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The Effects Of Altitude On Human Physiology

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The Effects of Altitude On Human Physiology


Changes in altitude have a profound effect on the human body. The body


attempts to maintain a state of homeostasis or balance to ensure the optimal


operating environment for its complex chemical systems. Any change from this


homeostasis is a change away from the optimal operating environment. The body


attempts to correct this imbalance. One such imbalance is the effect of


increasing altitude on the body’s ability to provide adequate oxygen to be


utilized in cellular respiration. With an increase in elevation, a typical


occurrence when climbing mountains, the body is forced to respond in various


ways to the changes in external environment. Foremost of these changes is the


diminished ability to obtain oxygen from the atmosphere. If the adaptive


responses to this stressor are inadequate the performance of body systems may


decline dramatically. If prolonged the results can be serious or even fatal. In


looking at the effect of altitude on body functioning we first must understand


what occurs in the external environment at higher elevations and then observe


the important changes that occur in the internal environment of the body in


response.


HIGH ALTITUDE


In discussing altitude change and its effect on the body mountaineers


generally define altitude according to the scale of high (8,000 – 12,000 feet),


very high (12,000 – 18,000 feet), and extremely high (18,000+ feet), (Hubble,


1995). A common misperception of the change in external environment with


increased altitude is that there is decreased oxygen. This is not correct as the


concentration of oxygen at sea level is about 21% and stays relatively unchanged


until over 50,000 feet (Johnson, 1988).


What is really happening is that the atmospheric pressure is decreasing


and subsequently the amount of oxygen available in a single breath of air is


significantly less. At sea level the barometric pressure averages 760 mmHg while


at 12,000 feet it is only 483 mmHg. This decrease in total atmospheric pressure


means that there are 40% fewer oxygen molecules per breath at this altitude


compared to sea level (Princeton, 1995).


HUMAN RESPIRATORY SYSTEM


The human respiratory system is responsible for bringing oxygen into the


body and transferring it to the cells where it can be utilized for cellular


activities. It also removes carbon dioxide from the body. The respiratory system


draws air initially either through the mouth or nasal passages. Both of these


passages join behind the hard palate to form the pharynx. At the base of the


pharynx are two openings. One, the esophagus, leads to the digestive system


while the other, the glottis, leads to the lungs. The epiglottis covers the


glottis when swallowing so that food does not enter the lungs. When the


epiglottis is not covering the opening to the lungs air may pass freely into and


out of the trachea.


The trachea sometimes called the “windpipe” branches into two bronchi


which in turn lead to a lung. Once in the lung the bronchi branch many times


into smaller bronchioles which eventually terminate in small sacs called alveoli.


It is in the alveoli that the actual transfer of oxygen to the blood takes place.


The alveoli are shaped like inflated sacs and exchange gas through a


membrane. The passage of oxygen into the blood and carbon dioxide out of the


blood is dependent on three major factors: 1) the partial pressure of the gases,


2) the area of the pulmonary surface, and 3) the thickness of the membrane


(Gerking, 1969). The membranes in the alveoli provide a large surface area for


the free exchange of gases. The typical thickness of the pulmonary membrane is


less than the thickness of a red blood cell. The pulmonary surface and the


thickness of the alveolar membranes are not directly affected by a change in


altitude. The partial pressure of oxygen, however, is directly related to


altitude and affects gas transfer in the alveoli.


GAS TRANSFER


To understand gas transfer it is important to first understand something


about the behavior of gases. Each gas in our atmosphere exerts its own pressure


and acts independently of the others. Hence the term partial pressure refers to


the contribution of each gas to the entire pressure of the atmosphere. The


average pressure of the atmosphere at sea level is approximately 760 mmHg. This


means that the pressure is great enough to support a column of mercury (Hg) 760


mm high. To figure the partial pressure of oxygen you start with the percentage


of oxygen present in the atmosphere which is about 20%. Thus oxygen will


constitute 20% of the total atmospheric pressure at any given level. At sea


level the total atmospheric pressure is 760 mmHg so the partial pressure of O2


would be approximately 152 mmHg.


760 mmHg x 0.20 = 152 mmHg


A similar computation can be made for CO2 if we know that the concentration is


approximately 4%. The partial pressure of CO2 would then be about 0.304 mmHg at


sea level.


Gas transfer at the alveoli follows the rule of simple diffusion.


Diffusion is movement of molecules along a concentration gradient from an area


of high concentration to an area of lower concentration. Diffusion is the result


of collisions between molecules. In areas of higher concentration there are more


collisions. The net effect of this greater number of collisions is a movement


toward an area of lower concentration. In Table 1 it is apparent that the


concentration gradient favors the diffusion of oxygen into and carbon dioxide


out of the blood (Gerking, 1969). Table 2 shows the decrease in partial pressure


of oxygen at increasing altitudes (Guyton, 1979).


Table 1


ATMOSPHERIC AIR ALVEOLUS VENOUS BLOOD


OXYGEN 152 mmHg (20%) 104 mmHg (13.6%) 40 mmHg CARBON


DIOXIDE 0.304 mmHg (0.04%) 40 mmHg (5.3%) 45 mmHg


Table 2 ALTITUDE (ft.) BAROMETRIC PRESSURE (mmHg) Po2 IN AIR (mmHg)


Po2 IN ALVEOLI (mmHg) ARTERIAL OXYGEN SATURATION (%)


0 760 159* 104 97


10,000 523 110 67 90


20,000 349 73 40 70


30,000 226 47 21 20


40,000 141 29 8 5


50,000 87 18 1 1


*this value differs from table 1 because the author used the value for


the concentration of O2 as 21%. The author of table 1 choose to use the value as


20%.


CELLULAR RESPIRATION


In a normal, non-stressed state, the respiratory system transports


oxygen from the lungs to the cells of the body where it is used in the process


of cellular respiration. Under normal conditions this transport of oxygen is


sufficient for the needs of cellular respiration. Cellular respiration converts


the energy in chemical bonds into energy that can be used to power body


processes. Glucose is the molecule most often used to fuel this process although


the body is capable of using other organic molecules for energy.


The transfer of oxygen to the body tissues is often called internal


respiration (Grollman, 1978). The process of cellular respiration is a complex


series of chemical steps that ultimately allow for the breakdown of glucose into


usable energy in the form of ATP (adenosine triphosphate). The three main steps


in the process are: 1) glycolysis, 2) Krebs cycle, and 3) electron transport


system. Oxygen is required for these processes to function at an efficient level.


Without the presence of oxygen the pathway for energy production must proceed


anaerobically. Anaerobic respiration sometimes called lactic acid fermentation


produces significantly less ATP (2 instead of 36/38) and due to this great


inefficiency will quickly exhaust the available supply of glucose. Thus the


anaerobic pathway is not a permanent solution for the provision of energy to the


body in the absence of sufficient oxygen.


The supply of oxygen to the tissues is dependent on: 1) the efficiency


with which blood is oxygenated in the lungs, 2) the efficiency of the blood in


delivering oxygen to the tissues, 3) the efficiency of the respiratory enzymes


within the cells to transfer hydrogen to molecular oxygen (Grollman, 1978). A


deficiency in any of these areas can result in the body cells not having an


adequate supply of oxygen. It is this inadequate supply of oxygen that results


in difficulties for the body at higher elevations.


ANOXIA


A lack of sufficient oxygen in the cells is called anoxia. Sometimes the


term hypoxia, meaning less oxygen, is used to indicate an oxygen debt. While


anoxia literally means “no oxygen” it is often used interchangeably with hypoxia.


There are different types of anoxia based on the cause of the oxygen deficiency.


Anoxic anoxia refers to defective oxygenation of the blood in the lungs. This is


the type of oxygen deficiency that is of concern when ascending to greater


altitudes with a subsequent decreased partial pressure of O2. Other types of


oxygen deficiencies include: anemic anoxia (failure of the blood to transport


adequate quantities of oxygen), stagnant anoxia (the slowing of the circulatory


system), and histotoxic anoxia (the failure of respiratory enzymes to adequately


function).


Anoxia can occur temporarily during normal respiratory system regulation


of changing cellular needs. An example of this would be climbing a flight of


stairs. The increased oxygendemand of the cells in providing the mechanical


energy required to climb ultimately produces a local hypoxia in the muscle cell.


The first noticeable response to this external stress is usually an increase in


breathing rate. This is called increased alveolar ventilation. The rate of our


breathing is determined by the need for O2 in the cells and is the first


response to hypoxic conditions.


BODY RESPONSE TO ANOXIA


If increases in the rate of alveolar respiration are insufficient to


supply the oxygen needs of the cells the respiratory system responds by general


vasodilation. This allows a greater flow of blood in the circulatory system. The


sympathetic nervous system also acts to stimulate vasodilation within the


skeletal muscle. At the level of the capillaries the normally closed


precapillary sphincters open allowing a large flow of blood through the muscles.


In turn the cardiac output increases both in terms of heart rate and stroke


volume. The stroke volume, however, does not substantially increase in the non-


athlete (Langley, et.al., 1980). This demonstrates an obvious benefit of regular


exercise and physical conditioning particularly for an individual who will be


exposed to high altitudes. The heart rate is increased by the action of the


adrenal medulla which releases catecholamines. These catecholamines work


directly on the myocardium to strengthen contraction. Another compensation


mechanism is the release of renin by the kidneys. Renin leads to the production


of angiotensin which serves to increase blood pressure (Langley, Telford, and


Christensen, 1980). This helps to force more blood into capillaries. All of


these changes are a regular and normal response of the body to external


stressors. The question involved with altitude changes becomes what happens when


the normal responses can no longer meet the oxygen demand from the cells?


ACUTE MOUNTAIN SICKNESS


One possibility is that Acute Mountain Sickness (AMS) may occur. AMS is


common at high altitudes. At elevations over 10,000 feet, 75% of people will


have mild symptoms (Princeton, 1995). The occurrence of AMS is dependent upon


the elevation, the rate of ascent to that elevation, and individual


susceptibility.


Acute Mountain Sickness is labeled as mild, moderate, or severe


dependent on the presenting symptoms. Many people will experience mild AMS


during the process of acclimatization to a higher altitude. In this case


symptoms of AMS would usually start 12-24 hours after arrival at a higher


altitude and begin to decrease in severity about the third day. The symptoms of


mild AMS are headache, dizziness, fatigue, shortness of breath, loss of appetite,


nausea, disturbed sleep, and a general feeling of malaise (Princeton, 1995).


These symptoms tend to increase at night when respiration is slowed during sleep.


Mild AMS does not interfere with normal activity and symptoms genera

lly subside


spontaneously as the body acclimatizes to the higher elevation.


Moderate AMS includes a severe headache that is not relieved by


medication, nausea and vomiting, increasing weakness and fatigue, shortness of


breath, and decreased coordination called ataxia (Princeton, 1995). Normal


activity becomes difficult at this stage of AMS, although the person may still


be able to walk on their own. A test for moderate AMS is to have the individual


attempt to walk a straight line heel to toe. The person with ataxia will be


unable to walk a straight line. If ataxia is indicated it is a clear sign that


immediate descent is required. In the case of hiking or climbing it is important


to get the affected individual to descend before the ataxia reaches the point


where they can no longer walk on their own.


Severe AMS presents all of the symptoms of mild and moderate AMS at an


increased level of severity. In addition there is a marked shortness of breath


at rest, the inability to walk, a decreasing mental clarity, and a potentially


dangerous fluid buildup in the lungs.


ACCLIMATIZATION


There is really no cure for Acute Mountain Sickness other than


acclimatization or descent to a lower altitude. Acclimatization is the process,


over time, where the body adapts to the decrease in partial pressure of oxygen


molecules at a higher altitude. The major cause of altitude illnesses is a rapid


increase in elevation without an appropriate acclimatization period. The process


of acclimatization generally takes 1-3 days at the new altitude. Acclimatization


involves several changes in the structure and function of the body. Some of


these changes happen immediately in response to reduced levels of oxygen while


others are a slower adaptation. Some of the most significant changes are:


Chemoreceptor mechanism increases the depth of alveolar ventilation.


This allows for an increase in ventilation of about 60% (Guyton, 1969). This is


an immediate response to oxygen debt. Over a period of several weeks the


capacity to increase alveolar ventilation may increase 600-700%.


Pressure in pulmonary arteries is increased, forcing blood into portions


of the lung which are normally not used during sea level breathing.


The body produces more red blood cells in the bone marrow to carry


oxygen. This process may take several weeks. Persons who live at high altitude


often have red blood cell counts 50% greater than normal.


The body produces more of the enzyme 2,3-biphosphoglycerate that


facilitates the release of oxygen from hemoglobin to the body tissues (Tortora,


1993).


The acclimatization process is slowed by dehydration, over-exertion, alcohol and


other depressant drug consumption. Longer term changes may include an increase


in the size of the alveoli, and decrease in the thickness of the alveoli


membranes. Both of these changes allow for more gas transfer.


TREATMENT FOR AMS


The symptoms of mild AMS can be treated with pain medications for


headache. Some physicians recommend the medication Diamox (Acetazolamide). Both


Diamox and headache medication appear to reduce the severity of symptoms, but do


not cure the underlying problem of oxygen debt. Diamox, however, may allow the


individual to metabolize more oxygen by breathing faster. This is especially


helpful at night when respiratory drive is decreased. Since it takes a while for


Diamox to have an effect, it is advisable to start taking it 24 hours before


going to altitude. The recommendation of the Himalayan Rescue Association


Medical Clinic is 125 mg. twice a day. The standard dose has been 250 mg., but


their research shows no difference with the lower dose (Princeton, 1995).


Possible side effects include tingling of the lips and finger tips, blurring of


vision, and alteration of taste. These side effects may be reduced with the 125


mg. dose. Side effects subside when the drug is stopped. Diamox is a sulfonamide


drug, so people who are allergic to sulfa drugs such as penicillin should not


take Diamox. Diamox has also been known to cause severe allergic reactions to


people with no previous history of Diamox or suffer allergies. A trial course of


the drug is usually conducted before going to a remote location where a severe


allergic reaction could prove difficult to treat. Some recent data suggests that


the medication Dexamethasone may have some effect in reducing the risk of


mountain sickness when used in combination with Diamox (University of Iowa,


1995).


Moderate AMS requires advanced medications or immediate descent to


reverse the problem. Descending even a few hundred feet may help and definite


improvement will be seen in descents of 1,000-2,000 feet. Twenty-four hours at


the lower altitude will result in significant improvements. The person should


remain at lower altitude until symptoms have subsided (up to 3 days). At this


point, the person has become acclimatized to that altitude and can begin


ascending again. Severe AMS requires immediate descent to lower altitudes (2,000


- 4,000 feet). Supplemental oxygen may be helpful in reducing the effects of


altitude sicknesses but does not overcome all the difficulties that may result


from the lowered barometric pressure.


GAMOW BAG


This invention has revolutionized field treatment of high altitude


illnesses. The Gamow bag is basically a portable sealed chamber with a pump. The


principle of operation is identical to the hyperbaric chambers used in deep sea


diving. The person is placed inside the bag and it is inflated. Pumping the bag


full of air effectively increases the concentration of oxygen molecules and


therefore simulates a descent to lower altitude. In as little as 10 minutes the


bag creates an atmosphere that corresponds to that at 3,000 – 5,000 feet lower.


After 1-2 hours in the bag, the person’s body chemistry will have reset to the


lower altitude. This lasts for up to 12 hours outside of the bag which should be


enough time to travel to a lower altitude and allow for further acclimatization.


The bag and pump weigh about 14 pounds and are now carried on most major high


altitude expeditions. The gamow bag is particularly important where the


possibility of immediate descent is not feasible.


OTHER ALTITUDE-INDUCED ILLNESS


There are two other severe forms of altitude illness. Both of these


happen less frequently, especially to those who are properly acclimatized. When


they do occur, it is usually the result of an increase in elevation that is too


rapid for the body to adjust properly. For reasons not entirely understood, the


lack of oxygen and reduced pressure often results in leakage of fluid through


the capillary walls into either the lungs or the brain. Continuing to higher


altitudes without proper acclimatization can lead to potentially serious, even


life-threatening illnesses.


HIGH ALTITUDE PULMONARY EDEMA (HAPE)


High altitude pulmonary edema results from fluid buildup in the lungs.


The fluid in the lungs interferes with effective oxygen exchange. As the


condition becomes more severe, the level of oxygen in the bloodstream decreases,


and this can lead to cyanosis, impaired cerebral function, and death. Symptoms


include shortness of breath even at rest, tightness in the chest, marked fatigue,


a feeling of impending suffocation at night, weakness, and a persistent


productive cough bringing up white, watery, or frothy fluid (University of Iowa,


1995.). Confusion, and irrational behavior are signs that insufficient oxygen is


reaching the brain. One of the methods for testing for HAPE is to check recovery


time after exertion. Recovery time refers to the time after exertion that it


takes for heart rate and respiration to return to near normal. An increase in


this time may mean fluid is building up in the lungs. If a case of HAPE is


suspected an immediate descent is a necessary life-saving measure (2,000 – 4,000


feet). Anyone suffering from HAPE must be evacuated to a medical facility for


proper follow-up treatment. Early data suggests that nifedipine may have a


protective effect against high altitude pulmonary edema (University of Iowa,


1995).


HIGH ALTITUDE CEREBRAL EDEMA (HACE)


High altitude cerebral edema results from the swelling of brain tissue


from fluid leakage. Symptoms can include headache, loss of coordination (ataxia),


weakness, and decreasing levels of consciousness including, disorientation, loss


of memory, hallucinations, psychotic behavior, and coma. It generally occurs


after a week or more at high altitude. Severe instances can lead to death if not


treated quickly. Immediate descent is a necessary life-saving measure (2,000 -


4,000 feet). Anyone suffering from HACE must be evacuated to a medical facility


for proper follow-up treatment.


CONCLUSION


The importance of oxygen to the functioning of the human body is


critical. Thus the effect of decreased partial pressure of oxygen at higher


altitudes can be pronounced. Each individual adapts at a different speed to


exposure to altitude and it is hard to know who may be affected by altitude


sickness. There are no specific factors such as age, sex, or physical condition


that correlate with susceptibility to altitude sickness. Most people can go up


to 8,000 feet with minimal effect. Acclimatization is often accompanied by fluid


loss, so the ingestion of large amounts of fluid to remain properly hydrated is


important (at least 3-4 quarts per day). Urine output should be copious and


clear.


From the available studies on the effect of altitude on the human body


it would appear apparent that it is important to recognize symptoms early and


take corrective measures. Light activity during the day is better than sleeping


because respiration decreases during sleep, exacerbating the symptoms. The


avoidance of tobacco, alcohol, and other depressant drugs including,


barbiturates, tranquilizers, and sleeping pills is important. These depressants


further decrease the respiratory drive during sleep resulting in a worsening of


the symptoms. A high carbohydrate diet (more than 70% of your calories from


carbohydrates) while at altitude also appears to facilitate recovery.


A little planning and awareness can greatly decrease the chances of


altitude sickness. Recognizing early symptoms can result in the avoidance of


more serious consequences of altitude sickness. The human body is a complex


biochemical organism that requires an adequate supply of oxygen to function. The


ability of this organism to adjust to a wide range of conditions is a testament


to its survivability. The decreased partial pressure of oxygen with increasing


altitude is one of these adaptations.


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of Iowa Medical College, 1995.


Gerking, Shelby D., Biological Systems, W.B. Saunders Company, 1969.


Grolier Electronic Publishing, The New Grolier Multimedia Encyclopedia, 1993.


Grollman, Sigmund, The Human Body: Its Structure and Physiology, Macmillian


Publishing Company, 1978.


Guyton, Arthur C., Physiology of the Human Body, 5th Edition, Saunders College


Publishing, 1979.


Hackett, P., Mountain Sickness, The Mountaineers, Seattle, 1980.


Hubble, Frank, High Altitude Illness, Wilderness Medicine Newsletter,


March/April 1995.


Hubble, Frank, The Use of Diamox in the Prevention of Acute Mountain Sickness,


Wilderness Medicine Newsletter, March/April 1995.


Isaac, J. and Goth, P., The Outward Bound Wilderness First Aid Handbook, Lyons &


Burford, New 1991.


Johnson, T., and Rock, P., Acute Mountain Sickness, New England Journal of


Medicine, 1988:319:841-5


Langley, Telford, and Christensen, Dynamic Anatomy and Physiology, McGraw-Hill,


1980.


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Starr, Cecie, and Taggart, Ralph, Biology: The Unity and Diversity of Life,


Wadsworth Publishing Company, 1992.


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