Difference between revisions of "The Science of Intermittent Hypoxic Exposure"

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* Subjects exposed hypoxia in a hypobaric chamber showed elevated EPO levels after 114 mins at 9,000 feet and or after 84 minutes at 12,000 feet. EPO levels continued to rise with longer exposure. <ref name="acu"/>
 
* Subjects exposed hypoxia in a hypobaric chamber showed elevated EPO levels after 114 mins at 9,000 feet and or after 84 minutes at 12,000 feet. EPO levels continued to rise with longer exposure. <ref name="acu"/>
 
* Research using the AltoLab system showed a significant improvement in sprint speed. The study used 6 mins hypoxia (10,000 to 18,000 ft) with 4 min recovery for an hour a day for 15 days. The study shown a tiny improvement in blood parameters (hemoglobin/hematocrit) normally associated with altitude training.<ref name="alto"/>
 
* Research using the AltoLab system showed a significant improvement in sprint speed. The study used 6 mins hypoxia (10,000 to 18,000 ft) with 4 min recovery for an hour a day for 15 days. The study shown a tiny improvement in blood parameters (hemoglobin/hematocrit) normally associated with altitude training.<ref name="alto"/>
 +
* IHT increased lung force in asthmatic and non-asthmatic athletes. There was no deterioration in asthma status from the trial, and half of the asthmatics reported a reduction in the need for medication. The trial used 15 sessions over three weeks, with each session being 5 mins hypoxia followed by 5 mins normal air, repeated for 60 minutes. The hypoxia was equivalent to 22,500 ft.<ref name="asthmatic"/> Other studies have reported a similar improvement in asthma, with reduced attacks, reduced severity of attacks and reduced need for medicatin.
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==See Also==
 
==See Also==
 
* [[Altitude Training]]
 
* [[Altitude Training]]
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<ref name="jack">http://jap.physiology.org/cgi/content/full/96/5/1800 Intermittent normobaric hypoxia does not alter performance or erythropoietic markers in highly trained distance runners</ref>
 
<ref name="jack">http://jap.physiology.org/cgi/content/full/96/5/1800 Intermittent normobaric hypoxia does not alter performance or erythropoietic markers in highly trained distance runners</ref>
 
<ref name="USSR">http://www.ncbi.nlm.nih.gov/pubmed/12162864 Intermittent hypoxia research in the former soviet union and the commonwealth of independent States: history and review of the concept and selected applications.</ref>
 
<ref name="USSR">http://www.ncbi.nlm.nih.gov/pubmed/12162864 Intermittent hypoxia research in the former soviet union and the commonwealth of independent States: history and review of the concept and selected applications.</ref>
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<ref name="asthmatic">http://www.hypoxico.com/images/pdfs/Does_IHT_effect_the_lung_function_of_asthmatic_athletes.pdf Does IHT effect the lung function of asthmatic athletes</ref>
 
</references>
 
</references>

Revision as of 16:47, 22 June 2010

Use of Intermittent Hypoxic Training (IHT) is relatively new in the west, but the USSR (and later CIS) has been researching and using IHT since the 1930's. Usage includes sports, altitude acclimatization, and treatment of clinical disorders, including chronic lung diseases, bronchial asthma, hypertension, diabetes mellitus, Parkinson’s disease, emotional disorders, and even radiation toxicity.

1 Mechanisms

There appear to be three mechanisms underlying the effects of IHT: regulation of respiration, mitochondrial respiration, and free-radical production.

  • The regulation of respiration results in increased sensitivity of breathing rate to altitude, improved gas exchange in the lungs and changes to the autonomic nervous system.
  • Improvements in mitochondrial respiration results in optimized use of oxygen in energy production.
  • Exposure to both low and normal oxygen levels improves the body's antioxidant defense.

The research shows that there is wide individual variation in the response to IHT and altitude. This variation exists in both humans and animals, and appears to be due to mechanisms beyond simple iron insufficiency.

2 Research from the USSR[1]

  • Expose subjects to 15,000 feet for 1 hour per day over several days for 7 to 11 sessions showed increased blood O2 compared with initial exposure and the benefits were detectable for up to 4 weeks.
  • Exposure of 30 mins to 3 hours every 2 to 3 days for 9 exposures increased hemoglobin by 12% and red blood cells by 22%
  • Exposure of 3x (6 min low O2, 4 min normal air) per day for 14 days increased breathing volume at altitude by ~50%. PO2 started at 50 mmHg (20,000 ft) dropping to 35 mmHg (28,000 ft). Several studies have shown similar results.
  • 5x (15 min 11% O2 + 15 min recovery) for 14 day produced changes to the metabolic pathways that optimize the use of oxygen.
  • Studies in rats suggest that continuous exposure to altitude reduces anti-oxidant defenses, but IHT improves them.
  • Other studies in rats indicate that IHT changes the ratio of fat to protein burning in favor of fats by 80%.
  • A study of workers that cleaned up after Chernobyl nuclear reactor explosion showed that they had higher levels of oxidant stress where higher than normal. Exposing the workers to IHT of 3x (5 mins 7-8% [28,000+ ft] O2 with 5 mins normal air) for 14 days significantly reduced the oxidant stress.
  • Studies have shown IHT reduces the oxidant stress associated with bronchial asthma. (There were large variations in individual response, and more research is needed.)
  • Recent studies indicate that IHT stimulates NO (Nitric Oxide) production, with the excess stored in the vascular walls. This improves blood pressure.
  • Research indicates that there is a very wide variability in the response to altitude (IHT or other) and tolerance of extreme hypoxia. Future research may provide methods of overcoming the lack of response in some individuals.

3 Western Research

  • Research [2] using highly trained runners showed no running improvement with IHT This research used simulated altitudes of 15,000 at the start rising to 20,000 feet at the end. This gave O2 saturations of 90% at the start, going down to 80% at the end. The athletes were given 5 mins hypoxic, 5 mins nomal for 70 minutes total for five days per week, 4 weeks total. Given the research from the USSR, it is possible that the 7x 5 minutes exposure is insufficient to gain the required benefits.
  • A study[3] looking at Hypoxia EPO, a hormone that stimulates red blood cell production showed a ~50% increase in EPO from 4 hours of IHT or 2 hours of continuous hypoxia, but no response from 5 minutes or 1 hour. The IHT was a simulated altitude of 18,000 ft
  • Subjects exposed hypoxia in a hypobaric chamber showed elevated EPO levels after 114 mins at 9,000 feet and or after 84 minutes at 12,000 feet. EPO levels continued to rise with longer exposure. [4]
  • Research using the AltoLab system showed a significant improvement in sprint speed. The study used 6 mins hypoxia (10,000 to 18,000 ft) with 4 min recovery for an hour a day for 15 days. The study shown a tiny improvement in blood parameters (hemoglobin/hematocrit) normally associated with altitude training.[5]
  • IHT increased lung force in asthmatic and non-asthmatic athletes. There was no deterioration in asthma status from the trial, and half of the asthmatics reported a reduction in the need for medication. The trial used 15 sessions over three weeks, with each session being 5 mins hypoxia followed by 5 mins normal air, repeated for 60 minutes. The hypoxia was equivalent to 22,500 ft.[6] Other studies have reported a similar improvement in asthma, with reduced attacks, reduced severity of attacks and reduced need for medicatin.

4 See Also

5 References

  1. http://www.ncbi.nlm.nih.gov/pubmed/12162864 Intermittent hypoxia research in the former soviet union and the commonwealth of independent States: history and review of the concept and selected applications.
  2. http://jap.physiology.org/cgi/content/full/96/5/1800 Intermittent normobaric hypoxia does not alter performance or erythropoietic markers in highly trained distance runners
  3. http://jap.physiology.org/cgi/content/abstract/73/3/837 Erythropoietin response to acute normobaric hypoxia in humans
  4. http://jap.physiology.org/cgi/content/abstract/66/4/1785?ijkey=5bbdebe4e97a65aad9ea16d9d6a7f0c9de2d7dc0&keytype2=tf_ipsecsha Rate of erythropoietin formation in humans in response to acute hypobaric hypoxia
  5. http://www.pharmapacific.com/images/AltoLab_Clinical_Research_Study.pdf Running performance and altitude exposure
  6. http://www.hypoxico.com/images/pdfs/Does_IHT_effect_the_lung_function_of_asthmatic_athletes.pdf Does IHT effect the lung function of asthmatic athletes