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Altitude training

November 20, 2023

Altitude training is the practice by some endurance athletes of training for several weeks at high altitude, preferably over 2,400 metres (8,000 ft) above sea level, though more commonly at intermediate altitudes due to the shortage of suitable high-altitude locations. At intermediate altitudes, the air still contains approximately 20.9% oxygen, but the barometric pressure and thus the partial pressure of oxygen is reduced.[1][2]

Altitude training in the Swiss Olympic Training Base in the Alps (elevation 1,856 m or 6,089 ft) in St. Moritz.

Depending on the protocols used, the body may acclimate to the relative lack of oxygen in one or more ways such as increasing the mass of red blood cells and hemoglobin, or altering muscle metabolism.[3][4][5][6] Proponents claim that when such athletes travel to competitions at lower altitudes they will still have a higher concentration of red blood cells for 10–14 days, and this gives them a competitive advantage. Some athletes live permanently at high altitude, only returning to sea level to compete, but their training may suffer due to less available oxygen for workouts.

Altitude training can be simulated through use of an altitude simulation tent, altitude simulation room, or mask-based hypoxicator system where the barometric pressure is kept the same, but the oxygen content is reduced which also reduces the partial pressure of oxygen. Hypoventilation training, which consists of reducing the breathing frequency while exercising, can also mimic altitude training by significantly decreasing blood and muscle oxygenation.[7]

Background history edit

 
Altitude training in a low-pressure room in East Germany

The study of altitude training was heavily delved into during and after the 1968 Olympics, which took place in Mexico City, Mexico: elevation 2,240 metres (7,349 ft). It was during these Olympic Games that endurance events saw significant below-record finishes while anaerobic, sprint events broke all types of records.[8] It was speculated prior to these events how the altitude might affect performances of these elite, world-class athletes and most of the conclusions drawn were equivalent to those hypothesized: that endurance events would suffer and that short events would not see significant negative changes. This was attributed not only to less resistance during movement—due to the less dense air[9]—but also to the anaerobic nature of the sprint events. Ultimately, these games inspired investigations into altitude training from which unique training principles were developed with the aim of avoiding underperformance.

Training regimens edit

Athletes or individuals who wish to gain a competitive edge for endurance events can take advantage of exercising at high altitude. High altitude is typically defined as any elevation above 1,500 metres (5,000 ft).

Live-high, train-low edit

One suggestion for optimizing adaptations and maintaining performance is the live-high, train-low principle. This training idea involves living at higher altitudes in order to experience the physiological adaptations that occur, such as increased erythropoietin (EPO) levels, increased red blood cell levels, and higher VO2 max,[10] while maintaining the same exercise intensity during training at sea level. Due to the environmental differences at high altitude, it may be necessary to decrease the intensity of workouts. Studies examining the live-high, train-low theory have produced varied results, which may be dependent on a variety of factors such as individual variability, time spent at high altitude, and the type of training program.[11][12] For example, it has been shown that athletes performing primarily anaerobic activity do not necessarily benefit from altitude training as they do not rely on oxygen to fuel their performances.

A non-training elevation of 2,100–2,500 metres (6,900–8,200 ft) and training at 1,250 metres (4,100 ft) or less has shown to be the optimal approach for altitude training.[13] Good venues for live-high train-low include Mammoth Lakes, California; Flagstaff, Arizona; and the Sierra Nevada, near Granada in Spain.[14]

Altitude training can produce increases in speed, strength, endurance, and recovery by maintaining altitude exposure for a significant period of time. A study using simulated altitude exposure for 18 days, yet training closer to sea-level, showed performance gains were still evident 15 days later.[15]

Opponents of altitude training argue that an athlete's red blood cell concentration returns to normal levels within days of returning to sea level and that it is impossible to train at the same intensity that one could at sea level, reducing the training effect and wasting training time due to altitude sickness. Altitude training can produce slow recovery due to the stress of hypoxia.[16] Exposure to extreme hypoxia at altitudes above 16,000 feet (5,000 m) can lead to considerable deterioration of skeletal muscle tissue. Five weeks at this altitude leads to a loss of muscle volume of the order of 10–15%.[17]

Live-high, train-high edit

In the live-high, train-high regime, an athlete lives and trains at a desired altitude. The stimulus on the body is constant because the athlete is continuously in a hypoxic environment. Initially VO2 max drops considerably: by around 7% for every 1000 m above sea level. Athletes will no longer be able to metabolize as much oxygen as they would at sea level. Any given velocity must be performed at a higher relative intensity at altitude.[16]

Repeated sprints in hypoxia edit

In repeated sprints in hypoxia (RSH), athletes run short sprints under 30 seconds as fast as they can. They experience incomplete recoveries in hypoxic conditions. The exercise to rest time ratio is less than 1:4, which means for every 30 second all out sprint, there is less than 120 seconds of rest.[18]

When comparing RSH and repeated sprints in normoxia (RSN), studies show that RSH improved time to fatigue and power output. RSH and RSN groups were tested before and after a 4-week training period. Both groups initially completed 9–10 all-out sprints before total exhaustion. After the 4 week training period, the RSH group was able to complete 13 all out sprints before exhaustion and the RSN group only completed 9.[18]

Possible physiological advantages from RSH include compensatory vasodilation and regeneration of phosphocreatine (PCr). The body's tissues have the ability to sense hypoxia and induce vasodilation. The higher blood flow helps the skeletal muscles maximize oxygen delivery. A greater level of PCr resynthesis augments the muscles power production during the initial stages of high-intensity exercise.[19]

RSH is still a relatively new training method and is not fully understood.[18]

Artificial altitude edit

Altitude simulation systems have enabled protocols that do not suffer from the tension between better altitude physiology and more intense workouts. Such simulated altitude systems can be utilized closer to competition if necessary.

In Finland, a scientist named Heikki Rusko has designed a "high-altitude house." The air inside the house, which is situated at sea level, is at normal pressure but modified to have a low concentration of oxygen, about 15.3% (below the 20.9% at sea level), which is roughly equivalent to the amount of oxygen available at the high altitudes often used for altitude training due to the reduced partial pressure of oxygen at altitude. Athletes live and sleep inside the house, but perform their training outside (at normal oxygen concentrations at 20.9%). Rusko's results show improvements of EPO and red-cell levels.

Artificial altitude can also be used for hypoxic exercise, where athletes train in an altitude simulator which mimics the conditions a high altitude environment. Athletes are able to perform high intensity training at lower velocities and thus produce less stress on the musculoskeletal system.[16] This is beneficial to an athlete who had a musculoskeletal injury and is unable to apply large amounts of stress during exercise which would normally be needed to generate high intensity cardiovascular training. Hypoxia exposure for the time of exercise alone is not sufficient to induce changes in hematologic parameters. Hematocrit and hemoglobin concentrations remain in general unchanged.[17] There are a number of companies who provide altitude training system, most notably Hypoxico, Inc. who pioneered the artificial altitude training systems in the mid-1990s.

A South African scientist named Neil Stacey has proposed the opposite approach, using oxygen enrichment to provide a training environment with an oxygen partial pressure even higher than at sea level. This method is intended to increase training intensity.[20]

Principles and mechanisms edit

Altitude training works because of the difference in atmospheric pressure between sea level and high altitude. At sea level, air is denser and there are more molecules of gas per litre of air. Regardless of altitude, air is composed of 21% oxygen and 78% nitrogen. As the altitude increases, the pressure exerted by these gases decreases. Therefore, there are fewer molecules per unit volume: this causes a decrease in partial pressures of gases in the body, which elicits a variety of physiological changes in the body that occur at high altitude.[21]

The physiological adaptation that is mainly responsible for the performance gains achieved from altitude training, is a subject of discussion among researchers. Some, including American researchers Ben Levine and Jim Stray-Gundersen, claim it is primarily the increased red blood cell volume.[22]

Others, including Australian researcher Chris Gore, and New Zealand researcher Will Hopkins, dispute this and instead claim the gains are primarily a result of other adaptions such as a switch to a more economic mode of oxygen utilization.[23]

Increased red blood cell volume edit

 
Human red blood cells

At high altitudes, there is a decrease in oxygen hemoglobin saturation. This hypoxic condition causes hypoxia-inducible factor 1 (HIF1) to become stable and stimulates the production of erythropoietin (EPO), a hormone secreted by the kidneys,[24] EPO stimulates red blood cell production from bone marrow in order to increase hemoglobin saturation and oxygen delivery. Some athletes demonstrate a strong red blood cell response to altitude while others see little or no gain in red cell mass with chronic exposure.[25] It is uncertain how long this adaptation takes because various studies have found different conclusions based on the amount of time spent at high altitudes.[26]

While EPO occurs naturally in the body, it is also made synthetically to help treat patients with kidney failure and to treat patients during chemotherapy. Over the past thirty years, EPO has become frequently abused by competitive athletes through blood doping and injections in order to gain advantages in endurance events. Abuse of EPO, however, increases RBC counts beyond normal levels (polycythemia) and increases the viscosity of blood, possibly leading to hypertension and increasing the likelihood of a blood clot, heart attack or stroke. The natural secretion of EPO by the human kidneys can be increased by altitude training, but the body has limits on the amount of natural EPO that it will secrete, thus avoiding the harmful side effects of the illegal doping procedures.

Other mechanisms edit

Other mechanisms have been proposed to explain the utility of altitude training. Not all studies show a statistically significant increase in red blood cells from altitude training. One study explained the success by increasing the intensity of the training (due to increased heart and respiration rate).[15] This improved training resulted in effects that lasted more than 15 days after return to sea level.

Another set of researchers claim that altitude training stimulates a more efficient use of oxygen by the muscles.[23] This efficiency can arise from numerous other responses to altitude training, including angiogenesis, glucose transport, glycolysis, and pH regulation, each of which may partially explain improved endurance performance independent of a greater number of red blood cells.[5] Furthermore, exercising at high altitude has been shown to cause muscular adjustments of selected gene transcripts, and improvement of mitochondrial properties in skeletal muscle.[27][28]

In a study comparing rats active at high altitude versus rats active at sea level, with two sedentary control groups, it was observed that muscle fiber types changed according to homeostatic challenges which led to an increased metabolic efficiency during the beta oxidative cycle and citric acid cycle, showing an increased utilization of ATP for aerobic performance.[29]

Due to the lower atmospheric pressure at high altitudes, the air pressure within the breathing system must be lower than it would be at low altitudes in order for inhalation to occur. Therefore, inhalation at high altitudes typically involves a relatively greater lowering of the thoracic diaphragm than at low altitudes.

See also edit

References edit

  1. ^ West, JB (October 1996). "Prediction of barometric pressures at high altitude with the use of model atmospheres". Journal of Applied Physiology. 81 (4): 1850–4. doi:10.1152/jappl.1996.81.4.1850. PMID 8904608.
  2. ^ . Altitude.org. Archived from the original on 2010-02-01. Retrieved 2010-07-03.
  3. ^ Formenti, F; Constantin-Teodosiu, D; Emmanuel, Y; Cheeseman, J; et al. (June 2010). "Regulation of human metabolism by hypoxia-inducible factor". Proceedings of the National Academy of Sciences of the USA. 107 (28): 12722–12727. Bibcode:2010PNAS..10712722F. doi:10.1073/pnas.1002339107. PMC 2906567. PMID 20616028.
  4. ^ Wehrlin, JP; Zuest, P; Hallén, J; Marti, B (June 2006). "Live high—train low for 24 days increases hemoglobin mass and red cell volume in elite endurance athletes". J. Appl. Physiol. 100 (6): 1938–45. doi:10.1152/japplphysiol.01284.2005. PMID 16497842. S2CID 2536000.
  5. ^ a b Gore, CJ; Clark, SA; Saunders, PU (September 2007). "Nonhematological mechanisms of improved sea-level performance after hypoxic exposure". Med. Sci. Sports Exerc. 39 (9): 1600–9. doi:10.1249/mss.0b013e3180de49d3. PMID 17805094.
  6. ^ Muza, SR; Fulco, CS; Cymerman, A (2004). . US Army Research Inst. Of Environmental Medicine Thermal and Mountain Medicine Division Technical Report (USARIEM–TN–04–05). Archived from the original on 2009-04-23. Retrieved 2009-03-05.{{cite journal}}: CS1 maint: unfit URL (link)
  7. ^ Xavier Woorons, "Hypoventilation training, push your limits!", Arpeh, 2014, 176 p (ISBN 978-2-9546040-1-5)
  8. ^ "Mexico 1968 Summer Olympics". Olympics.org. 2018-12-18.
  9. ^ Ward-Smith, AJ (1983). "The influence of aerodynamic and biomechanical factors on long jump performance". Journal of Biomechanics. 16 (8): 655–658. doi:10.1016/0021-9290(83)90116-1. PMID 6643537.
  10. ^ Gore, CJ; Hahn, AG; Aughey, RJ; Martin, DT; et al. (2001). "Live high:train low increases muscle buffer capacity and submaximal cycling efficiency". Acta Physiol Scand. 173 (3): 275–286. doi:10.1046/j.1365-201X.2001.00906.x. PMID 11736690.
  11. ^ Levine, BD; Stray-Gunderson, J (2001). The effects of altitude training are mediated primarily by acclimatization rather than by hypoxic exercise. Advances in Experimental Medicine and Biology. Vol. 502. pp. 75–88. doi:10.1007/978-1-4757-3401-0_7. ISBN 978-1-4419-3374-4. PMID 11950157.
  12. ^ Stray-Gundersen, J; Chapman, RF; Levine, BD (2001). ""Living high—training low" altitude training improves sea level performance in male and female elite runners". Journal of Applied Physiology. 91 (3): 1113–1120. doi:10.1152/jappl.2001.91.3.1113. PMID 11509506.
  13. ^ Rodríguez, FA; Truijens, MJ; Townsend, NE; Stray-Gundersen, J; et al. (2007). "Performance of runners and swimmers after four weeks of intermittent hypobaric hypoxic exposure plus sea level training". Journal of Applied Physiology. 103 (5): 1523–1535. doi:10.1152/japplphysiol.01320.2006. PMID 17690191. S2CID 25708310.
  14. ^ Egan, E. (2013). Notes from higher grounds: an altitude training guide for endurance athletes. Kukimbia Huru Publishing. ISBN 978-0992755201.
  15. ^ a b Brugniaux, JV; Schmitt, L; Robach, P; Nicolet, G; et al. (January 2006). "Eighteen days of "living high, training low" stimulate erythropoiesis and enhance aerobic performance in elite middle-distance runners". Journal of Applied Physiology. 100 (1): 203–11. doi:10.1152/japplphysiol.00808.2005. PMID 16179396. S2CID 25804302.
  16. ^ a b c Smoliga, J (Summer 2009). "High-altitude training for distance runners". Track Coach. 188.
  17. ^ a b Hoppeler, H; Vogt, M (2001). "Muscle tissue adaptations to hypoxia". Journal of Experimental Biology. 204 (18): 3133–3139. doi:10.1242/jeb.204.18.3133. PMID 11581327.
  18. ^ a b c Faiss, Raphael; Girard, Olivier; Millet, Gregoire P (11 September 2013). "Advancing hypoxic training in team sports: from intermittent hypoxic training to repeated sprint training in hypoxia". Br J Sports Med. 47: i45–i50. doi:10.1136/bjsports-2013-092741. PMC 3903143. PMID 24282207.
  19. ^ Bogdanis, GC; Nevill, ME; Boobis, LH; Lakomy, HK (1 March 1996). "Contribution of phosphocreatine and aerobic metabolism to energy supply during repeated sprint exercise". Journal of Applied Physiology. 80 (3): 876–884. doi:10.1152/jappl.1996.80.3.876. PMID 8964751. S2CID 19815357.
  20. ^ Neil, Stacey (2017-10-17). "Oxygen enrichment to enhance training effectiveness and physiological adaptation". Zenodo. doi:10.5281/zenodo.1013924.
  21. ^ . Altitude.org. Archived from the original on 2010-04-16. Retrieved 2010-07-03.
  22. ^ Levine, BD; Stray-Gundersen, J (November 2005). "Point: positive effects of intermittent hypoxia (live high:train low) on exercise performance are mediated primarily by augmented red cell volume". Journal of Applied Physiology. 99 (5): 2053–5. doi:10.1152/japplphysiol.00877.2005. PMID 16227463. S2CID 11660835.
  23. ^ a b Gore, CJ; Hopkins, WG (November 2005). "Counterpoint: positive effects of intermittent hypoxia (live high:train low) on exercise performance are not mediated primarily by augmented red cell volume". Journal of Applied Physiology. 99 (5): 2055–7, discussion 2057–8. doi:10.1152/japplphysiol.00820.2005. PMID 16227464.
  24. ^ Prchal, JT; Pastore, YD (2004). "Erythropoietin and erythropoiesis: polycythemias due to disruption of oxygen homeostasis". Hematology Journal. 5: S110–S113. doi:10.1038/sj.thj.6200434. PMID 15190290.
  25. ^ Chapman, R; Levine, BD (2007). "Altitude training for the marathon". Sports Medicine. 37 (4): 392–395. doi:10.2165/00007256-200737040-00031. PMID 17465617. S2CID 20397972.
  26. ^ Rupert, JL; Hochachka, PW (2001). "Genetic approaches to understanding human adaptation to altitude in the Andes". Journal of Experimental Biology. 204 (Pt 18): 3151–60. doi:10.1242/jeb.204.18.3151. PMID 11581329.
  27. ^ Zoll, J; Ponsot, E; Dufour, S; Doutreleau, S; et al. (April 2006). "Exercise training in normobaric hypoxia in endurance runners. III. Muscular adjustments of selected gene transcripts". J. Appl. Physiol. 100 (4): 1258–66. doi:10.1152/japplphysiol.00359.2005. PMID 16540710. S2CID 2068027.
  28. ^ Ponsot, E; Dufour, SP; Zoll, J; Doutrelau, S; et al. (April 2006). "Exercise training in normobaric hypoxia in endurance runners. II. Improvement of mitochondrial properties in skeletal muscle". J. Appl. Physiol. 100 (4): 1249–57. doi:10.1152/japplphysiol.00361.2005. PMID 16339351. S2CID 3904731.
  29. ^ Bigard, AX; Brunet, A; Guezennec, CY; Monod, H (1991). "Skeletal muscle changes after endurance training at high altitude". Journal of Applied Physiology. 71 (6): 2114–2121. doi:10.1152/jappl.1991.71.6.2114. PMID 1778900.

November 20, 2023
altitude, training, practice, some, endurance, athletes, training, several, weeks, high, altitude, preferably, over, metres, above, level, though, more, commonly, intermediate, altitudes, shortage, suitable, high, altitude, locations, intermediate, altitudes, . Altitude training is the practice by some endurance athletes of training for several weeks at high altitude preferably over 2 400 metres 8 000 ft above sea level though more commonly at intermediate altitudes due to the shortage of suitable high altitude locations At intermediate altitudes the air still contains approximately 20 9 oxygen but the barometric pressure and thus the partial pressure of oxygen is reduced 1 2 Altitude training in the Swiss Olympic Training Base in the Alps elevation 1 856 m or 6 089 ft in St Moritz Depending on the protocols used the body may acclimate to the relative lack of oxygen in one or more ways such as increasing the mass of red blood cells and hemoglobin or altering muscle metabolism 3 4 5 6 Proponents claim that when such athletes travel to competitions at lower altitudes they will still have a higher concentration of red blood cells for 10 14 days and this gives them a competitive advantage Some athletes live permanently at high altitude only returning to sea level to compete but their training may suffer due to less available oxygen for workouts Altitude training can be simulated through use of an altitude simulation tent altitude simulation room or mask based hypoxicator system where the barometric pressure is kept the same but the oxygen content is reduced which also reduces the partial pressure of oxygen Hypoventilation training which consists of reducing the breathing frequency while exercising can also mimic altitude training by significantly decreasing blood and muscle oxygenation 7 Contents 1 Background history 2 Training regimens 2 1 Live high train low 2 2 Live high train high 2 3 Repeated sprints in hypoxia 2 4 Artificial altitude 3 Principles and mechanisms 3 1 Increased red blood cell volume 3 2 Other mechanisms 4 See also 5 ReferencesBackground history edit nbsp Altitude training in a low pressure room in East GermanyThe study of altitude training was heavily delved into during and after the 1968 Olympics which took place in Mexico City Mexico elevation 2 240 metres 7 349 ft It was during these Olympic Games that endurance events saw significant below record finishes while anaerobic sprint events broke all types of records 8 It was speculated prior to these events how the altitude might affect performances of these elite world class athletes and most of the conclusions drawn were equivalent to those hypothesized that endurance events would suffer and that short events would not see significant negative changes This was attributed not only to less resistance during movement due to the less dense air 9 but also to the anaerobic nature of the sprint events Ultimately these games inspired investigations into altitude training from which unique training principles were developed with the aim of avoiding underperformance Training regimens editAthletes or individuals who wish to gain a competitive edge for endurance events can take advantage of exercising at high altitude High altitude is typically defined as any elevation above 1 500 metres 5 000 ft Live high train low edit One suggestion for optimizing adaptations and maintaining performance is the live high train low principle This training idea involves living at higher altitudes in order to experience the physiological adaptations that occur such as increased erythropoietin EPO levels increased red blood cell levels and higher VO2 max 10 while maintaining the same exercise intensity during training at sea level Due to the environmental differences at high altitude it may be necessary to decrease the intensity of workouts Studies examining the live high train low theory have produced varied results which may be dependent on a variety of factors such as individual variability time spent at high altitude and the type of training program 11 12 For example it has been shown that athletes performing primarily anaerobic activity do not necessarily benefit from altitude training as they do not rely on oxygen to fuel their performances A non training elevation of 2 100 2 500 metres 6 900 8 200 ft and training at 1 250 metres 4 100 ft or less has shown to be the optimal approach for altitude training 13 Good venues for live high train low include Mammoth Lakes California Flagstaff Arizona and the Sierra Nevada near Granada in Spain 14 Altitude training can produce increases in speed strength endurance and recovery by maintaining altitude exposure for a significant period of time A study using simulated altitude exposure for 18 days yet training closer to sea level showed performance gains were still evident 15 days later 15 Opponents of altitude training argue that an athlete s red blood cell concentration returns to normal levels within days of returning to sea level and that it is impossible to train at the same intensity that one could at sea level reducing the training effect and wasting training time due to altitude sickness Altitude training can produce slow recovery due to the stress of hypoxia 16 Exposure to extreme hypoxia at altitudes above 16 000 feet 5 000 m can lead to considerable deterioration of skeletal muscle tissue Five weeks at this altitude leads to a loss of muscle volume of the order of 10 15 17 Live high train high edit In the live high train high regime an athlete lives and trains at a desired altitude The stimulus on the body is constant because the athlete is continuously in a hypoxic environment Initially VO2 max drops considerably by around 7 for every 1000 m above sea level Athletes will no longer be able to metabolize as much oxygen as they would at sea level Any given velocity must be performed at a higher relative intensity at altitude 16 Repeated sprints in hypoxia edit In repeated sprints in hypoxia RSH athletes run short sprints under 30 seconds as fast as they can They experience incomplete recoveries in hypoxic conditions The exercise to rest time ratio is less than 1 4 which means for every 30 second all out sprint there is less than 120 seconds of rest 18 When comparing RSH and repeated sprints in normoxia RSN studies show that RSH improved time to fatigue and power output RSH and RSN groups were tested before and after a 4 week training period Both groups initially completed 9 10 all out sprints before total exhaustion After the 4 week training period the RSH group was able to complete 13 all out sprints before exhaustion and the RSN group only completed 9 18 Possible physiological advantages from RSH include compensatory vasodilation and regeneration of phosphocreatine PCr The body s tissues have the ability to sense hypoxia and induce vasodilation The higher blood flow helps the skeletal muscles maximize oxygen delivery A greater level of PCr resynthesis augments the muscles power production during the initial stages of high intensity exercise 19 RSH is still a relatively new training method and is not fully understood 18 Artificial altitude edit Altitude simulation systems have enabled protocols that do not suffer from the tension between better altitude physiology and more intense workouts Such simulated altitude systems can be utilized closer to competition if necessary In Finland a scientist named Heikki Rusko has designed a high altitude house The air inside the house which is situated at sea level is at normal pressure but modified to have a low concentration of oxygen about 15 3 below the 20 9 at sea level which is roughly equivalent to the amount of oxygen available at the high altitudes often used for altitude training due to the reduced partial pressure of oxygen at altitude Athletes live and sleep inside the house but perform their training outside at normal oxygen concentrations at 20 9 Rusko s results show improvements of EPO and red cell levels Artificial altitude can also be used for hypoxic exercise where athletes train in an altitude simulator which mimics the conditions a high altitude environment Athletes are able to perform high intensity training at lower velocities and thus produce less stress on the musculoskeletal system 16 This is beneficial to an athlete who had a musculoskeletal injury and is unable to apply large amounts of stress during exercise which would normally be needed to generate high intensity cardiovascular training Hypoxia exposure for the time of exercise alone is not sufficient to induce changes in hematologic parameters Hematocrit and hemoglobin concentrations remain in general unchanged 17 There are a number of companies who provide altitude training system most notably Hypoxico Inc who pioneered the artificial altitude training systems in the mid 1990s A South African scientist named Neil Stacey has proposed the opposite approach using oxygen enrichment to provide a training environment with an oxygen partial pressure even higher than at sea level This method is intended to increase training intensity 20 Principles and mechanisms editAltitude training works because of the difference in atmospheric pressure between sea level and high altitude At sea level air is denser and there are more molecules of gas per litre of air Regardless of altitude air is composed of 21 oxygen and 78 nitrogen As the altitude increases the pressure exerted by these gases decreases Therefore there are fewer molecules per unit volume this causes a decrease in partial pressures of gases in the body which elicits a variety of physiological changes in the body that occur at high altitude 21 The physiological adaptation that is mainly responsible for the performance gains achieved from altitude training is a subject of discussion among researchers Some including American researchers Ben Levine and Jim Stray Gundersen claim it is primarily the increased red blood cell volume 22 Others including Australian researcher Chris Gore and New Zealand researcher Will Hopkins dispute this and instead claim the gains are primarily a result of other adaptions such as a switch to a more economic mode of oxygen utilization 23 Increased red blood cell volume edit nbsp Human red blood cellsAt high altitudes there is a decrease in oxygen hemoglobin saturation This hypoxic condition causes hypoxia inducible factor 1 HIF1 to become stable and stimulates the production of erythropoietin EPO a hormone secreted by the kidneys 24 EPO stimulates red blood cell production from bone marrow in order to increase hemoglobin saturation and oxygen delivery Some athletes demonstrate a strong red blood cell response to altitude while others see little or no gain in red cell mass with chronic exposure 25 It is uncertain how long this adaptation takes because various studies have found different conclusions based on the amount of time spent at high altitudes 26 While EPO occurs naturally in the body it is also made synthetically to help treat patients with kidney failure and to treat patients during chemotherapy Over the past thirty years EPO has become frequently abused by competitive athletes through blood doping and injections in order to gain advantages in endurance events Abuse of EPO however increases RBC counts beyond normal levels polycythemia and increases the viscosity of blood possibly leading to hypertension and increasing the likelihood of a blood clot heart attack or stroke The natural secretion of EPO by the human kidneys can be increased by altitude training but the body has limits on the amount of natural EPO that it will secrete thus avoiding the harmful side effects of the illegal doping procedures Other mechanisms edit Other mechanisms have been proposed to explain the utility of altitude training Not all studies show a statistically significant increase in red blood cells from altitude training One study explained the success by increasing the intensity of the training due to increased heart and respiration rate 15 This improved training resulted in effects that lasted more than 15 days after return to sea level Another set of researchers claim that altitude training stimulates a more efficient use of oxygen by the muscles 23 This efficiency can arise from numerous other responses to altitude training including angiogenesis glucose transport glycolysis and pH regulation each of which may partially explain improved endurance performance independent of a greater number of red blood cells 5 Furthermore exercising at high altitude has been shown to cause muscular adjustments of selected gene transcripts and improvement of mitochondrial properties in skeletal muscle 27 28 In a study comparing rats active at high altitude versus rats active at sea level with two sedentary control groups it was observed that muscle fiber types changed according to homeostatic challenges which led to an increased metabolic efficiency during the beta oxidative cycle and citric acid cycle showing an increased utilization of ATP for aerobic performance 29 Due to the lower atmospheric pressure at high altitudes the air pressure within the breathing system must be lower than it would be at low altitudes in order for inhalation to occur Therefore inhalation at high altitudes typically involves a relatively greater lowering of the thoracic diaphragm than at low altitudes See also editEffects of high altitude on humansReferences edit West JB October 1996 Prediction of barometric pressures at high altitude with the use of model atmospheres Journal of Applied Physiology 81 4 1850 4 doi 10 1152 jappl 1996 81 4 1850 PMID 8904608 Online high altitude oxygen and pressure calculator Altitude org Archived from the original on 2010 02 01 Retrieved 2010 07 03 Formenti F Constantin Teodosiu D Emmanuel Y Cheeseman J et al June 2010 Regulation of human metabolism by hypoxia inducible factor Proceedings of the National Academy of Sciences of the USA 107 28 12722 12727 Bibcode 2010PNAS 10712722F doi 10 1073 pnas 1002339107 PMC 2906567 PMID 20616028 Wehrlin JP Zuest P Hallen J Marti B June 2006 Live high train low for 24 days increases hemoglobin mass and red cell volume in elite endurance athletes J Appl Physiol 100 6 1938 45 doi 10 1152 japplphysiol 01284 2005 PMID 16497842 S2CID 2536000 a b Gore CJ Clark SA Saunders PU September 2007 Nonhematological mechanisms of improved sea level performance after hypoxic exposure Med Sci Sports Exerc 39 9 1600 9 doi 10 1249 mss 0b013e3180de49d3 PMID 17805094 Muza SR Fulco CS Cymerman A 2004 Altitude Acclimatization Guide US Army Research Inst Of Environmental Medicine Thermal and Mountain Medicine Division Technical Report USARIEM TN 04 05 Archived from the original on 2009 04 23 Retrieved 2009 03 05 a href Template Cite journal html title Template Cite journal cite journal a CS1 maint unfit URL link Xavier Woorons Hypoventilation training push your limits Arpeh 2014 176 p ISBN 978 2 9546040 1 5 Mexico 1968 Summer Olympics Olympics org 2018 12 18 Ward Smith AJ 1983 The influence of aerodynamic and biomechanical factors on long jump performance Journal of Biomechanics 16 8 655 658 doi 10 1016 0021 9290 83 90116 1 PMID 6643537 Gore CJ Hahn AG Aughey RJ Martin DT et al 2001 Live high train low increases muscle buffer capacity and submaximal cycling efficiency Acta Physiol Scand 173 3 275 286 doi 10 1046 j 1365 201X 2001 00906 x PMID 11736690 Levine BD Stray Gunderson J 2001 The effects of altitude training are mediated primarily by acclimatization rather than by hypoxic exercise Advances in Experimental Medicine and Biology Vol 502 pp 75 88 doi 10 1007 978 1 4757 3401 0 7 ISBN 978 1 4419 3374 4 PMID 11950157 Stray Gundersen J Chapman RF Levine BD 2001 Living high training low altitude training improves sea level performance in male and female elite runners Journal of Applied Physiology 91 3 1113 1120 doi 10 1152 jappl 2001 91 3 1113 PMID 11509506 Rodriguez FA Truijens MJ Townsend NE Stray Gundersen J et al 2007 Performance of runners and swimmers after four weeks of intermittent hypobaric hypoxic exposure plus sea level training Journal of Applied Physiology 103 5 1523 1535 doi 10 1152 japplphysiol 01320 2006 PMID 17690191 S2CID 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