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Arquivos Brasileiros de Cardiologia

Print version ISSN 0066-782XOn-line version ISSN 1678-4170

Arq. Bras. Cardiol. vol.73 n.1 São Paulo July 1999

https://doi.org/10.1590/S0066-782X1999000700011 

Update


 

Physical Activity at Moderate and High Altitudes. Cardiovascular and Respiratory Morbidit

 

Augusta L. Campos, Ricardo Vivacqua C. Costa

Rio de Janeiro, RJ - Brazil

 

 

In recent decades, sports activities related to nature have become increasingly popular. As more and more people look for ski resorts in mountainous regions or become involved with activities such as walking and/or mountain climbing at moderate and high altitudes, diseases related to this environmental stress become problems that doctors have to face with an increasing frequency; they need, therefore, to know these entities better. In addition, many athletic competitions are performed at altitudes above 2,000 m, such as the Olympic Games of 1968 and the World Cup Soccer Games of 1970, which took place in Mexico City, Mexico, at 2,240 m. Experts have been investigating how to improve athletic performance in such situations.

"Diseases of altitude" are primarily caused by hypoxia and are influenced by the cold weather and the time of exposure. The main syndromes are acute mountain sickness (AMS), high-altitude pulmonary edema (HAPE), and high-altitude cerebral edema (HACE). Potential noxious effects of the hypobaric hypoxia include conditions such as coronary heart disease, pulmonary diseases, hemoglobinopathies and pregnancy.

 

Acute responses to hypobaric hypoxia

Cardiopulmonary effects – systemic blood pressure: In normotensive individuals, the results of the studies regarding the response of blood pressure (BP) to initial exposure to hypobaric hypoxia have been distinct. Some investigators have found an increase in BP 1-5, others a slight reduction 6-7, and others no change at all 8,9. The tendency observed in most of the studies, however, is an increase in blood pressure levels on the first day of exposure to a significant altitude and, later, a decline of the values to those found at sea level, mainly in regard to the systolic blood pressure (SBP) 3,5.

Studies evaluating the behavior of pressure in normotensive individuals during exercise, after acute exposure to hypobaric hypoxia, have also shown discrepancies. Balke 10 observed an increase of 5 to 10mmHg in the SBP and a reduction of 5mmHg in diastolic BP in 6 individuals during exercise on a bicycle at a simulated altitude of 4,200m, when compared with that found at sea level. Malconian et al 11 found a 10% reduction in the mean BP at maximal effort, in a simulated altitude of 8,848m, corresponding to the summit of Mount Everest, compared with the values found at sea level. D'Este et al 12 performed a submaximal test on 10 normotensive individuals after acute exposure to 2,500m and did not find significant differences in the pressure response compared with the results of the test at sea level. Palatini et al 13 found a significant increase in the SBP at rest but not at the maximal effort, in 5 endurance athletes, who underwent a prolonged submaximal test on bicycles, 12 hours after exposure to 3,322m.

In regard to investigations in hypertensive patients, D'Este et al 12 did not observe any change in BP at rest, but SBP significantly increased to the submaximal level during exercise, but not at the maximal effort. Savonitto et al 14 studied the effects of acute exposure at 3,460m on the response of BP to dynamic and isometric exercises in 11 men with light to moderate systemic hypertension. The results observed were light increases in the SBP at rest but no significant changes occurred during the exercise. In the handgrip test, BP and heart rate (HR) were not influenced by the acute exposure to the hypobaric hypoxia.

We understand that the diversity of the methodologies of the different experiments has rendered the comparison of the results difficult.

The small number of hypertensive individuals studied under these conditions and the wide variety of responses among them do not allow us to exclude the possibility that nontreated hypertensive individuals, when exercising at moderate and elevated altitudes, may have pressure levels hazardously elevated.

Cardiovascular autonomic modulation – Sympathetic nervous activity increases with the increase in altitude, but it relates better to the ventilatory response to chronic hypobaric hypoxia than to the severity of the hypoxia itself 15.

Acute exposure to hypobaric hypoxia increases HR at rest 2-5,11. It also increases the component of low frequency and reduces that of high frequency in the spectral analysis 3,8. The maximal HR of the exercise, however, may be maintained or undergo reduction 11,14,16. The last behavior is more prevalent at high altitudes 11, maybe because of the longer time of exposure to hypoxia inherent in those conditions. Malconian et al 11 found a 25% reduction in the maximal HR at a simulated altitude of 8,848m, in relation to that at sea level. Savard et al 16 observed a partial restoration of the previous levels in individuals who had been at altitudes between 5,250 and 8,700m, after inhalation of 60% O2.

Sagawa et al 17 examined the baroreflex response of 7 nonacclimatized men at sea level and at the first hour of exposure to altitudes between 3,800 and 4,300m, in a hypobaric chamber. The results were in accordance with a significant reduction (p<0.05) in the sensitivity of the carotid baroreflex cardiac response.

These results suggest that the acute response to the hypobaric hypoxia relate more to an increase in the sympathetic activity. A longer exposure to this environmental condition causes a reduction in the adrenergic activity 16. Chronic hypobaric hypoxia may reduce the maximal HR by reducing the density and affinity of the beta-adrenergic receptors, as already demonstrated for the alpha-2 receptors 18.

Pulmonary ventilation and saturation of oxygen – Barometric pressure decreases as altitude increases. While the percentage of oxygen in the air remains constant (20.93%), the partial pressure of oxygen decreases 19. The lower density of the air at high altitudes reduces the resistance of the airways, and the maximal inspiratory and expiratory flows are higher than at sea level 20. In spite of this, however, the efficacy of the ventilatory muscles may be reduced due to hypoxia, and therefore, be a limiting factor to exercise 20.

Pulmonary ventilation increases and, inversely, saturation of oxygen (SaO2) drops with an increase in altitude 2,5,20.

Malconian et al 21 studied 8 healthy men (age range: 21-31 years) in simulated altitude (hypobaric chamber) during the sleeping period. SaO2 at sea level was 97±1%, at 4,572m it was 79±3%, at 6,100m it was 62±11%, and at 7,620m it was 52±2%. During maximal exercise at 8,848m in a cycloergometer, the mean SaO2 reached 49% with a mean pH of 8 11.

Oxygen uptake (VO2) – Several studies show a reduction in VO2 at rest and/or at certain level of exercise at moderate and high altitudes 5,22,23.

Basu et al 5 studied 16 men (age range: 20-30 years) during the initial days of acclimatization in the Himalayas, at altitudes between 3,100 and 4,200m. The values of VO2 at rest and during submaximal exercise with a load of 100 W, at sea level, were, respectively, 3.25 and 20.31mL/kg/min. At the altitude of 3,110 m, the values of VO2 at rest and during the submaximal effort with 100 W dropped significantly (p<0.001) and continued to drop (p<0.01) at 4,177m.

At lower altitudes, 2,500m, Levine et al 23 observed a 12% reduction of the peak VO2 in a population of 20 old people, during the acute exposure; VO2 reached normal values after acclimatization. In another extremity, at the simulated altitude of Mount Everest, an 80% drop in the maximal VO2 in relation to sea level was found 24.

Pressure of the pulmonary artery and ventricular function – Davila-Roman et al 25 studied the ventricular function in 14 runners who had completed an ultramarathon at high altitude (2,350 to 4,300m's), to evaluate if prolonged exercise, such as in this type of race, would damage the left ventricle (LV). Until then, there were reports of damage to the LV after strenuous exercise. Before the race, the echocardiograms were normal; SBP of the pulmonary artery had a mean value of 28mmHg and the dosages of troponin I was undetectable. Immediately after the marathon, the echocardiograms showed, as expected, global and segmental increase of the left ventricular function in all individuals and, except for one, the values of troponin I were undetectable. However, in 5 of them, marked dilation with hypokinesia of the right ventricle (RV) was observed, as well as paradoxical movement of the interventricular septum, pulmonary hypertension, and bronchospasm. One of these individuals showed a slight elevation of troponin I. At the end of one day; these findings had already normalized. Therefore, in this sample of athletes performing at high altitudes, inversely to the expectation, the ventricular damage occurred in the RV and not in the LV. The incidence and pathogenesis of these findings still need to be determined. We do not think that the RV impairment is exclusively secondary to the ultramarathon.

Malconian et al 11 found electrocardiographic alterations compatible with pulmonary hypertension (increase in the amplitude of the P wave in D2, D3, AVF, right shift of the QRS axis, increase in the ratio S/R in the left precordials and increase in the negativity of the T wave in V1 and V2), from the simulated altitude of 6,100 m on. Most of the changes reversed to normal 12 hours after the return to sea level.

Respiratory changes and arrhythmias during sleep – At high altitudes and during sleep, some healthy individuals have a periodical respiratory pattern, also called Cheyne-Stokes respiration 17,21,26. Combined with this variation, there are cyclic changes in the cardiac rhythm and HR 19. Cummings and Lysgaard 27 recorded their own cardiac rhythms and observed a pronounced respiratory sinus arrhythmia and bradycardia during sleep at 5,033m.

During the Operation Everest II, simultaneous records of respiration and electrocardiogram were performed in 8 individuals during sleep 21. The evaluations were carried out at sea level and at the following altitudes: 5,490m, 6,100m, and 7,620m. The results found at high altitudes were the following: sinus bradycardia (41±0.5bpm), bradycardia-tachycardia cycles respectively related to the phases of the periodical respiratory cycle of bradypnea/apnea and tachypnea, sinus arrhythmia, junctional escapes, and ventricular and supraventricular extrasystoles. Similar results had already been observed in previous studies 21.

The mechanisms of these alterations of respiration and cardiac rhythm are yet to be determined. Administration of oxygen or carbon dioxide eliminates apnea but not the respiratory periodicity during exposure to hypobaric hypoxia 19. A mechanism of vagal modulation may be involved 21.

Endocrine alterations Roberts et al 28 observed an increase in glucose cellular uptake, at rest and during submaximal exercise, resulting from exposure to hypobaric hypoxia. According to these authors, glucose utilization is higher initially than after acclimatization, and this is intensified by the use of beta-blockers. McClelland et al 29, studying rats, did not find any increase in carbohydrate utilization.

Hypobaric hypoxia increases diuresis. During the Australian Bicentennial Mount Everest Expedition 30, 10 individuals were evaluated in regard to the effects of the exposure to an altitude of 5,400m on the plasmatic concentration of the atrial natriuretic peptide. Results showed reduction in the activity of plasmatic renin and aldosterone, increase in the levels of the atrial natriuretic peptide, and also increase in the diuresis and natriuresis.

Zaccaria et al 31 studied the hormones that regulate sodium in 7 men, one week and 21 days after being at 5,050m, before and after exercise and they compared the results to those obtained at sea level. Plasmatic samples of renin, aldosterone and atrial natriuretic peptide activity were obtained at the orthostatic position and at the end of a maximal exercise. Sodium excretion and the urinary volume in 24 hours were also evaluated, as well as the total body water and hematocrit. They found a constant suppression of the plasmatic renin activity and of the aldosterone levels, the opposite of the findings at sea level, concluding that these hormones were not stimulated by strenuous exercise. They also observed an increase of the atrial natriuretic peptide during acute exposure, but not during chronic exposure.

We consider the above-discussed endocrine alterations not yet well clarified, requiring further studies.

Endothelial and blood alterations – Endothelin 1: Exposure to a continuous increase in altitude progressively increases plasmatic endothelin 1 (ET-1) 32,33, which is a peptide synthesized by endothelial cells, with potent vasoconstrictive and mitogenic action upon the vascular smooth muscles.

Morganti et al 32 observed changes in the plasmatic dosages of ET-1 (from 1.8±0.1pg/mL, at sea level, to 2.7± 0.2mg/mL, at 4,240m), concomitantly with reductions of the SaO2 (from 98.6±0.2%, at sea level, to 80.8±0.4%, at that altitude). In a study of 6 men climbing the Monte Rosa in the Alps (4,559m), those authors also found increases in the pulmonary SBP (from 19±1 to 26±1.9mmHg), directly related to the increase of plasmatic ET-1.

Increase in the plasmatic ET-1 has been observed in cases of HAPE (high-altitude pulmonary edema), including in the bronchoalveolar lavage, and it is part of one of the hypotheses about the pathogenesis of HAPE 33.

Erythropoietin – A few hours after exposure to hypobaric hypoxia, the secretion of renal erythropoietin increases 34-37. As it stimulates the synthesis of red blood cells, in approximately one week it significantly increases the concentration of hemoglobin and, therefore, the capacity of transporting O2 in the blood 38. Therefore, even though erythropoietin levels increase at the acute phase of exposure to higher altitudes, its effects will be felt during acclimatization

Vascular endothelial growth factor – Asano et at 37 studied 8 swimmers training at 1,886m. After 10 days of training, they observed transient reduction in the levels of the vascular endothelial growth factor (VEGF) in the serum, followed by a significant increase, reaching a peak at the 19th day. The initial values were obtained one month after the return to a low altitude. We do not know, however, if the reduction of VEGF occurred in the first days of exposure to altitude.

 

Acclimatization

Hypobaric hypoxia triggers adaptive physiological mechanisms destined to satisfy the energetic needs of the cells. Acclimatization happens when after days of exposure to a certain altitude, usually a period of 2 to 3 weeks, there is a chronic adaptation to environmental conditions 38,39.

The physiological mechanisms are the following: 1) increase in the pulmonary ventilation 39; 2) reduction in the HR previously increased in the acute response 22,39; 3) decrease in the plasmatic volume 39,40; 4) reduction of the accumulation of lactate in the blood during submaximal exercise in relation to the more elevated levels of acute response 39; 5) improvement of the cardiorespiratory capacity for exercise, also related to the initial exposure to the hypobaric hypoxia 23,41; 6) increase in the secretion of renal erythropoietin, in the hemoglobin mass and in the hematocrit 34,36,37,42.

The time necessary for each of these responses varies. Some of them are fully manifested within days of arrival at a certain altitude, while others may require 2 to 3 weeks 39. In regard to extreme altitudes, such as those above 8,000m, however, a period of 77 days seems to be more adequate 43.

Unlike the acclimatization period, the return to the biological conditions at sea level is much less known. Beidleman et al 39 studied the effects of acclimatization on 6 men who, after 16 days at 4,300m, stayed for 8 days at sea level, returning then to the previous altitude, but at this time in a hypobaric chamber. Even though the performance of the submaximal exercise was not maintained after the return to the altitude, several responses of acclimatization were retained. These responses lasted longer than necessary for acclimatization, except for the HR; this fact may be explained by the rapid changes of the autonomous nervous system. Some individuals, whose work is athletic competition or recreational activities involving intermittent journeys into high altitudes, may benefit from the responses to previous acclimatization.

 

Diseases of altitude

Even though acute mountain sickness (AMS), high-altitude pulmonary edema (HAPE) and high-altitude cerebral edema (HACE) are distinct disorders, they relate to each other. They usually occur in young and healthy people as a result of poor acclimatization. The more severe forms of HAPE and HACE are not necessarily preceded by MAS 26.

Acute mountain sickness (AMS) – AMS is the most common of all. It is usually self-limited and rarely leads to death. Symptoms appear between 4 and 8 hours after arrival at the altitude 35, and the most characteristic ones are the following: headache, nausea, insomnia, anorexia, and dyspnea 17,26,38. Despite the individual tolerance to hypobaric hypoxia, the best way to prevent AMS is to ascend slowly 19,26,38,44. One should also avoid strenuous efforts at the initial phase of acclimatization, provide a good hydration ingesting at least 3 liters of water per day, and eat light meals in which carbohydrates predominate 19,26. In all 3 situations, the best treatment is the descent 19,26,44,45.

Controlled studies have shown that acetazolamide reduces the incidence and severity of MAS 17,46,47. Being an inhibitor of carbonic anhydrase, it facilitates the excretion of urinary bicarbonate, promoting reduction of the respiratory alkalosis and, therefore, increasing the respiratory drive with reduction of the nocturnal hypoxemia 19,26,38,47. Doses used vary from 125 to 250mg every 12 hours or 500mg in tablets with prolonged release every 24 hours. Drug intake should start one day before ascent and continue until 2 days after reaching the maximal height or can be maintained for longer periods, if the risk of AMS is high 19,26,38,47. The side effects can include increase in diuresis, epigastralgia, and paresthesia 19,26,46,47.

High-altitude pulmonary edema (HAPE) – HAPE is a noncardiogenic pulmonary edema. It is accompanied by pulmonary hypertension, an increase in the pulmonary capillary permeability and hypoxemia 48. HAPE typically occurs in young and healthy mountaineers and is precipitated by rapid ascents at altitudes above 2,500-3,000m 45,48-50. There is an individual susceptibility and it tends to recur 45,48,49,51. HAPE clinically manifests 2 to 5 days after acute exposure to hypobaric hypoxia, 78% of the cases appear until the 10th day 38,45, with the following symptoms: abnormal dyspnea on effort and, later, even at rest, cyanosis, dry cough that evolves to a mucous-sanguinolent cough, and tachycardia 19,38. Teleradiography shows diffuse alveolar images unevenly distributed 19,38,45. The alveolar fluid is rich in proteins and inflammatory mediators 33,45,52,53.

HAPE is a severe and potentially fatal condition and immediate descent is mandatory 19,26. If this is impossible or concomitantly with the descent, the therapeutical scheme recommended is to inhale oxygen and use 10-20mg of nifedipine by sublingual via plus 20mg of slow-release nifedipine, which should be repeated every 6 hours 26,38,53,54.

In a double-blind study, the prophylactic use of nifedipine reduced the incidence of recurrent pulmonary edema in mountaineers during ascent at 4,559m 55. This calcium channel antagonist decreases the pulmonary artery pressure and increases SaO2. A blocking action of the inflammatory response to hypoxia was also described 54.

Inhalation of nitric oxide has been recently tried in the treatment of HAPE, because of its selective vasodilating action upon the pulmonary vascular network 56. Anand et al 56 treated random patients with moderate to high intensity HAPE with 50% O2, nitric oxide at 15 ppm, a mixture of O2 and nitric oxide, and environmental air. They discovered that both O2 and nitric oxide reduce the pressure in the pulmonary artery and also the pulmonary perfusion-ventilation disorder, and improve oxygenation. The results showed an additive effect with a more significant improvement of the pulmonary hemodynamics and of the gas exchanges, when O2 and nitric oxide are simultaneously used.

Pathophysiology of HAPE remains partially unknown. Accumulation of fluid with a high content of protein in the alveolar space results from an increase in the permeability of the pulmonary vascular endothelium, exceeding the capacity of reabsorption 53. There are several hypotheses to explain this increase in permeability and some of them are listed below: 1) pulmonary arterial hypertension 57-59; 2) hypoxia inducing the release of inflammatory mediators, such as cytokines, ET-1, and intercellular adhesion molecule (ICAM-1) 33,52; 3) hyperperfusion of the pulmonary vessels not undergoing vasoconstriction (hypoxic pulmonary vasoconstriction is extensive but not uniform) leading to dilation and high flow in the capillaries and consequent capillary lesion 60. On the other hand, the rapid normalization that occurs with oxygen therapy and descent indicates a preserved pulmonary "architecture" 53. Perhaps the interaction of these and other hypotheses may explain the mechanisms responsible for HAPE.

A study trying to elucidate the reason for a constitutional predisposition to recurrent HAPE was recently published. Hanaoka et al 49 showed that some human lymphocyte antigens (HLA) are increased in Japanese patients with HAPE, especially those with the recurrent disease. HLA-DR6 and/or HLA-DR4 were most frequently found in Japanese individuals with HAPE than in a control group. The HLA-DR6-positive individuals with HAPE had significantly higher pulmonary arterial pressures than other HLA-DR6-negative patients with HAPE. The authors say that at least some cases of HAPE are immunologically mediated, perhaps through a greater susceptibility to pulmonary hypertension. This study supports the observations of Steinacker et al 61, who found a smaller pulmonary vasoconstriction, a greater vascular capacitance and a greater ventilatory response during exercise in individuals resistant to HAPE compared with those who had HAPE.

High-altitude cerebral edema (HACE) – It usually happens at altitudes higher than 4,500m 38. Intense headache, mental confusion, hallucinations, and ataxia 19,38 characterize HACE. The victim is usually tired, with no conditions to objectively evaluate his/her own status, may have hallucinations and walk like a drunken person 19. The fine movements of the hands, fingers and eyes are affected 19. Edema and petechial hemorrhages are typically found in the brain at autopsy 19. Prevention can be done through a slow ascent, good hydration and avoidance of strenuous exercises 19,26. Descent is the treatment and it should be started immediately because evolution to death can be rapid 19,26,38. Oxygen improves the symptoms, but when interrupted, the situation aggravates even more 19. Dexamethasone does not affect cerebral edema, but reduces the symptoms and, therefore, makes the descent easier 26.

 

Sports activities at moderate and high altitudes

There are 3 groups of individuals classified according to their way of responding to hypobaric hypoxia. The groups are the following: 1) healthy people living at sea level or at low altitudes; 2) those who were born and live at moderate and high altitudes; 3) those with heart diseases, pulmonary diseases and hemoglobinopathies.

The first group can be subdivided into sedentary, active and athletic individuals. The acclimatization process has no direct correlation with the previous level of physical conditioning. An athlete with high aerobic conditioning is equally exposed to the diseases of altitude as a sedentary individual. In absolute values, however, especially after the acclimatization period, the differences in the cardiopulmonary capacities are kept as at sea level. Physical training and the intensity of the exercises should be differentiated and adequate to each subgroup.

The second group is well represented by the Sherpas, a small ethnic group living in the Himalayas at altitudes ranging from 3,000 to 4,900m 62. The maximum altitude a man can permanently live at is 5,300m 63. A large number of those people provide support to climbers of the highest mountains in the world, as carriers and mountain guides, and they usually do this without an extra oxygen supply.

Garrido et al 62 assessed the cardiorespiratory capacity of 6 Sherpa climbers at sea level. They found a VO2max of 66.7±3.7mL/min-1.kg-1 and a ventilatory anaerobic threshold of 62(±4)% of the VO2max. This high functional reserve can be associated with a process of natural selection and also with physiological adaptations induced by long training in a hostile environment 62. Supporting the first hypothesis, a study showed that in Lhasa, Tibet (3,658m), the newborns descending from the Tibetans had a higher arterial SaO2 at birth and during the first months of life than the descendents of the Chinese 64. In regard to the second hypothesis, Curran et al 22 compared within the same ethnic group Tibetans living at 4,400m and at 3,658m, through a cycloergometric test with direct oxygen consumption at 3,658m. The authors observed that the first group reached a higher load of exercise (211+/-6 versus 177+/-7 watts, p<0.01) with a lower pulmonary ventilation (127+/-5 versus 149+/-5 L/minBTPS, p<0.01).

The third group has been studied at moderate altitudes, 2,000 to 4,000m. Most of the people with heart disease can safely reach these altitudes, even though hypobaric hypoxia stimulates the autonomic nervous system and this response can be exacerbated by physical activity, therefore increasing the myocardial VO2 23,65-67. During the first four days of exposure to high altitudes, the risks are higher 21,63. A gradual ascent with limitation of the physical activity to a level lower than that performed at sea level, the improvement of physical conditioning before ascent and a strict control of pressure levels, in addition to a therapeutical scheme, minimize possible complications 65,66. However, subgroups of patients with pulmonary hypertension, decompensated heart failure, unstable angina, recent acute myocardial infarction, noncontrolled severe atrial hypertension, severe pulmonary disease, homozygote sickle cell anemia, recurrent thromboembolic episodes, and patients with a severe anemia or reduction in SaO2 can be at high risk 65,66. On the other hand, some individuals with the sickle cell trait have their first crisis of vascular occlusion during exercise at these altitudes. In competitions, they have the tolerance to exercise reduced, which until then had not been observed at sea level 68.

Several sports activities are particularly dependent on high altitudes and have their peculiarities. A typical example is mountaineering.

Mountaineering – As a general rule, in long ascents at altitudes higher than 3,000m, the positive difference of the altitudes between two consecutive nights should not exceed 300m, and there should be two nights at the same altitude at every 3 days 26.

Controlled studies have shown that the use of acetazolamide enhances the velocity of ascent by reducing the symptoms of AMS and improving physical performance 46,47. Compared with individuals taking placebo, those using acetazolamide had a smaller weight loss, a smaller muscle mass loss and a greater tolerance for effort 46.

To reduce the risks of dehydration caused by inspiration in a cold and dry environment, an abundant hydration with 3 to 5 liters of liquids per day is fundamental, as well as a diet rich in carbohydrates, which release more energy (5.0 kcal/L O2) than lipids (4.7 kcal/L O2) 69.

In regard to coca chewing, a common habit in the Andean countries, a study carried out at the Instituto Boliviano de Pesquisa by Spielvogel et al 70 concluded that the beneficial effects of the herb were caused neither by an increase in the maximum capacity to exercise nor by its greater efficiency. Coca chewing increases the plasmatic concentration of free fatty acids and, therefore, can benefit prolonged submaximal exercisers.

Based on studies carried out in expeditions at high altitudes, above 7,500m, it has been observed that despite the extreme hypoxemia, the cardiac function is preserved with no electrocardiographic evidence of myocardial hypoxia 11,71. Disorders of the central nervous system, however, are frequent and alterations in the motor coordination have been described persisting for more than 12 months 71.

A relevant point is training athletes who are going to compete at moderate altitudes, when they come from regions close to the sea level.

Athletic training – Limitations of performance in competitions at moderate altitudes were more carefully observed during the Olympic Games of 1968 in Mexican City, at 2,240 m. Then, the athletes performing predominantly aerobic activities did not break records in activities such as long races. Good performance was observed only in activities of short duration, such as the 100-m races, in which the mobilization of sources of oxidative energy is small.

Acclimatization usually takes two weeks at moderate altitudes up to 2,300m. Beyond this altitude, to each additional ascent of 610m, one week should be added, up to the altitude of 4,572m 69, characterizing a gradual acclimatization considered more physiological and safer.

Our experience with soccer players, who acclimatized to compete at 3,600m, showed that the major complications resulting from the altitude such as headache, nausea, vomiting and reduction in performance were observed more often at the 3rd and 7th days of stay. These complications reappeared when the athletes moved to higher places, in a program of gradual acclimatization 72.

One characteristic of the low threshold of sensitivity to hypobaric hypoxia that we observed was the elevation of the HR at rest, when waking up, 24 hours after the arrival at the altitude, in relation to the HR obtained at the wake up time at sea level. An 80% increase would indicate clinical complications at that altitude, requiring an individualized training 73.

Training at altitude cannot be performed with the same intensity as that at sea level. Studies of university students revealed that the intensity of the training at 2,300m would be 60% of the VO2 max reached at sea level, at 3,100m it would be 56%, and at 4,000m 39% of the VO2 max74. In practical terms, we believe there is certain difficulty in maintaining these levels of intensity, which certainly reach more elevated levels. Any symptom or clinical sign, however, can limit the athlete's physical activity.

It is believed that in prolonged sports competitions involving races and successive stops, such as soccer and basketball, the players may suffer little influence of the hypobaric hypoxia as a result of a reduced intensity training 75. This reduction in the intensity of the physical training does not imply reduction in the tactical training, which should be maintained. This is especially important so that the players can get used to a change in the dynamics of the displacement of the ball consequent to the smaller atmospheric pressure.

We consider the training at progressively higher altitudes the best way to prepare a group of athletes to compete at altitudes higher than 2,600m. Our greatest experience was with the preparation of soccer players for competitions at 3,600m in the city of La Paz, Bolivia 73.

The training started at low altitude and lasted 15 days. The workload was assessed considering the cardiorespiratory capacity obtained through ergospirometric tests in treadmill, with direct evaluation of the expired gases. The workload reached at the anaerobic threshold of the athlete was applied as base of training, because we considered it the most practical manner to prepare for the physical restrictions observed in hypobaric hypoxia. To exemplify, we briefly show the results of the ergospirometric evaluation of 15 soccer players for a competition at 3,600m: age range: 26±2 years; VO2 max: 61±3.7mL/kg/min; anaerobic threshold: 78±4.6% of the VO2 max; training intensity: 200±10m/min; training HR: 143±12bpm73.

The effect of training was controlled during physical conditioning, applying the field tests (Guidelines ACSM) 76. The best results were obtained with an initial training at 2,600m during one week; at 2,900m another week; and at 3,600 m during the week preceding the competition 73.

We observed that after the period of acclimatization, the return to sea level is characterized by an improvement of the performance, consequent to training and, possibly, to the increase in the capacity of oxygen transportation. In the assessment of a group of 15 athletes, 16 days after a period of 2 weeks at 2,900 m (Quito, Ecuador) and a reassessment at 700m (Poços de Caldas, Minas Gerais state, Brazil), which is a nonsignificant altitude, we obtained the following results of VO2 max in field tests 76: at 2,900m, 50±2.8mL/kg/min, at 700m, 57.42±3.6mL/kg/min, with significant differences 72. Authors studying runners who underwent acclimatization at 2,300 and 4,000m, however, observed no significant improvement in the physical capacity after return from the altitude 77.

Finally, we can conclude that competitions at moderate and high altitudes depend on adequate evaluation of the athlete, individual training regarding parameters obtained at sea level and at certain altitude, control of the body weight to establish a balance between caloric intake and physical activity, good hydration, gradual acclimatization, and perfect understanding between the technical team and athletes.

 

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