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Carmen Bott November 18, 2003 HKIN 562

OVERTRAINING SYNDROME A Review of Contributing Factors and Markers of Regeneration Status among Anaerobic, Intermittent Sport Athletes. Carmen Bott November 18, 2003 HKIN 562. Overtraining Syndrome.

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Carmen Bott November 18, 2003 HKIN 562

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  1. OVERTRAINING SYNDROME A Review of Contributing Factors and Markers of Regeneration Status among Anaerobic, Intermittent Sport Athletes Carmen Bott November 18, 2003 HKIN 562

  2. Overtraining Syndrome • The process of training excessively and the fatigue state and associated symptoms that result • Overtraining is the stimulus, OTS is the consequence • An imbalance between stress of training and athlete’s tolerance of the stress

  3. Overtraining Syndrome • Occurs when actual physical performances are adversely affected and cannot be reversed without long-term rest and recovery • Diagnosis is one of exclusion, not inclusion.

  4. Classical Symptoms • Physiological • Psychological • Immunological • Biochemical Fry et al 1991

  5. Physiological • Decreased performance (time, %RM) • Inability to meet previous performance • Recovery Prolonged • Decreased muscular strength & work capacity • Loss of Coordination • Chronic Fatigue

  6. Psychological • Feelings of Depression • General Apathy • Emotional instability • Difficulty concentrating • Fear of competition

  7. Immunological • Increased susceptability to and severity of illnesses, colds and allergies • Flu-like illness • Minor scratches that heal slowly • Bacterial infections

  8. Biochemical • Negative Nitrogen balance • Depressed muscle glycogen concentration • Mineral depletion (zinc, cobalt, aluminum, selenium, copper) • Elevated cortisol • Low free testosterone

  9. Forms of OTS Sympathetic Overtraining Sx • Increased pulse rate at rest, decreased body mass, disturbed sleep, decreased pulse recovery, decreased appetitie, emotional instability Parasympathetic Overtraining Sx • Progressive anaemia, low blood pressure, digestive disturbances, early fatigue, low resting pulse, fast return of heart rate to basal levels, decreased PBL, altered immune function, high fatigue ratings

  10. Characteristics of Both Forms • SOTS: stress response that proceeds exhaustion, may predominantly effect speed and power athletes and athletes who are younger. Also seems to be related to inappropriately intensive training sessions and too much psycho-emotional stress. • POTS: associated with exhaustion of the neuroendocrine system, may predominantly affect endurance athletes

  11. Diagnostic Complications • Some symptoms may predispose other symptoms • Some may disappear, while others appear in their place • Different types of activity produces different symptoms • No clear point where training fatigue finishes and overtraining begins

  12. Who is Susceptible? • Athletes at all levels of performance • Highly motivated athletes • Athletes with amateur coaches • Sports where strength, speed and coordination are essential (Wolf 1961, found symptoms of OTS 73 of 95 cases) • Athletes trying to “make the jump” to the next level • Athletes with little training experience

  13. A Continuum of OT Sx (Fry et al) Some symptoms disappear Increasing state of fatigue Continued intensive training Increasing complexity & severity of Sx Acute fatigue Overload stimulus Over-reaching OTS

  14. Pathogenesis

  15. The Glutamine Hypothesis • AA found within the human body; produced in skeletal muscle • Glutamine homeostasis placed under stress when tissues are stressed catabolically (surgery, trauma, burns, acidosis) • Stores can become depleted – can drop 2x during intense endurance exercise

  16. Exercise-induced Immunosuppression • Acute bout of exercise produces similar responses to infection – increase in number of leukocytes • Between 3 and 72 hrs post exercise, viruses and bacteria may threaten the immune system and increase risk of infection • Insufficient recovery = cumulative effect

  17. Tissue Trauma • Occurs when: training is strenuous and exhaustive, an athlete increases exercise volume & or intensity, abruptly + not enough recovery • Markers of tissue damage include creatine kinase, serum urea, myoglobin, 3-methyl-histidine and C-reactive protein.

  18. Tissue Trauma • Overload injuries due to repetitive microtrauma present a more gradual onset of symptoms compared to acute injuries • Repetitive forces encountered on landing and push-off must be considered. • Fatigued muscles, resulting from adapting to higher training loads, may react in the same manner as weak muscles & become strained

  19. High Impact Forces • Muscles that contract quickly to absorb force are likely the source of microtrauma • Ground reaction forces (absent in cycling) • Eccentric contractions result in greater muscle fiber injury • Concentric hypoxia = muscle ischemia?? • No, b/c circulating monocytes are not activated and CTK not elevated

  20. The Cytokine Hypothesis • Exercise-induced microtrauma to the musculoskeletal system and the inflammatory response is the precursor episode(s) to OTS • Local inflammation leads to chronic inflammation when recovery is insufficient

  21. The Cytokine Hypothesis • Neutrophil accumulation monocyte accumulation • Upregulation of cytokines • Released from monocytes; they direct local inflammatory responses and activate immune cells and direct influx of WBCs

  22. Pro-inflammatory Cytokines • The release from monocytes causes systemic inflammation and a paradigm of sickness behaviour and subsequent activation of the SNS and the HPAA. • Released in large quantities, therefore they can act on several organ systems

  23. Exercise Prescription Variables • During anabolic phase, training stimulus is most effective • Supercompensation depends on magnitude of stimulus • Principles: Individualization, Specificity, Progressive Overload • Training Variables: exercise choice & sequence, # sets and reps, rest periods, tempos

  24. Review of Markers

  25. Detection of Impending OTS: • Endocrine Markers • Testosterone, cortisol and ftes:cort • Catecholamines • Plasma Markers • Creatine Phosphokinase (CPK) • Peak Blood Lactate • Glutamine • Cytokines

  26. Detection of Impending OTS: • Biochemical Markers • Muscle glycogen stores • Physiological Markers • Heart Rate – resting, maximal, variability • Psychological & Info processing Markers • Questionnaires • Logs and RPE • Profile of mood states

  27. Testosterone • Steroid hormone responsible for many anabolic and androgenic qualities • Acute bouts of heavy RT = increased **total levels • Affected by chronic RT = increased • Increased RT volume = decreased resting levels, which may impact protein synthesis in skeletal muscle tissue and neural regulation of muscle activity

  28. Cortisol • Also a steroid hormone • Increases gluconeogenic activity in the liver, decreasing glucose uptake and increasing glycogen synthesis in muscle tissue and mobilizing AA • Important during recovery b/c protein-catabolic effect on skeletal muscle

  29. Cortisol • Reflects long-term training stress (> 1mo) • Elevated levels found in overtrained athletes • Increase RT Vol & Intensity, cort levels • HI RT + HI EE = cort levels • MAXIMAL RT overtraining has no change • **therefore data on endurance athletes cannot be compared to anaerobic athletes

  30. FTES: CORT • Indicator of anabolic-catabolic status of the individual • Correlation exists between an increase in strength and increase in ratio • Decreaes of 30% indicate insufficient regeneration in sprint and strength sports • Responses can vary from different exercise prescriptions • Can vary over the course of a mesocycle

  31. Free Testosterone and Cortisol

  32. Free Testosterone and Cortisol

  33. Catecholamines • Regulate metabolic and cardiocirculatory reactions and adaptations to physical and psychological stress. • Exercise induced responses are due to SNS input and correlated with exercise intensity • Shorter high intensity exercise results in greater catecholamine secretion and shows a higher Epi:NE ratio

  34. Catecholamines • Due to NE spillover from SNS synapses • Also, high psych stress during physical exercise is followed by obvious increases in Epi and NE. • With endurnace training, a decrease in glycogen availablility increases catecholamine levels, yet resting levels decreased.

  35. Problems with Hormonal Markers

  36. Plasma Creatine Kinase • A well-documented index of muscle damge in athletes • Found to be elevated in some along with elevations of myoglobin and lactate dehydrogenase • Well-trained athletes may not exhibit increased levels (reg ecc training) • Females – estrogen may have a membrane stabilizing effect

  37. Peak Plasma Lactate • Intermediate product in the breakdown of glycogen • Decreased PBL response indicates parasympathetic OT (standardized maximal test) • Corresponds with glycogen level depletion

  38. Resting and Peak Blood Lactate

  39. Resting and Peak Blood Lactate

  40. Plasma Glutamine • Decrease could be due to an increased demand by tissues, decreased production or altered transport kinetics • Baseline levels are higher in elite athletes • Acute OT = depressed levels of plasma glutamine (no studies on O-R) after prolonged exercise but not after short-term exercise

  41. Glutamine • 5 days of overload training resulted in decreased levels and permanently low levels found during periods of prolonged training and in OT athletes • Linked to chronic states of fatigue • Plasma levels increase temporarily after injestion of a meal containing protein

  42. Endurance athletes at rest and after 2-3 weeks of heavy intensified training Source: Gleeson, Review 2002

  43. Resistance Exercise Overreaching and Overtraining Fry and Kraemer 124

  44. References • Halson, S. G.I. Lancaster, A. Jeukendrup, and M. Gleeson. Immunological Respnses to overreaching in cyclists. Medicine and Science in Sports and exercise. 35 (5) 854-861. 2003. • Hooper, Sue et al.: Markers for Monitoring Overtraining and Recovery. Medicine and Science in Sports and Exercise 1995 106-112. • Kraemer, William J.:Strength Training Basics, Designing Work-outs to Meet Patient’s Goals. The Physician and Sports Medicine 2003;31(8):39-45. • Lehmann, M, Foster, C, Dickhuth, Hans-Herman, Uwe, A: Autonomic imbalance hypothesis and overtraining syndrome. Medicine and Science in Sports and Exercise, 1998 30(7) 1140-1145. • Lieber, Richard an Friden, Jan.: Muscle Damage is not a function of muscle force but of active muscle strain. Journal of Applied Physiology 1993; 74: 520-526. • Petibois, Cyril et al.: Biochemical Aspects of Overtraining in Endurance Sports. Review Article. Sports Medicine 2002; 32(13): 867-878. • Pichot, V., T.Busso, F. Roche, M. Garet, F. Costes, D. Duverney, J.R. Lacour and J.C. Barthelemy. Autonomic adaptations to intensive and overload training periods: a laboratory study. Medicine and Science in Sports and Exercise. Vol 34(10), 1660-1666. 2002. • Rowbottom, David, Keat, David and Morton, Alan. The emerging role of glutamine as an indicator of exercise stress and overtraining a review. Sports Medicine 1996; 21 (2): 80-97. • Rowbottom, Keast, Goodman and Morton: The haematological, biochemical and immunological profile of athletes suffering from the overtraining syndrome. European Journal of Applied Physiology 1995; 70: 502-509. • Smith, Lucille Lakier.: Overtraining, Excessive Exercise, and Altered Immunity. Review Article. Sports Medicine 2003; 33(5): 347-364. • Snyder, Ann C., H Kuipers, Bo Cheng, Rodrique Servais and Erik Fransen. Overtraining following intensified training with normal muscle glycogen. Medicine and Science in Sports and exercise, 1995 10631070, 1995. • ACSM position paper: http://www.acsm.org/USOC_ACSMconsensus.htm pp 1-6.

  45. References • Clarkson, PM, Nosaka, K. Muscle Finction after exercise-induced muscle damage and rapid adaptation. Medicine and Science in Sports and Exercise. 24(5); 512-20, 1992 • Clarkson, PM, Tremblay, I. Exercise-induced muscle damage and rapid adaptation in humans. Journal of Applied Physiology. 65(1) 1-6, 1988. • Dressendorfer RH, Wade CE, Iverson D (987( Decereased Plasma testosterone in overtrained runners (abstract). Med Sci Sports exerc 19:S10. • Fry A.C. and Kraemer, W.J. Resistance exercise overtraining and overreaching neuroendocrine responses Review Article, Sports Medicine. 1997 23 (2) 106-129 • Fry A.C., Kraemer, W.J., Van Borselen, F, Lynch, J.M. Triplett, N.T., Koziris, L.P., Fleck, S.J: Catecholamine responses to short-term high-intensity resistance exercise overtraining. Journal of Applied Physiology 941-945. • Fry, R.W. et al.: Psychological and immunological correlates of acute overtraining. British Journal of Sports Medicine 1994; 28(4) 241-245. • Fry R.W, Morton Alan, Garcia Webb Peter and Keast, David: Monitoring exercise stress by changes in metabolic and hormonal responses over a 24-h period. European Journal of Applied Physiology 1991 63: 228-234. • Fry R.W., Morton, A, Keast, D. Overtraining in Athletes An Update: Review Article. Sports Medicine 12(1): 32-65, 1991. • Gleeson, Michael. Biochemical and immunological markers of overtraining: Review. Journal of sports Science and Medicine 2002 1, 31-41.

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