Medical issues associated with commercial flights.

Almost 2 billion people travel aboard commercial airlines every year. Health-care providers and travellers need to be aware of the potential health risks associated with air travel. Environmental and physiological changes that occur during routine commercial flights lead to mild hypoxia and gas expansion, which can exacerbate chronic medical conditions or incite acute in-flight medical events. The association between venous thromboembolism and long-haul flights, cosmic-radiation exposure, jet lag, and cabin-air quality are growing health-care issues associated with air travel. In-flight medical events are increasingly frequent because a growing number of individuals with pre-existing medical conditions travel by air. Resources including basic and advanced medical kits, automated external defibrillators, and telemedical ground support are available onboard to assist flight crew and volunteering physicians in the management of in-flight medical emergencies.

Introduction

Fitness for air travel is a growing issue because many passengers are unaware of health implications associated with commercial air travel. Almost 2 billion people travel by air every year,1, 2 and physicians are now expected to identify individuals unfit for air travel and give them advice. More than 95% of individuals with health problems who have to travel by air would like to receive more medical advice from their physician. Also, the age of travellers is increasing and long-haul aircrafts—such as the Airbus A380 and Boeing 777 LR—are now capable of extending flight times to 18–20 h; therefore, an increasing number of travellers with various underlying medical conditions could face environmental and physiological changes associated with the flight. Here, we review the health issues associated with commercial air travel.

Cabin pressure

Cabin pressure can affect the health and wellbeing of passengers in many ways, including hyobaric hypoxia affecting those with pre-existing respiratory conditions and heart failure, and gas expansion within body cavities and medical devices.

Although commercial flights usually cruise at altitudes of 7010–12 498 m above sea level, the passenger cabin is pressurised to an altitude of 1524–2438 m. Most regulatory governmental agencies require the cabin altitude not to exceed 2438 m.4, 5, 6 Most healthy individuals tolerate this cabin pressure; however, a study of adult volunteers simulating a 20-h flight showed that the frequency of reported complaints associated with acute mountain sickness (fatigue, headache, lightheadedness, and nausea) increased with increasing altitude and peaked at 2438 m, with most symptoms becoming apparent after 3–9 h of exposure. Cabin pressurisation to 2438 m reduces the atmospheric pressure of the cabin, resulting in a concomitant decrease of arterial oxygen partial pressure (PaO2) from 95 mm Hg to 60 mm Hg at the maximum cabin altitude of 2438 m. In healthy passengers, these pressures lead to a 3–4% decrease in systemic oxyhaemoglobin saturation (the corresponding PaO2 value remains within the flat portion of the oxyhaemoglobin dissociation curve) (figure ).5, 7 However, many passengers with pre-existing cardiac, pulmonary, and haematological conditions have a reduced baseline PaO2, so reduced cabin pressure leads to further reduction of oxygen saturation, which lowers further with increasing flight times (figure).8, 9 The decreased oxygen saturation can exacerbate medical conditions.2, 4, 9, 10 For example, a recent prospective observational study showed that 18% of passengers with chronic obstructive pulmonary disease have at least mild respiratory distress during a flight.

Figure

Effect of cabin altitude on oxyhaemoglobin saturation

(A) The aircraft passenger cabin is normally pressurised to an altitude of 1524–2438 m. This reduced pressure within the passenger cabin results in lower systemic PaO2 and decreased oxyhaemoglobin. For most healthy passengers, this results in a decrease in the arterial partial pressure oxygen tension from 95 mm Hg (12·7 kPa) to 65 mm Hg (8·7 kPa) corresponding to an oxyhaemoglobin saturation from 95–100% at sea level (A) to 90% at a cabin altitude of 2438 m (B). (B) Passengers with pre-existing lower sea-level oxyhaemoglobin saturations have greater declines during a flight. In this example, a passenger with mild chronic obstructive pulmonary disease with a sea-level PaO2 of 70 mm Hg (A) and a FEV1 of 1·6 L (50% predicted) will have a corresponding reduction of PaO2 to about 53 mm Hg or oxyhaemoglobin saturation of approximately 84% at a cabin altitude of 2438 m (B). This passenger should be prescribed oxygen for air travel. PaO2=arterial oxygen partial pressure. FEV1=forced expiratory effort in 1 second.

Several methods are available to assess the need for in-flight oxygen (panel 1 ).9, 10, 12, 13 Oxygen supplementation is recommended for passengers with either a resting oxygen saturation of 92% or lower (PaO2 ≤67 mm Hg) or if the expected in-flight PaO2 is less than 50–55 mm Hg. Guidelines from the British Thoracic Society (BTS) suggest hypoxic-challenge testing in individuals with resting oxygen saturations of 92–95% at sea level who have additional risk factors, such as hypercapnia or abnormal spirometry. The Aerospace Medical Association (AsMa) guidelines suggest sea-level blood gas determination or pulmonary-function testing with hypoxic-challenge testing as the gold standard, and recommend in-flight oxygen for individuals with a sea-level PaO2 of 70 mm Hg or lower, or with an expected in-flight PaO2 of 55 mm Hg or lower. However, some evidence suggests that these guidelines might need revision because predictive equations often inaccurately estimate in-flight PaO2.2, 9, 12, 14, 15, 16 Additionally, recent work has shown that initial sea-level oxygen saturation poorly identifies individuals at risk of desaturation below 90% during either hypoxic-challenge testing in the laboratory17, 18 or routine commercial flights.15, 17 No studies that assess individuals with heart failure during commercial air travel exist; however, several small studies have shown that people with chronic heart failure tolerate altitudes up to 2500–3000 m.19, 20 BTS or AsMa guidelines should be followed with patients affected by heart failure who have to travel by air.

Hypoxic-challenge test (hypoxia altitude simulation test):

The maximum cabin altitude of 2438 m can be simulated at sea level with a gas mixture containing 15% oxygen in nitrogen. Individuals breathe the hypoxic gas mixture for 20 min while oxygen saturation is monitored. Arterial blood gases are also measured before and at the end of the test. An individual needs in-flight oxygen if PaO2 falls below 50 mm Hg or if the oxygen saturation measured via pulse oximetry falls below 85%.

Predictive Dillard equations:

PaO2 at altitude can be estimated with several published predictive equations, which use values of ground-level PaO2 and lung-function measurements to predict in-flight PaO2:

In-flight PaO2=0·453×ground-level PaO2 (mm Hg)+0·386 (FEV1% predicted)+2·44

In-flight PaO2=0·519×ground-level PaO2 (mm Hg)+11·855×FEV1 (L)−1·760

Several options exist for passengers needing medical oxygen during air travel. Compressed oxygen supplied by the airline is available for individuals with a physician's statement of need and prescription. Since 2005, portable oxygen concentrators, which concentrate oxygen in ambient air by removing nitrogen content, have become available as an alternative to traditional oxygen cylinders. Passengers should possess a signed doctor's statement of medical need and notify the airline of their intention to use portable oxygen concentrators before travelling. Because of a modification in the US Government Air Carrier Access Act in May, 2008, all US-based air carriers and foreign air carrier flights that begin or end in the USA have to accommodate passengers who need portable oxygen concentrators.

Gas in body cavities is also affected by cabin pressure. According to Boyle's law, the volume that a gas occupies is inversely proportional to the surrounding pressure. Thus, at the low cabin pressures associated with cruising altitudes, gas in body cavities expands by 30%.6, 10, 23 For healthy passengers, this expansion can result in minor abdominal cramping and barotrauma to the ears in certain circumstances. However, passengers who have undergone recent surgical procedures are at increased risk of problems related to gas expansion, and many anecdotal reports, including those of bowel perforation and wound dehiscence, have been published. Guidelines recommend delaying air travel for 14 days after major surgical procedures.10, 23 Individuals with bowel obstructions or diverticulitis are advised to wait 7–10 days before air travel.10, 23

Passengers who scuba dive also have an increased risk of decompression sickness if they fly too soon after diving. The diver's alert network recommends a 12-h interval between diving and air travel for divers who make a dive per day without decompression. Divers participating in several dives per day, or a dive requiring decompression, should wait 24 h before air travel.10, 23

Gas expansion also affects medical devices, such as pneumatic splints, feeding tubes, urinary catheters, and cuffed endotracheal or tracheostomy tubes. Gas-expansion concerns in these devices can be eliminated by instillation of water rather than air during air travel.6, 26

Air travel and venous thromboembolism risk

The relation between long-haul flights (>8 h) and increased risk of venous thromboembolism has generated great interest in both medical publications and the media. Overall, studies show an association between venous thromboembolism and long-haul air travel, with risk up to four-fold, depending on study methods.27, 28, 29, 30, 31, 32, 33

Risk peaks when flight duration is more than 8 h;34, 35, 36 a population-based study showed that risk started to increase when flight duration exceeded 4 h. Business-class versus economy-class travel has no effect on venous thromboembolism incidence. A systematic review of publications on air-travel venous thromboembolism calculated a pooled odds ratio (OR) of 1·59 (95% CI 1·04–2·43) from case–control studies27, 38, 39, 40, 41 and a relative risk of 2·93 (95% CI 1·5–5·58) from several prospective controlled cohort studies.38, 40 These results are consistent with those of the population-based (MEGA) study (OR 1·7, 95% CI 1·0–3·1). Another population-based study of 9000 business travellers followed for 4·4 years showed an absolute risk for venous thromboembolism of one every 4656 flights (incidence rate ratio 3·2, 95% CI 1·8–5·6). Risk increased with increasing number of flights during the first 2 weeks after a flight and when other traditional risk factors for venous thromboembolism were present. Several factors—such as immobility, dehydration, hypobaric hypoxia—and individual risk factors (obesity, malignancy, recent surgery, and history of hypercoagulable states) explain why the risk of venous thromboembolism increases with air travel.40, 42

Immobilisation has been linked to 75% of air-travel cases of venous thromboembolism, with the long-flight thrombosis study (LONFLIT) showing the greatest frequency of venous thromboembolism occurring in non-aisle seating where passengers tend to move less.42, 43, 44, 45

Dehydration can increase risk of venous thromboembolism due to haemoconcentration and hyperviscosity, potentially leading to hypercoagulable states. Several studies have provided evidence of dehydration or increased lower-limb oedema in healthy people during long-simulated flights.47, 48 Hypobaric-chamber studies have not consistently shown that the mild hypobaric hypoxic changes during a flight lead to increased activation of coagulation in healthy individuals with no thrombophilia compared with that in individuals seated and not moving at ground level.5, 46, 49

Thrombophilia or oral contraceptive use substantially increase the risk of developing venous thromboembolism.29, 32, 50 In the MEGA study, factor V Leiden increased this risk by 14 times (OR 13·6, 95% CI 2·9–64·2), and thrombophilia or use of oral contraceptives increased risk 16 times (16·1, 3·6–70·9) and 14 times (13·9, 1·7–117·5), respectively.

Recommendations to reduce the risk of developing venous thromboembolism during air travel are based more on common sense than on evidence and include: being well hydrated, reducing alcohol and caffeine consumption, changing positions or walking throughout the cabin, and doing periodic calf-muscle exercises to reduce venous stasis. Use of graduated compression stockings with an ankle pressure of 17–30 mm Hg can reduce risk during air travel, as shown by a meta-analysis, in which only two of 1237 individuals who wore compression stockings had venous thrombosis compared with 46 of 1245 individuals who did not wear them. Compression stockings therefore are recommended for travellers prone to immobility.51, 52, 53

Anticoagulant thromboprophylaxis in the context of air travel is growing but no formal guidelines exist. One survey done by thrombosis and haemostasis professionals showed major differences in the use of prophylactic measures for air travel. Many clinicians seem to recommend aspirin before air travel for individuals at moderate risk of venous thromboembolism. However, because of scarce evidence showing substantial benefit, aspirin is not recommended alone as prophylaxis for any air traveller.41, 43, 52, 55 Although randomised trials have shown benefit of low-molecular-weight heparin as thromboprophylaxis for air travellers who are at moderate risk for venous thromboembolism and do not take routine anticoagulant drugs,43, 56 its routine use in circumstances other than those for air travellers at high risk of venous thromboembolism remains controversial.41, 52

Overall, use of physical and pharmacological thromboprophylaxis should be based on an individual risk assessment. The table summarises evidence-based guidelines updated in 2008 by the American College of Chest Physicians conference on antithrombotic and thrombolytic therapy.

Table

Risk of venous thromboembolism prophylaxis in air travellers

	Definition	Recommendations	Quality of evidence*
Low risk	Flight time less than 8 h or distance less than 5000 km	Avoid constrictive clothing around waist and lower extremities; avoid dehydration; move about cabin several times or do calf-stretching exercises	Grade 1C
Moderate risk	Flight time more than 8 h or distance more than 5000 km, and: obesity, large varicose veins, pregnancy, hormone-replacement therapy, tobacco use or oral contraceptives, or relative immobility	Low-risk measures and: wear properly fitted below-knee compression stockings providing 15–30 mm Hg of pressure at the ankle; aisle seating	Grade 1C and grade 2B
High risk	Flight time more than 8 h or distance more than 5000 km, and: history of previous venous thromboembolism; hypercoagulable state (eg, factor V Leiden); major surgery 6 weeks before air travel (including hip or knee arthroplasty); known malignancy	Moderate-risk measures and: low-molecular-weight heparin injected before departure in individuals who are not on warfarin	Grade 1C and grade 2B

Data are based on references 38, 40, 41, 51, 52, 53, 57.

Grade 1C is a strong recommendation, but existing evidence is of low quality and benefits clearly outweigh risk or burden. Grade 2B is a weak recommendation derived from moderate quality evidence, and benefits of therapy are balanced with risk and burden.

Cosmic-radiation exposure

Cosmic radiation comes from outside the solar system and from particles released during solar flares. Intensity of radiation depends on the year (due to solar cycles), altitude, latitude, and length of exposure. Because many types of cancer might be linked to cosmic radiation—especially breast cancer, skin cancer, and melanoma—effects of radiation on flight crews and frequent air-travellers are of concern.58, 59

In 1991, the International Commission on Radiological Protection (ICRP) declared cosmic radiation an occupational risk for flight crews, which led to exposure monitoring and guidelines to reduce crew annual exposure to 20 mSv, which is more than double the exposure of most crews.60, 61, 62 Ground-radiation exposure should be restricted to 1 mSv per year in the population, but air-travel-related cosmic-radiation exposure does not have a specific limit. The UK Civil Aviation Authority (CAA) and the European Joint Aviation Authority (JAA) require aircraft capable of flying at altitudes greater than 15 km, to actively monitor radiation levels, so that they can lower flying altitude as needed. However, this regulation is currently not relevant to commercial aviation because no commercial aircraft fly at such altitudes.

A solar-radiation alert system monitors high-particle intensity from solar radiation, and the US Federal Aviation Administration (FAA) issues a solar-radiation advisory to air carriers via the national oceanic and atmospheric administration (NOAA) weather wire service when solar flares might cause increased radiations at commercial-aircraft altitudes.

Data for increased cancer risks specifically due to cosmic radiation in crew members are inconclusive.62, 65, 66, 67, 68 No studies have been done to assess the health consequences of cosmic-radiation exposure during air travel in the general population. However, even the most-frequent air travellers are unlikely to be at risk. Recommendations need to be in place for pregnant women because the fetus is exposed to the same radiation dose as the mother. The ICRP recommends a radiation limit of 1 mSv during the whole pregnancy, whereas the National Council on Radiation Protection and Measurements recommends a monthly limit of 0·5 mSv. These recommendations limit pregnant crew members and frequent air travellers, because flying roughly 15 long-haul round trips, for example, can expose a fetus to more than 1 mSv. To avoid risk to the fetus, the FAA recommends pregnant crew members to take short, low-altitude, low-latitude flights, and the CAA requests that employers of a pregnant crew member schedule her flights so that she remains under the 1-mSv limit.7, 59 Pregnant women, and air travellers in general, can access the solar-radiation alert system online before travelling and change flight days accordingly.

Jet lag

Jet lag is a temporary circadian-rhythm disorder associated with long-haul flights, characterised by daytime fatigue, sleep–wake disturbances, decreased appetite, constipation, and reduced psychomotor coordination and cognitive skills.71, 72, 73 Jet lag is due to desynchronisation between the body's internal clock mechanism, residing within the suprachiasmatic nucleus of the hypothalamus,74, 75, 76 and the new light–dark cycle caused by abrupt time-zone changes.72, 73, 77, 78, 79 The degree and severity of jet lag is influenced by both flight direction and number of time zones crossed.72, 80 Westward travel lengthens the traveller's day, thereby causing a phase delay in the circadian rhythm, whereas eastward travel shortens the day and causes a phase advance.72, 73, 80 Travellers have greater difficulty falling asleep after an eastward travel than after a westward travel because of the internal clock's natural tendency to resist shortening the 24-h day cycle.79, 81, 82, 83 Re-entrainment (synchronisation) typically takes one day for every time zone crossed westward or 1·5 days for every time zone crossed eastward.72, 73, 80, 81

Panel 2 lists various therapies available to keep jet lag to a minimum. Exogenous melatonin is the gold standard treatment for jet-lag symptoms.73, 83, 89, 90 When taken in the evening, melatonin phase advances the circadian clock, whereas early morning administration phase delays the circadian rhythm.73, 90 Various treatment regimens have been recommended, but a Cochrane meta-analysis of ten trials concluded that taking 0·5–5 mg of melatonin at the desired destination bedtime is effective for reducing or preventing jet lag.

Agomelatine

New dual melatonin-receptor and serotonin 5-HT2C receptor agonist

Efficacious for symptoms of depression and sleep–wakefulness disorders

Not tested for jet lag, but could be more useful for individuals having westward-travel jet lag, who commonly show symptoms of depression

Benzodiazepines 82, 84, 85

Some reported efficacy in sleep quality (eg, temazepam)

Some reported efficacy in other circadian-rhythm or sleep parameters

Caffeine 82, 86

Poorly studied

Might increase night-time awakenings

Slow-release caffeine showed faster re-entrainment (measured physiologically)

Melatonin 73, 83, 87

Phase advances of about 2·5 h

Usually only needed after arrival but, if travelling across more than 7–8 time zones, pre-treatment for 2–3 days may be needed

Recommended especially if crossing five or more time zones, travelling eastwardly, or with a history of jet-lag symptoms

Caution in people with epilepsy or on warfarin (case reports of adverse effects)

Paediatric use not studied and therefore not recommended

Ramelteon

New melatonin-receptor agonist with no abuse potential

Indication for treatment of primary insomnia in individuals of 55 years of age or older

Untested for circadian-rhythm disturbances

Phototherapy 72, 80, 81

Involves intentional exposure or avoidance to bright light to hasten re-entrainment

Efficacy is questionable

Often impractical or inconvenient

Pre-flight sleep hygiene 72, 81, 88

Westbound: go to sleep 1 h later than usual and be awake 1 h later than usual 3 days before travelling

Eastbound: go to sleep 1 h earlier than usual and be awake 1 h earlier than usual 3 days before travelling

Use of bright-light exposure to adjust circadian rhythm has shown conflicting results and its benefit depends on combination with other therapies, such as bedtime adjustment or melatonin.91, 92, 93 Simulation studies showed a benefit of gradually advancing the sleep cycle by going to sleep 1 h earlier than usual every day for 3 days before travelling eastward, combined with morning bright-light exposure, in an attempt to phase advance the circadian rhythm.87, 92 For westward travel, one small randomised controlled study of 20 individuals combined bedtime adjustment with timed bright-light versus dim-light exposure after westward travel, and showed larger phase delays in the bright-light group than in the dim-light group (2·59 h vs 1·5 h, p <0·02), but no significant difference in sleep efficiency or self-reported symptoms of jet lag.

Infectious diseases and air travel

Air travellers spend long periods in enclosed spaces, which facilitates the spread of infectious diseases. Since 1946, several outbreaks of serious infectious diseases have been reported aboard commercial airlines, including influenza,94, 95 measles, severe acute respiratory syndrome (SARS),97, 98 tuberculosis,99, 100 food poisoning,101, 102 viral enteritis, and small pox. Although less-serious outbreaks—such as the common cold or some viral syndromes—have not been reported, they can occur. Lack of reporting is likely to be the result of incubating periods of many infections being longer than the flight. One prospective questionnaire study of air travellers going from San Francisco to Denver during the winter months showed an upper-respiratory tract infection frequency of 3–20% depending on the reporting methods. PCR assays to study atypical bacteria and respiratory viruses in 155 air travellers showed that not many travellers had the same viral profile and no association existed between any pathogen and a particular airport, suggesting that travellers acquired their viruses before rather than during the flight.

Most commercial aircrafts re-circulate up to 50% of the cabin air and use high-efficiency particulate air filters. One study showed no significant difference in self-reported infection rates in aircrafts that use these filters compared with those in aircrafts that use a single-pass cabin ventilation system.

Risk of onboard transmission of infection is mainly restricted to individuals with either close personal contact or seated within two rows of an index passenger.1, 107 However, on Air China flight 112, 22 passengers and crew member developed probable onboard severe acute respiratory syndrome-associated coronavirus (SARS-CoV) infection. The 2002–03 SARS epidemic indicated that commercial air travel has an effect on infectious-disease spread. WHO estimates that 6·5 passengers per million who travelled aboard commercial flights originating from regions of active transmission during the outbreak were symptomatic with probable SARS. Overall, 40 flights carried 37 probable SARS-CoV source cases during the outbreak, resulting in 29 probable onboard secondary cases.

Whether reducing the number of flights during a large-scale epidemic or pandemic would slow the spread of an infectious-disease outbreak remains unclear.109, 110 An observational study, however, showed that the peak date of the US influenza season was delayed 13 days after the terrorist attacks of Sept 11, 2001, consistent with a greatly reduced number of flights during that time. This, together with other modelling studies, suggest that flight limitations might slow the spread of pandemic influenza by several weeks, thereby providing time for mass vaccination of the population and contingency plan setup.

In-flight medical events

Calculation of the exact incidence of in-flight medical events for commercial air travel has always been difficult, mainly because air carriers are not obliged to report in-flight medical events, and no national or international database exists. Scarce data suggest an incidence of 1 in 10 000–40 000 passengers (about 50–100 in-flight medical events per day) aboard US-registered airlines. British Airways health services reported 31 200 medical incidents aboard their aircrafts during 2007, with 3000 being deemed serious.

Many in-flight medical events arise aboard commercial airlines and most are minor.6, 114 Cardiac, neurological, and respiratory complaints are the most serious in-flight medical events, with cardiac and neurological complaints accounting for most diversions. Passengers older than 70 years have the highest rates of in-flight medical events, but the mean age of passengers with an in-flight medical event is 44 years for men and 49 years for women.6, 112

According to British, Canadian, and US laws, medical professionals are not required to volunteer assistance during an in-flight medical event, unless they have a pre-existing clinical relationship with the passenger. In contrast, physicians in Australia and many Asian, European, and middle east countries are required to provide assistance. For international flights, the country where the aircraft is registered has jurisdiction, except when the aircraft is on the ground or in sovereign airspace.6, 112 Medical assistance during an in-flight medical event is protected under Good Samaritan laws, and no physician has ever been held liable for his or her actions while providing medical care. The 1998 US Aviation Medical Assistance Act limits liability for volunteering physicians under the assumption that they act in good faith, receive no monetary compensation, and provide reasonable care. This law pertains to events that occur within US airspace and aircraft registered within the USA. Gifts, such as seat upgrades and liquors, are not considered compensation. Furthermore, many airlines indemnify volunteering physicians, and the captain should provide written confirmation on request.

Commercial aircraft have medical kits (1–4 first-aid kits and at least one enhanced emergency medical kit), as required by aviation regulatory agencies.6, 112 Emergency medical kits vary from carrier to carrier and can be extensively complex (panel 3 ). Most commercial flights also carry an automated external defibrillator, and some models have a screen showing a basic rhythm strip. Most commercial air carriers use on-ground telemedical assistance to medically assess at the gate passengers who seem unfit for travel, and to provide medical advice and support during in-flight medical events. Several companies and academic medical institutions provide 24-h ground-to-air medical support and have ground-based physicians, who also advise the flight deck on the best diversion location and arrange emergency personnel to meet the aircraft.

Diagnostic/general

Sphygmomanometer* †

Stethoscope*

Automated external defibrillator

Gloves*

Tape* †

Tourniquet* †

Urinary catheter†

Instructions on use of medications* †

Medications

Allergy

Adrenocortical steroid†

Antihistamine (po and iv)* †

Bronchodilator inhaler* †

Epinephrine* †

Analgesia

Aspirin*

Paracetamol*

Major analgesic drugs (eg, morphine)†

Neurological

Anticonvulsant drugs†

Sedative drugs†

Cardiac or resuscitation

Atropine* †

Epinephrine* †

Digoxin†

Dextrose* †

Diuretic drugs†

Lidocaine*

Nitroglycerine* †

Miscellaneous

Uterine contractant†

Clinicians who offer medical assistance during a flight should know that their role is to assist the flight crew and not to take complete control of the situation. The captain of the aircraft has the ultimate authority (panel 4 ). In case of violent or unruly passengers, volunteering physicians might need to assist in chemical or physical restraint. If chemical restraint is used, physicians should consider that passengers could have ingested alcohol or other substances that might cause oversedation or other effects. Panel 5 lists general guidelines for the initial management of common in-flight medical events.

Be prepared to show medical credential (eg, licence) or answer questions about degree or training

Act within your abilities

Obtain consent from the affected passenger. Assume implied consent when passenger is incapacitated or unresponsive

Do not fear litigation. Although physicians have been deposed, no litigation has ever been brought forward against a responding physician

Request and establish communication with the airline's ground medical support for advice and consultation regardless of how minor or serious the in-flight medical event is

Request the enhanced emergency medical kit (many airlines will initially only offer the basic first-aid kit) but do not open it unless needed. Each kit has a placard listing the contents of the kit

Recommend diversion of the aircraft if you believe it is needed. Recommendation to divert the aircraft should be considered if a passenger has chest pain, shortness of breath, severe abdominal pain that does not improve with initial treatment interventions, cardiac arrest, acute coronary syndrome, severe dyspnoea, stroke, refractory seizure, severe agitation, or if a passenger is persistently unresponsive

Never officially pronounce a passenger dead, even if you assess that resuscitation is futile and cease treatment, especially on international flights

Acute abdominal pain

Administer antiacid if appropriate

Request cabin altitude reduction to increase cabin pressure, which will increase oxygenation and decrease gas expansion

Administer paracetamol or ibuprofen to relieve discomfort. Some medical kits contain morphine, which can be used in cases of extreme pain

A parenteral or oral antiemetic drug if available in the medical kit might help in cases of persistent vomiting

Acute agitation or misconduct

Attempt to de-escalate the situation. Look for medical causes, such as hypoxia or hypoglycaemia

Offer or administer benzodiazepine, if available and indicated (be aware for possible oversedative effect, if passenger is already taking other substances)

If physical restraint is needed, it should be undertaken by 4–5 individuals. The restrained individual should be placed in the left lateral recumbent position

Appropriately monitor patient if chemical or physical restraints are used. Be aware of high risk of complications (hypoxia, metabolic acidosis, and sudden death) because of fighting against restraints coupled with recent extreme exertion by the agitated passenger

Acute allergic reaction and anaphylaxis

Administer diphenhydramine 12·5 mg po, im, or iv (paediatric); 25–50 mg po, im, or iv(adult) for both simple allergic reactions and anaphylaxis

Administer epinephrine 0·01 mL/kg/dose 1 in 1000 solution im or sc every 5–20 min as needed up to three doses (paediatric), or 0·3–0·5 mL 1 in 1000 solution im or sc every 5–20 min as needed up to three doses (adults) in the presence of severe generalised urticaria, angio-oedema, stridor, or bronchospasm

Establish iv access and administer fluids in presence of anaphylaxis if possible

Chest pain

If diagnosis is uncertain, an antacid could help to confirm dyspepsia

For persistent pain or if myocardial infarction is suspected, administer oxygen, aspirin 325 mg po, and nitroglycerin 0·4 mg sublingual every 5 min up to three doses or morphine sulfate 3 mg iv or im, as indicated

Request cabin altitude reduction to increase cabin pressure

Some airlines carry automated external defibrillators with a cardiac rhythm display to help assess cardiac rhythm

Asthma or chronic obstructive pulmonary disease

Administer oxygen and inhaled bronchodilator (two puffs every 15 min) as indicated

Request cabin altitude reduction to increase cabin pressure

Cardiac arrest

Place automated external defibrillator on patient. Some defibrillators incorporate a rhythm display that can help making decisions

Follow basic life support or advanced cardiac life support resuscitation algorithms

If resuscitation is stopped because of no return of spontaneous circulation, the individual should not be pronounced dead officially on international flights due to medico-legal reasons

Hypoglycemia

If conscious, administer oral glucose gel

If not conscious, establish iv access and administer D50 dextrose (1 amp) for adult or 2 mL/kg of D25 dextrose (D50 diluted 1:1 with normal saline solution) for paediatric

Seizure

Keep passenger away from nearby objects

Do not place anything in passenger's mouth

Administer benzodiazepine if available (diazepam 0·1–0·3 mg/kg iv or im for paediatrics, and 5 mg iv or im for adults)

Unresponsive passenger

Place automated external defibrillator pads on patient

Establish iv access if possible

Administer oxygen, D50 dextrose (1 amp) iv for adult or D25 dextrose (2 mL/kg) for paediatric, naloxone 0·1–2 mg iv or im (if available)

Follow basic life support or advanced cardiac life support resuscitation algorithms

Vasovagal syncope

Lay patient supine and elevate legs if possible

Apply cold compress to forehead

Medical fitness for air travel

Airlines have the right to refuse passengers who are unfit to fly for medical reasons.6, 119 Many conditions contraindicate air travel and passengers who cannot tolerate hypoxia or pressure changes should not fly (panel 6 ). Passengers should be able to walk a distance of 50 m and climb one flight of stairs without angina or severe dyspnoea. If a passenger needs oxygen, he or she requires physician documentation stating fitness to travel at 2438 m. Passengers bringing needles and syringes into the cabin should possess documentation of need and carry the medication that requires that equipment with pharmacy-labelled identification. Some passengers might also need a qualified medical escort, such as passengers whose fitness to travel is in doubt due to possible exacerbation or instability of chronic disease or passengers who have organ failure requiring transplantation. Many air carriers have limited transport of passengers on stretchers or those unable to sit upright in a seat. Numerous air ambulance services and clinics offer physician-assisted or nurse-assisted escorts for commercial air flights, and physicians or passengers can call airlines for assistance.

Cardiac and pulmonary disorders

Myocardial infarction 7–10 days before air travel

Unstable angina

Coronary artery bypass graft 10–14 days before air tarvel

Decompensated heart failure

Uncontrolled dysarythmia

Contagious pulmonary infections

Baseline sea-level PaO2<67–70 mm Hg without supplemental oxygen

Obstructive/restrictive lung-disease exacerbation

Large pleural effusion

Pneumothorax 3 weeks before air travel (7–14 days with medical escort)

Neurological disorders

Stroke 5–10 days before air travel

Uncontrolled seizures or 24–h after grand-mal seizure

Surgical interventions

Any gastrointestinal, thoracic, ear, nose, and throat, and neurological surgical procedure 10–14 days before air travel

Uncomplicated appendectomy or laparoscopic surgery 5 days before air travel

Pregnancy

From 36th week of pregnancy (from 32nd weeks for multiple gestation) up to 7 days after delivery. Doctor certification needed after 28 weeks of pregnancy

Complicated pregnancy

Paediatrics

First week of life

Miscellaneous

Unlikely to survive flight

Severe contagious illness

Sickle-cell disease exacerbation 10 days before air travel

Severe anaemia (haemoglobin <8·5g/dL) unless due to chronic disease

Aggressive unpredictable behaviour or acute psychosis

Severe sinusitis

Decompression syndrome 3–7 days before air travel

Controversies and future directions

Passenger health and wellbeing during commercial air travel continues to evolve. Cabin air quality remains an issue, and it has been linked to passenger and flight crew complaints of dry eyes, stuffy nose, and skin irritation, as well as headaches, lightheadedness, and confusion. Peer-reviewed studies on the effect of vaporised organic compounds, such as tricresyl phosphate, that have led to reported cases of crew and passenger incapacitation are needed. These compounds are the result of vaporised jet oils that can mix with air entering the aircraft cabin. Several research groups, such as the cabin air-quality reference group and the Australian civil aviation safety authority, are addressing knowledge gaps on health effects of cabin air, including the role of vaporised organic compounds.

The American society of heating, refrigerating, and air conditioning engineers—an industry leader in developing indoor air-quality standards—set, for the first time, new air-quality standards in commercial aircrafts. The new standards also address chemical, physical, and biological contaminants that affect cabin air quality. How these standards will be adopted by aviation and governmental regulatory agencies remains unclear. At present, no regulations by the CAA, FAA, or JAA exist requiring use, certification, or maintenance of high-efficiency particulate air. New aircrafts, such as the Airbus A380 and Boeing 787, are being designed to operate at cabin altitude of 1829 m compared with the current altitude of 2438 m, in addition to having improved cabin air quality and passenger seating. These changes will improve passenger wellbeing and comfort.

How individuals with compromised cardiac and pulmonary function can endure long air travel needs to be assessed, and current screening guidelines should undergo re-assessment. Furthermore, absence of a globally accepted guideline, and major differences in the use of prophylactic measures by clinicians for air-travel-related thrombosis emphasise the need for additional studies on interventions and clear guidelines on prevention of air-travel-related venous thrombosis.

The molecular basis for circadian-rhythm disorders has been recently clarified and future clinical application might lead to new treatments for jet lag.

The risk that commercial aircrafts are vehicles of influenza pandemic spread is real and opportunities exist to keep the risk to a minimum. The international air-transport association, in partnership with WHO and other stakeholders, have established guidelines for aviation-industry operations during pandemic influenza outbreaks to keep commercial air-travel spread to a minimum. These include communication of the risk to the population, establishment of national passenger exit screening from outbreak regions, and increasing airline preparedness (in-flight illness and aircraft cleaning).127, 128

In-flight medical events are projected to increase and AsMa encourages the creation of a database, but many air carriers are reluctant to participate. Commercial space travel is projected to start within the next decade and aerospace medical societies have set up subcommittees to address the unique medical conditions associated with civilian space travel.

In the modern travel era, clear understanding of the medical consequences of commercial flights has become increasingly important. Individuals need to be aware of the possible medical complications of air travel, and physicians should identify people at potential risk from air travel and advise them of any necessary treatments to travel safely.

Search strategy and selection criteria

We searched Medline for peer-reviewed publications over the past 10 years written in English, with the keywords “air travel”, together with “hypoxia”, “surgery”, “cosmic radiation”, “jet lag”, “venous thromboembolism”, “infectious diseases”, “pandemic”, and “in-flight medical emergencies”. Titles, abstracts, or both, of all articles were reviewed to assess relevance. We reviewed governmental reports from the UK Department of Transport Civil Aviation Authority, UK House of Lords, US Federal Aviation Administration, and documents published by the British Thoracic Society, Aerospace Medical Association, WHO, US Institute of Medicine, and the International Commission on Radiological Protection. We also searched the above keywords with the Google search engine.