Difference between revisions of "Mechanisms of Overtraining Syndrome"

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There are many proposed mechanisms behind Overtraining Syndrome, but none of them are generally accepted<ref name="OTPhysioReview"/><ref name="OTDepression"/>.
+
There are many proposed mechanisms behind [[Overtraining Syndrome]], but none of them are generally accepted<ref name="OTPhysioReview"/><ref name="OTDepression"/>.
* '''Glycogen hypothesis'''. One hypothesis is that Overtraining Syndrome produces chronically depleted glycogen levels leading to the problems of Overtraining Syndrome. While there is evidence of lower blood sugar in overtrained athletes, glycogen stores are generally replenished between exercises<ref name="OTBiochemical"/>. Studies<ref name="OTCostill"/><ref name="OTSnyder"/> have concluded that glycogen depletion was not responsible for short term Overtraining Syndrome. There is also the suggestion<ref name="OTBiochemical"/> that glycogen depletion has a knock on effect of increasing BCAA oxidation which in turn causes Overtraining Syndrome symptoms (see below).
+
* '''[[Glycogen]] hypothesis'''. One hypothesis is that [[Overtraining Syndrome]] produces chronically depleted [[Glycogen]] levels leading to the problems of [[Overtraining Syndrome]]. While there is evidence of lower blood sugar in overtrained athletes, [[Glycogen]] stores are generally replenished between exercises<ref name="OTBiochemical"/>. Studies<ref name="OTCostill"/><ref name="OTSnyder"/> have concluded that [[Glycogen]] depletion was not responsible for short term [[Overtraining Syndrome]]. There is also the suggestion<ref name="OTBiochemical"/> that [[Glycogen]] depletion has a knock on effect of increasing BCAA oxidation which in turn causes [[Overtraining Syndrome]] symptoms (see below).
* '''BCAA hypothesis'''<ref name="OTBiochemical"/>. This hypothesis suggests that BCAA is used in higher amounts by the muscles because of glycogen depletion. This BCAA consumption indirectly leads to a rise in tryptophan, and tryptophan is able to enter the brain where it is converted to serotonin. This increase in serotonin is linked to clinical depression and could cause symptoms of Overtraining Syndrome. However consumption of BCAA during or after exercise has not been shown to help.
+
* '''BCAA hypothesis'''<ref name="OTBiochemical"/>. This hypothesis suggests that BCAA is used in higher amounts by the muscles because of [[Glycogen]] depletion. This BCAA consumption indirectly leads to a rise in tryptophan, and tryptophan is able to enter the brain where it is converted to serotonin. This increase in serotonin is linked to clinical depression and could cause symptoms of [[Overtraining Syndrome]]. However consumption of BCAA during or after exercise has not been shown to help.
 
* '''Free fatty acid hypothesis'''<ref name="OTDepression"/>. As mentioned in the BCAA hypothesis the levels of brain serotonin depend largely on the level of tryptophan in the blood, and tryptophan increases with higher free fatty acid plasma levels. Because endurance training tends to increase the level of free fatty acids in the blood, this hypothesis proposes that excessive endurance training raises the blood free fatty acid which raises the tryptophan levels which in turn raise the serotonin levels.
 
* '''Free fatty acid hypothesis'''<ref name="OTDepression"/>. As mentioned in the BCAA hypothesis the levels of brain serotonin depend largely on the level of tryptophan in the blood, and tryptophan increases with higher free fatty acid plasma levels. Because endurance training tends to increase the level of free fatty acids in the blood, this hypothesis proposes that excessive endurance training raises the blood free fatty acid which raises the tryptophan levels which in turn raise the serotonin levels.
* '''Glutamine hypothesis'''<ref name="OTBiochemical"/><ref name="OTPhysioReview"/>. Endurance exercise deplete glutamine levels and glutamine is important for immune system functioning. However decreased levels of glutamine have not been observed in overtrained athletes<ref name=" OTBiochemical "/>, and glutamine would only explain the compromised immune system, not other symptoms of Overtraining Syndrome.
+
* '''Glutamine hypothesis'''<ref name="OTBiochemical"/><ref name="OTPhysioReview"/>. Endurance exercise deplete glutamine levels and glutamine is important for immune system functioning. However decreased levels of glutamine have not been observed in overtrained athletes<ref name=" OTBiochemical "/>, and glutamine would only explain the compromised immune system, not other symptoms of [[Overtraining Syndrome]].
* '''Hypothalamus<ref name="OTBiochemical "/>/Adrenal Fatigue Syndrome<ref name="OTAdrenal"/> hypothesis'''. This hypothesis is based around compromise of the hypothalamus, pituitary gland or adrenal gland, which are all responsible for hormone levels. This hypothesis may have some limited support from the success in treating Overtraining Syndrome syndrome with hormone replacement therapy.
+
* '''Hypothalamus<ref name="OTBiochemical "/>/Adrenal Fatigue Syndrome<ref name="OTAdrenal"/> hypothesis'''. This hypothesis is based around compromise of the hypothalamus, pituitary gland or adrenal gland, which are all responsible for hormone levels. This hypothesis may have some limited support from the success in treating [[Overtraining Syndrome]] with hormone replacement therapy.
* '''Muscle damage hypothesis<ref name="OTBiochemical "/><ref name="OTTrauma"/>'''. Exercise induces damage to the muscle cells and this hypothesis suggests that this damage is the underlying root cause of Overtraining Syndrome. It is deemed unlikely that Overtraining Syndrome would be caused directly muscular damage, but rather this damage would precipitate other changes leading to Overtraining Syndrome<ref name="OTBiochemical"/>. It is been observed<ref name="OTSickAnimals"/> that wounded animals exhibit "recuperative behavior", where they become lethargic, less sociable, and exhibit reduced appetite and thirst. This behavior is believed to encourage recovery by reducing activity and exposure to predators. This "recuperative behavior" in some ways mimics Overtraining Syndrome and depression in human beings. Unfortunately this hypothesis has never been supported by objective measurement<ref name="OTBiochemical"/>.
+
* '''[[Muscle]] damage hypothesis<ref name="OTBiochemical "/><ref name="OTTrauma"/>'''. Exercise induces damage to the muscle cells and this hypothesis suggests that this damage is the underlying root cause of [[Overtraining Syndrome]]. It is deemed unlikely that [[Overtraining Syndrome]] would be caused directly muscular damage, but rather this damage would precipitate other changes leading to [[Overtraining Syndrome]]<ref name="OTBiochemical"/>. It is been observed<ref name="OTSickAnimals"/> that wounded animals exhibit "recuperative behavior", where they become lethargic, less sociable, and exhibit reduced appetite and thirst. This behavior is believed to encourage recovery by reducing activity and exposure to predators. This "recuperative behavior" in some ways mimics [[Overtraining Syndrome]] and depression in human beings. Unfortunately this hypothesis has never been supported by objective measurement<ref name="OTBiochemical"/>.
* '''Brain receptor hypothesis'''<ref name="OTDepression"/>.''' '''Exposure to chronic stress may lead to altered neurotransmitter receptors within the brain. Changes in these neurotransmitter receptors can modify the fundamental mechanisms of the brain and are believed to play a role in both Overtraining Syndrome and major depression.
+
* '''Brain receptor hypothesis'''<ref name="OTDepression"/>.''' '''Exposure to chronic stress may lead to altered neurotransmitter receptors within the brain. Changes in these neurotransmitter receptors can modify the fundamental mechanisms of the brain and are believed to play a role in both [[Overtraining Syndrome]] and major depression.
 
* '''Brain plasticity hypothesis'''<ref name="OTDepression"/>. The human brain retains the ability to update its 'neurological wiring', which is part of our ability to adapt and learn. This neural plasticity is one of the adaptations that occurs to long-term exercise. While mild levels of exercise in harms the creation of new neurons, severe exercise stress causes neurological degradation.
 
* '''Brain plasticity hypothesis'''<ref name="OTDepression"/>. The human brain retains the ability to update its 'neurological wiring', which is part of our ability to adapt and learn. This neural plasticity is one of the adaptations that occurs to long-term exercise. While mild levels of exercise in harms the creation of new neurons, severe exercise stress causes neurological degradation.
* '''Immune system hypothesis'''<ref name="OTDepression"/>. Several case histories of linked Overtraining Syndrome to a recent infection. Given the depression is the most consistent symptom of infectious diseases in humans, there is a hypothesis that an infection is a triggering event for Overtraining Syndrome. It is then believed that other mechanisms maintain the depressive state causing prolonged Overtraining Syndrome symptoms.
+
* '''Immune system hypothesis'''<ref name="OTDepression"/>. Several case histories of linked [[Overtraining Syndrome]] to a recent infection. Given the depression is the most consistent symptom of infectious diseases in humans, there is a hypothesis that an infection is a triggering event for [[Overtraining Syndrome]]. It is then believed that other mechanisms maintain the depressive state causing prolonged [[Overtraining Syndrome]] symptoms.
 
* '''Muscle calcium hypothesis'''<ref name="OTPhysioReview"/>. Calcium is part of the mechanism behind muscle contraction and this hypothesis proposes that less calcium is released in overtrained state, which limits muscular contraction. The problem with this hypothesis is that it would only explain physical performance problems, not the immune system or [[Mood State]] changes.
 
* '''Muscle calcium hypothesis'''<ref name="OTPhysioReview"/>. Calcium is part of the mechanism behind muscle contraction and this hypothesis proposes that less calcium is released in overtrained state, which limits muscular contraction. The problem with this hypothesis is that it would only explain physical performance problems, not the immune system or [[Mood State]] changes.
 
+
* '''Negative feedback hypothesis'''<ref name="OvertraingInSport"/>. It has been suggested that [[Overtraining Syndrome]] is one of the negative feedback systems in the body that prevents damage, similar to the [[Central Governor Theory]].
 
=References=
 
=References=
 
<references>
 
<references>
Line 21: Line 21:
 
<ref name="OTCostill">Effects of repeated days of intensified... [Med Sci Sports Exerc. 1988] - PubMed - NCBI http://www.ncbi.nlm.nih.gov/pubmed/3386503 </ref>
 
<ref name="OTCostill">Effects of repeated days of intensified... [Med Sci Sports Exerc. 1988] - PubMed - NCBI http://www.ncbi.nlm.nih.gov/pubmed/3386503 </ref>
 
<ref name="OTSnyder">Overtraining and glycogen depletion hyp... [Med Sci Sports Exerc. 1998] - PubMed - NCBI http://www.ncbi.nlm.nih.gov/pubmed/9662687 </ref>
 
<ref name="OTSnyder">Overtraining and glycogen depletion hyp... [Med Sci Sports Exerc. 1998] - PubMed - NCBI http://www.ncbi.nlm.nih.gov/pubmed/9662687 </ref>
 +
<ref name="OvertraingInSport">Overtraining In Sport, Kreider, Fry, O'Toole, Human Kinetics</ref>
 
</references>
 
</references>

Latest revision as of 04:55, 16 April 2013

There are many proposed mechanisms behind Overtraining Syndrome, but none of them are generally accepted[1][2].

  • Glycogen hypothesis. One hypothesis is that Overtraining Syndrome produces chronically depleted Glycogen levels leading to the problems of Overtraining Syndrome. While there is evidence of lower blood sugar in overtrained athletes, Glycogen stores are generally replenished between exercises[3]. Studies[4][5] have concluded that Glycogen depletion was not responsible for short term Overtraining Syndrome. There is also the suggestion[3] that Glycogen depletion has a knock on effect of increasing BCAA oxidation which in turn causes Overtraining Syndrome symptoms (see below).
  • BCAA hypothesis[3]. This hypothesis suggests that BCAA is used in higher amounts by the muscles because of Glycogen depletion. This BCAA consumption indirectly leads to a rise in tryptophan, and tryptophan is able to enter the brain where it is converted to serotonin. This increase in serotonin is linked to clinical depression and could cause symptoms of Overtraining Syndrome. However consumption of BCAA during or after exercise has not been shown to help.
  • Free fatty acid hypothesis[2]. As mentioned in the BCAA hypothesis the levels of brain serotonin depend largely on the level of tryptophan in the blood, and tryptophan increases with higher free fatty acid plasma levels. Because endurance training tends to increase the level of free fatty acids in the blood, this hypothesis proposes that excessive endurance training raises the blood free fatty acid which raises the tryptophan levels which in turn raise the serotonin levels.
  • Glutamine hypothesis[3][1]. Endurance exercise deplete glutamine levels and glutamine is important for immune system functioning. However decreased levels of glutamine have not been observed in overtrained athletes[3], and glutamine would only explain the compromised immune system, not other symptoms of Overtraining Syndrome.
  • Hypothalamus[3]/Adrenal Fatigue Syndrome[6] hypothesis. This hypothesis is based around compromise of the hypothalamus, pituitary gland or adrenal gland, which are all responsible for hormone levels. This hypothesis may have some limited support from the success in treating Overtraining Syndrome with hormone replacement therapy.
  • Muscle damage hypothesis[3][7]. Exercise induces damage to the muscle cells and this hypothesis suggests that this damage is the underlying root cause of Overtraining Syndrome. It is deemed unlikely that Overtraining Syndrome would be caused directly muscular damage, but rather this damage would precipitate other changes leading to Overtraining Syndrome[3]. It is been observed[8] that wounded animals exhibit "recuperative behavior", where they become lethargic, less sociable, and exhibit reduced appetite and thirst. This behavior is believed to encourage recovery by reducing activity and exposure to predators. This "recuperative behavior" in some ways mimics Overtraining Syndrome and depression in human beings. Unfortunately this hypothesis has never been supported by objective measurement[3].
  • Brain receptor hypothesis[2]. Exposure to chronic stress may lead to altered neurotransmitter receptors within the brain. Changes in these neurotransmitter receptors can modify the fundamental mechanisms of the brain and are believed to play a role in both Overtraining Syndrome and major depression.
  • Brain plasticity hypothesis[2]. The human brain retains the ability to update its 'neurological wiring', which is part of our ability to adapt and learn. This neural plasticity is one of the adaptations that occurs to long-term exercise. While mild levels of exercise in harms the creation of new neurons, severe exercise stress causes neurological degradation.
  • Immune system hypothesis[2]. Several case histories of linked Overtraining Syndrome to a recent infection. Given the depression is the most consistent symptom of infectious diseases in humans, there is a hypothesis that an infection is a triggering event for Overtraining Syndrome. It is then believed that other mechanisms maintain the depressive state causing prolonged Overtraining Syndrome symptoms.
  • Muscle calcium hypothesis[1]. Calcium is part of the mechanism behind muscle contraction and this hypothesis proposes that less calcium is released in overtrained state, which limits muscular contraction. The problem with this hypothesis is that it would only explain physical performance problems, not the immune system or Mood State changes.
  • Negative feedback hypothesis[9]. It has been suggested that Overtraining Syndrome is one of the negative feedback systems in the body that prevents damage, similar to the Central Governor Theory.

References

  1. 1.0 1.1 1.2 Physiological Perspective of Endurance Overtraining – A Comprehensive Update http://ajms.alameenmedical.org/article_vol05-1-jan-mar-2012/AJMS.5.1.2012%20P%207-20.pdf
  2. 2.0 2.1 2.2 2.3 2.4 The unknown mechanism of the overtraining syndrom... [Sports Med. 2002] - PubMed - NCBI http://www.ncbi.nlm.nih.gov/pubmed/11839081
  3. 3.0 3.1 3.2 3.3 3.4 3.5 3.6 3.7 3.8 Biochemical aspects of overtraining in endurance ... [Sports Med. 2002] - PubMed - NCBI http://www.ncbi.nlm.nih.gov/pubmed/12392446
  4. Effects of repeated days of intensified... [Med Sci Sports Exerc. 1988] - PubMed - NCBI http://www.ncbi.nlm.nih.gov/pubmed/3386503
  5. Overtraining and glycogen depletion hyp... [Med Sci Sports Exerc. 1998] - PubMed - NCBI http://www.ncbi.nlm.nih.gov/pubmed/9662687
  6. Alternative & Complementary Concepts/ Adrenal Fatigue Syndrome, Part 2: Adrenal Function and Overtraining http://journals.humankinetics.com/att-back-issues/ATTVolume15Issue2March/ALTERNATIVECOMPLEMENTARYCONCEPTSAdrenalFatigueSyndromePart2AdrenalFunctionandOvertraining
  7. Tissue trauma: the underlying cause of o... [J Strength Cond Res. 2004] - PubMed - NCBI http://www.ncbi.nlm.nih.gov/pubmed/14971991
  8. Biological basis of the behavior of si... [Neurosci Biobehav Rev. 1988] - PubMed - NCBI http://www.ncbi.nlm.nih.gov/pubmed/3050629
  9. Overtraining In Sport, Kreider, Fry, O'Toole, Human Kinetics