High altitude medicine: Difference between revisions
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== Altitude Stages == | == Altitude Stages == | ||
{| class="wikitable" | |||
| align="center" style="background:#f0f0f0;"|'''Stage''' | |||
| align="center" style="background:#f0f0f0;"|'''Altitude''' | |||
| align="center" style="background:#f0f0f0;"|'''Physiology''' | |||
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| Intermediate Altitude ||5000-8000ft||Decreased exercise performance without major impairment in SaO2 | |||
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| High Altitude||8000-12,000ft||Decreased SaO2 with marked impairment during exercise and sleep | |||
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| Very High Altitude ||12,000-18,000ft||Abrupt ascent can be dangerous; acclimatization is required to prevent illness | |||
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| Extreme Altitude ||>18,000ft|| | |||
*Only experienced by mountain climbers; accompanied by severe hypoxemia and hypocapnia | |||
*Sustained human habitation is impossible | |||
*RV strain, intestinal malabsorption, impaired renal function, polycythemia | |||
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== Physiology of Acclimatization == | == Physiology of Acclimatization == | ||
Revision as of 04:35, 5 March 2015
Altitude Stages
| Stage | Altitude | Physiology |
| Intermediate Altitude | 5000-8000ft | Decreased exercise performance without major impairment in SaO2 |
| High Altitude | 8000-12,000ft | Decreased SaO2 with marked impairment during exercise and sleep |
| Very High Altitude | 12,000-18,000ft | Abrupt ascent can be dangerous; acclimatization is required to prevent illness |
| Extreme Altitude | >18,000ft |
|
Physiology of Acclimatization
Ventilation
- Increased elevation -> decreased partial pressure of O2 -> decreased PaO2
- Hypoxic ventilatory response results in incr ventilation to maintain PaO2
- Vigor of this inborn response relates to successful acclimatization
- Initial hyperventilation is attenuated by respiratory alkalosis
- As renal excretion of bicarb compensates for resp alkalosis, pH returns toward normal
- At this point ventilation continues to increase
- Process of maximizing ventilation culminates 4-7d at a given altitude
- With continuing ascent the central chemoreceptors reset to ever lower values of PaCO2
- Completeness of acclimatization can be gauged by partial pressure of arterial CO2
- Acetazolamide, which results in bicarb diuresis, can facilitate this process
- As renal excretion of bicarb compensates for resp alkalosis, pH returns toward normal
Blood
- Erythropoietin level begins to rise within 2d of ascent to altitude
- Takes days to weeks to significantly increase red cell mass
- This adaptation is not important for the initial initial acclimatization process
Fluid Balance
- Peripheral venoconstriction on ascent to altitude causes increase in central blood volume
- This leads to decreased ADH -> diuresis
- This diuresis, along with bicarb diuresis, is considered a healthy response to altitude
- One of the hallmarks of AMS is antidiuresis
Cardiovascular System
- SV decreases initially while HR increases to maintain CO
- Cardiac muscle in healthy pts can withstand extreme hypoxemia w/o ischemic events
- Pulmonary circulation constricts w/ exposure to hypoxia
- Degree of pulm HTN varies; a hyperreactive response is associated with HAPE
Differential Diagnosis
High Altitude Illnesses
- Acute mountain sickness
- Chronic mountain sickness
- High altitude cerebral edema
- High altitude pulmonary edema
- High altitude peripheral edema
- High altitude retinopathy
- High altitude pharyngitis and bronchitis
- Ultraviolet keratitis
High Altitude Syndromes
- All caused by hypoxia
- All are seen in rapid ascent in unacclimatized pts
- Hypoxemia is maximal during sleep; the altitude in which you sleep is most important
- Above 10,000ft rule of thumb is to sleep no higher than 1000 additional ft/day
- All respond to O2/descent
See Also
Source
- Tintinalli