1/8/2023 0 Comments Altitude sickness medicationSome common destinations (such as the ones mentioned above) require rapid ascent by airplane to >3,400 meters, placing travelers in the high-risk category ( Table 3-04). The goal for the traveler may not be to avoid all symptoms of altitude illness but to have no more than mild illness. Creating an itinerary to avoid any occurrence of altitude illness is difficult because of variations in individual susceptibility, as well as in starting points and terrain. Given a baseline susceptibility, 3 factors largely influence the risk of a traveler developing altitude illness: elevation at destination, rate of ascent, and exertion ( Table 3-04). How a traveler has responded to high elevations previously is the most reliable guide for future trips if the elevation and rate of ascent are similar, although this is not an infallible predictor. Children are equally susceptible as adults people aged >50 years slightly so. Training or physical fitness do not affect risk. Susceptibility and resistance to altitude illness are genetic traits, and no simple screening tests are available to predict risk. Inadequate acclimatization may lead to altitude illness in any traveler going to 8,000 ft (2,500 m) or higher, and sometimes even at lower elevations. Expanded red-cell production does not play a role in acute acclimatization, although hemoglobin concentration is increased within 48 hours because of diuresis and decreased plasma volume. Increase in ventilation is the most important factor in acute acclimatization therefore, respiratory depressants must be avoided. Acclimatization prevents altitude illness, improves sleep and cognition, and increases comfort and well-being, although exercise performance will always be reduced compared to what it would be at lower elevations. The process of acute acclimatization to high elevation takes 3–5 days therefore, acclimatizing for a few days at 8,000–9,000 ft (2,500–2,750 m) before proceeding to a higher elevation is ideal. The human body adjusts very well to moderate hypoxia,but requires time to do so ( Box 3-05). ![]() Sleeping at high elevation produces the most hypoxemia day trips to high elevations with return to low elevation are much less stressful on the body. The magnitude of hypoxic stress depends on elevation, rate of ascent, and duration of exposure. At an elevation of 10,000 ft (3,000 m) above sea level, for example, the inspired PO2 is a little more than two-thirds (69%) what it is at sea level. The biggest concern, however, is hypoxia. There also have been reports of people with penicillin allergy having allergic reaction to acetazolamide.Ī type of steroid called dexamethasone has also been shown to help and is an option for those that cannot tolerate acetazolamide.Environments significantly above sea level expose travelers to cold, low humidity, increased ultraviolet radiation, and decreased air pressure, all of which can cause problems. This medication is related to sulfa drugs and should not be used by those allergic to sulfa. It works by acidifying the blood and thus increasing the breathing rate. ![]() One such medication is acetazolamide (Diamox). There are certain medications you can take to prevent and treat altitude sickness. ![]() The body is trying to adapt to the new altitude and in the process, blood vessels become leaky. Here’s what happens in altitude sickness. ![]() They are similar to what one may experience with a very bad hangover: headache fatigue, nausea, vomiting, and loss of appetite. The symptoms usually begin about 6 to 12 hours after higher altitude. If you have had altitude sickness in the past, you are more likely to have it again. Physical fitness and training does not matter. Anyone travelling to high altitudes (above 6,000-8,000 feet) needs to know the signs and symptoms of altitude sickness.
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