the wilderness setting, this panel recommends seeking a sheltered area inside a deep cave, far into a dense forest, or in a deep ravine; these features represent a safer alternative than remaining in an open, exposed area. Shallow caves, solitary trees, or open shelters (such as a picnic shelter, dugout, canopy, or lean-to) should be avoided because of the risk of side splash and ground current.
Bandara K. Lightning hazards: impacts and responses of the public. 18th Annual International Lightning Detection Conference. Helsinki, Finland: Vaisala; 2004.
When possible, the safest shelters are a building followed by a hardtop vehicle. Recommendation grade: 1C.
Lightning Position
The lightning position involves sitting or crouching with knees and feet close together to create only one point of contact with the ground (Figure 3). If standing, have feet touching. If sitting, lift feet off the ground. Take this position only when a lightning strike is imminent and when all other lightning prevention strategies have failed. Signs of imminent strike include a blue haze around objects or individuals (St. Elmo’s fire), static electricity over hair or skin, an ozone smell, or a nearby crackling sound. Attempt to minimize the risk of ground current injury by insulating oneself from the ground; sit on a pack (remove any metal from the pack), a dry coiled rope, or a rolled foam sleeping pad. This is a strategy of last resort, as it is a difficult position to maintain for a long time, and should not be relied on as primary prevention but may reduce the risk of injury from an imminent lightning strike.
This panel recommends the separation of group members by greater than 20 feet or more to limit potential mass casualties, as lightning can jump up to 15 feet between objects. Although each individual should be aware of lightning safety, groups should develop a specific lightning safety plan. Such a plan accounts for local weather patterns, current weather forecast, local terrain, and predetermined available shelter and evacuation routes.
A preestablished plan should mitigate the chaos of evacuating a crowd during a lightning storm. Further examples of lightning safety plans are available online through the National Lightning Safety Institute and the National Weather Service.
In the United States numerous commercial services are available that can provide automatic notifications when nearby lightning is detected by the National Lightning Detection Network (NLDN).
National Severe Storms Laboratory Overview of Real-Time Lightning Detection Systems and Their Meteorological Uses..
U.S. Dept. of Commerce, National Oceanic and Atmospheric Administration, Environmental Research Laboratories, National Severe Storms Laboratory; for sale by the National Technical Information Service,
Norman, OK; Springfield, VA1993
Automatic notices of lightning activity are transmitted by e-mail, text, or cell phone to a predetermined individual. As cell phone reception is rarely available in the wilderness, personal lightning detection devices are an alternative option that does not rely on cellular technology. These devices are about the size of a pager, are easy to carry, and can detect lightning as far away as 75 miles. The device immediately signals the person of lightning activity and its distance by beeps, flashing lights, or a text message. This technology can be used to augment (but not supersede) a lightning safety plan. It should be noted that the available data on the efficacy of this technology is not peer reviewed and are largely based on manufacturer testimonials. Recommendation grade: 2C.
Lightning In a Mountain Environment
The panel strongly recommends the avoidance of peaks and ridgelines in the afternoon as thunderstorms are most frequent during this time period.
A common safety adage is “up by noon and down by two,” meaning that hikers and climbers should be off peaks and ridgelines by 2:00 pm. If caught in a thunderstorm, climbers should tie-off individually as lightning is able to conduct over wet climbing ropes and may affect both climber and belayer. Individuals should discard metal objects such as ski poles or mountaineering axes to avoid contact burns.
Recommendation grade: 1C.
Lightning In a Water Environment
This panel recommends that individuals exit the water and seek shelter expeditiously if caught swimming during a lightning storm. When rafting or kayaking, move to shore and away from the water’s edge as soon as possible. When boating, seek shelter below deck after locking off the helm.
If no shelter is available below, tie into a lifeline. Recommendation grade: 1C.
Injuries and Treatment
Triage and Resuscitation
The mechanism of sudden death from lightning strike is simultaneous cardiac and respiratory arrest. The pathophysiology is classically described as an initial asystolic arrest caused by the simultaneous depolarization of all myocardial cells. Ventricular fibrillation may also be observed.
Cardiac automaticity, typically in the form of sinus bradycardia, precedes recovery of the respiratory system. As the medullary respiratory center remains paralyzed despite return of spontaneous circulation (ROSC), a second cardiac arrest may occur if ventilation is not supported. Animal models corroborate this paradigm.
Andrews CDM. Effects of lightning on mammalian tissue. Proceedings of the International Conference of Lightning and Static Electricity. Bath, England; 1989:104.
As ROSC precedes resolution of respiratory arrest, a patient’s ventilation should be supported as soon as possible. This highlights the need for a “reverse triage” system for lightning victims in which priority is initially given to those individuals without vital signs or spontaneous respirations.
In instances of multiple lightning casualties, we recommend using a reverse triage strategy. Recommendation grade 1C.
Resuscitation
Victims of lightning strike do not carry residual electrical charge; it is, therefore, safe to resuscitate these individuals immediately should the scene otherwise be deemed safe. Basic and advanced life support algorithms, including trauma when appropriate, remain the standard of care.
There are numerous case reports of survival with intact neurologic function in lightning victims who received immediate resuscitation; mortality from cardiac arrest is lower in the lightning victims when compared with cardiac arrest in the general population.
The effect of a lightning strike on the cardiovascular system is variable ranging from benign electrocardiographic (ECG) changes to sudden death. Cardiovascular collapse is more commonly associated with direct strikes, whereas more transient ECG changes are seen with contact strikes or ground current.
Initial cardiovascular effects can include ST elevation, prolongation of the QT interval, cardiomyopathy, atrial fibrillation, and elevated cardiac markers.
In one instance, a victim experienced cardiogenic shock and required an intraaortic balloon pump. However, her cardiac function normalized after 72 hours.
including those experiencing a direct strike or those complaining of chest pain or dyspnea, receive a screening ECG and echocardiography. Recommendation grade: 1C
TableHigh-risk indicators in lightning strike victims
Although elevated cardiac markers are commonly reported after lightning strike, such abnormalities are not typically prognostic and do not correlate with anatomic lesions. Routine screening of cardiac markers, therefore, has limited clinical utility.
Patients experiencing a direct strike or those with an abnormal screening ECG or echocardiogram should be monitored with telemetry for a minimum of 24 hours.
discharged patients should be counseled to return should they exhibit new chest pain or dyspnea. Recommendation grade: 1C.
Neurologic
Neurologic injuries are common after lightning strike and range from the transient and incidental to life threatening. These injuries have been categorized on the basis of symptom onset and duration.
As treatment strategies are limited for permanent neurologic injury resulting from lightning strikes, long-term neurorehabilitation is often the sole treatment option for those with permanent disability.
Transient neurologic symptoms with immediate onset
This group accounts for the majority of neurologic manifestations of lightning injury. These include loss of consciousness, seizure, headache, paresthesia or weakness, confusion, and memory loss.
Keraunoparalysis
Transient paralysis after lightning strike has been documented in numerous case reports and is postulated to result from an overstimulation of the autonomic nervous system, leading to vascular spasm.
Typically, lower limbs are affected more than upper limbs. Signs and symptoms include lack of pulse, pallor or cyanosis, and motor and sensory loss in the affected extremities. Keraunoparalysis typically resolves within several hours. As keraunoparalysis may mimic a pulseless victim, be vigilant to check a central pulse before starting cardiopulmonary resuscitation.We recommend hospital observation for keraunoparalysis. This phenomenon typically resolves spontaneously but may indicate more serious underlying trauma.
Keraunoparalysis can mimic a spinal injury; thus, spinal precautions should be maintained and diagnostic imaging should be performed to rule out spinal cord injury if neurologic deficits persist despite resolution of pallor or pulselessness.
Lightning-induced intracranial hemorrhage may also occur instantly, most commonly affecting the basal ganglia or brainstem; this is believed to be attributable to preferential conduction of electricity through these areas of the brain.
A multitude of delayed neurologic syndromes have been reported in victims struck by lightning. However, causality to lightning strike has not been clearly established and the underlying pathophysiology is not yet understood.
We recommend that anyone with delayed neurologic symptoms seek follow-up and treatment recommendations from a neurologist as soon as medically feasible. Recommendation grade: 2C.
Central nervous system injuries associated with secondary trauma and blast effect
Any person having been struck by lightning should have a thorough examination for traumatic head injuries. All lightning strike victims with loss of consciousness or a persistently abnormal neurologic examination should receive a computerized tomography scan of the head.
A transient “ferning” or “feathering” pattern known as the Lichtenberg figure is pathognomonic for lightning strike. It is not a burn, although its pathogenesis remains controversial.
This finding generally presents within 1 hour of lightning strike, and resolves in less than 24 hours. No histological change or damage has been found on biopsy, although pigment changes in the deeper layers of the skin may persist.
Treatment for these figures is not required, but their presence requires evaluation for other effects of lightning strike. Recommendation grade: 1C.
Burns
Burns associated with lightning injury include linear burns, punctate burns, and full-thickness burns. Linear burns are typically partial-thickness burns that result as sweat vaporizes into steam when lightning travels over the skin (also known as “flashover”). Areas that have heavy sweat concentration such as the underarms and beneath the breasts tend to be most affected.
Punctate burns are clustered circular burns believed to be the result of current passing out from the underlying deep tissue. An example is the “tip-toe” sign; these are small (usually <1 cm) full-thickness burns found at the distal toes or sole of the foot. These burns are thought to result from current exiting the body. Punctate burns can also be caused by water droplets on the skin (from sweat or rain) becoming superheated and turning to steam from the energy of a lightning strike. Larger full-thickness burns are typically found in areas where the skin is in direct contact with synthetic fabric that melts onto skin or a metal object that is heated by the electrical energy of the lightning strike.
Full-thickness burns requiring skin grafting are uncommon; only 10% of lightning victims required skin grafting in a case series of 16 patients treated in a burn unit.
It is worth noting that the presence of cranial burns predicted a 3-fold increase in mortality in one series, and these patients were twice as likely to undergo cardiac arrest.
In limited case series, superficial burns related to lightning that involve less than 20% of total body surface area tend to heal quickly and may be treated with routine burn care.
Ocular injuries are common after lightning strike and may affect the anterior and posterior chambers. Damage may result from a number of mechanisms, including passage of current through the lens, blunt and blast trauma, vasoconstriction, or heat. The lens is commonly injured after lightning strike. Cataracts, often bilateral, comprise the majority of these injuries although their exact incidence is not reliably known.
Visual prognosis is dependent on the extent of irreversible retinal damage and optic nerve injury as well as cataract formation. Ophthalmology evaluation is essential for all survivors of a high-risk (Table) lightning strike and for any victim who develops vision loss as soon as medically feasible. Recommendation grade: 1C.
Ear
The audiovestibular system is vulnerable to lightning, as it is a low-resistance pathway.
Rupture may occur through a combination of blast trauma and electrical injury. Uncomplicated TM rupture usually heals spontaneously and can be managed conservatively. Otorrhea may be a sign of underlying basilar skull fracture and secondary trauma. Sensorineural deafness is also common after lightning strike and is usually transient. However, passage of current through the temporal bone may cause microhemorrhages and microfractures to the deeper structures of the ear, resulting in permanent hearing loss.
Initial evaluation for TM integrity is necessary in all lightning strike victims; follow-up with an otolaryngologist is essential for victims with hearing loss. Recommendation grade: 1C.
Psychiatric and Neurocognitive
A number of poststrike psychiatric and cognitive dysfunctions are described in the literature.
These are typically divided into functional or behavioral categories. Functional deficits include abnormalities in memory and concentration including a reduced capacity for problem solving. Behavioral problems include depression, sleep disturbances, emotional lability, and aggressive behavior. These syndromes typically develop in days to weeks after a lightning strike, usually after the individual has returned from the wilderness setting. Victims and their families can be referred to one of several lightning support networks that may provide further counseling on the long-term sequelae of lightning injury. (Lightning Strike and Electric Shock Survivors International, Inc: http://www.lightning-strike.org; e-mail: info@lightning-strike.org; phone: (910) 346-4708.)
The lightning strike victim and his or her family should be counseled by primary providers to watch for symptoms of neuropsychiatric dysfunction and should seek specialized care from a mental health professional should such symptoms manifest. Recommendation grade: 1C.
Pregnancy
Lightning strikes in pregnancy are rare, with only 13 cases reported in the literature.
Among these victims, maternal mortality is zero, although fetal mortality approaches 50%. The fetus is likely at higher risk than the mother because it is surrounded by highly conductive amniotic fluid.
Pregnant women greater than 20 weeks’ gestation who have been struck by lightning should be evacuated to a hospital for lightning-associated injury screening and fetal monitoring. In general, pregnancies less than 20 weeks are not considered viable and do not require fetal monitoring. Recommendation grade: 1C.
Disposition and Evacuation
Individuals with high-risk indicators (Table) should be evacuated immediately after the scene is determined to be safe for rescuers. Lower-risk lightning injuries and other casualties should be triaged and evacuated based on their injuries and overall medical condition. Recommendation grade: 1C.
Conclusions
This article provides an updated summary of available evidence for the prevention and treatment of lightning injury. Although numerous case reports have been published since the original practice guidelines were released in 2012, the summary recommendations remain largely unchanged. Most available data continue to be based on small, retrospective case reports or series because the prospective study of lightning injuries is not logistically and ethically possible. Although the strength of the overall evidence is limited, the authors still believe that many recommendations can be strongly supported [1C] as there is little risk of associated harm. Improved reporting to a national or international database could help with future epidemiological studies. Consensus on injury classification systems would also simplify the reporting process and allow data to be more easily combined for future study. (Also see the online Supplementary Evidence Table 2.)
Cherington M, Walker J, Boyson M, Glancy R, Hedegaard H, Clark S. Closing the gap on the actual numbers of lightning casualties and deaths. 11th Conference on Applied Climatology. Dallas, TX: American Meteorological Society; 1999:379–380.
Lightning injuries: prevention and on-site treatment in mountains and remote areas. Official guidelines of the International Commission for Mountain Emergency Medicine and the Medical Commission of the International Mountaineering and Climbing Federation (ICAR and UIAA MEDCOM).
Bandara K. Lightning hazards: impacts and responses of the public. 18th Annual International Lightning Detection Conference. Helsinki, Finland: Vaisala; 2004.
Overview of Real-Time Lightning Detection Systems and Their Meteorological Uses..
U.S. Dept. of Commerce, National Oceanic and Atmospheric Administration, Environmental Research Laboratories, National Severe Storms Laboratory; for sale by the National Technical Information Service,
Norman, OK; Springfield, VA1993
Andrews CDM. Effects of lightning on mammalian tissue. Proceedings of the International Conference of Lightning and Static Electricity. Bath, England; 1989:104.
To provide guidance to clinicians about best practices, the Wilderness Medical Society convened an expert panel to develop evidence-based guidelines for the treatment and prevention of lightning injuries. These guidelines include a review of the epidemiology of lightning strikes and recommendations for the prevention of lightning strikes, along with treatment recommendations organized by organ system. Recommendations are graded based on the quality of supporting evidence according to criteria put forth by the American College of Chest Physicians.
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