Excess post-exercise oxygen consumption

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Excess post-exercise oxygen consumption (EPOC, informally called afterburn) is a measurably increased rate of oxygen intake following strenuous activity. In historical contexts the term "oxygen debt" was popularized to explain or perhaps attempt to quantify anaerobic energy expenditure, particularly as regards lactic acid/lactate metabolism; [1] in fact, the term "oxygen debt" is still widely used to this day. [2] However, direct and indirect calorimeter experiments have definitively disproven any association of lactate metabolism as causal to an elevated oxygen uptake. [3]

Contents

In recovery, oxygen (EPOC) is used in the processes that restore the body to a resting state and adapt it to the exercise just performed. These include: hormone balancing, replenishment of fuel stores, cellular repair, innervation, and anabolism. Post-exercise oxygen consumption replenishes the phosphagen system. New ATP is synthesized and some of this ATP donates phosphate groups to creatine until ATP and creatine levels are back to resting state levels again. Another use of EPOC is to fuel the body’s increased metabolism from the increase in body temperature which occurs during exercise. [4]

EPOC is accompanied by an elevated consumption of fuel. In response to exercise, fat stores are broken down and free fatty acids (FFA) are released into the blood stream. In recovery, the direct oxidation of free fatty acids as fuel and the energy consuming re-conversion of FFAs back into fat stores both take place. [5] [6] [7]

Illustration of the old "oxygen debt" theory Excess post-oxygen consumption (2).jpg
Illustration of the old "oxygen debt" theory

Duration of the effect

The EPOC effect is greatest soon after the exercise is completed and decays to a lower level over time. One experiment, involving exertion above baseline,[ clarification needed ] found EPOC increasing metabolic rate to an excess level that decays to 13% three hours after exercise, and 4% after 16 hours, for the studied exercise dose.[ citation needed ] Another study, specifically designed to test whether the effect existed for more than 16 hours, conducted tests for 48 hours after the conclusion of the exercise and found measurable effects existed up to the 38-hour post-exercise measurement, for the studied exercise dose. [8]

Size of the EPOC effect

Studies show that the EPOC effect exists after both aerobic exercise [9] and anaerobic exercise.[ citation needed ] In a 1992 Purdue study, results showed that high intensity, anaerobic type exercise resulted in a significantly greater magnitude of EPOC than aerobic exercise of equal work output. [10] For exercise regimens of comparable duration and intensity, aerobic exercise burns more calories during the exercise itself,[ citation needed ] but the difference is partly offset by the higher increase in caloric expenditure that occurs during the EPOC phase after anaerobic exercise.[ citation needed ] Anaerobic exercise in the form of high-intensity interval training was also found in one study to result in greater loss of subcutaneous fat, even though the subjects expended fewer than half as many calories during exercise. [11] Whether this result was caused by the EPOC effect has not been established, and the caloric content of the participants' diet was not controlled during this particular study period.[ citation needed ]


Most researchers use a measure of EPOC as a natural part of the quantification or measurement of exercise and recovery energy expenditure; to others this is not deemed necessary. After a single bout or set of weight lifting, Scott et al. found considerable contributions of EPOC to total energy expenditure. [12] In their 2004 survey of the relevant literature, Meirelles and Gomes found: "In summary, EPOC resulting from a single resistance exercise session (i.e., many lifts) does not represent a great impact on energy balance; however, its cumulative effect may be relevant". [13] This is echoed by Reynolds and Kravitz in their survey of the literature where they remarked: "the overall weight-control benefits of EPOC, for men and women, from participation in resistance exercise occur over a significant time period, since kilocalories are expended at a low rate in the individual post-exercise sessions." [14]

The EPOC effect clearly increases with the intensity of the exercise, and (at least in the case of aerobic exercise, perhaps also for anaerobic) the duration of the exercise. [9]

Studies comparing intermittent and continuous exercise consistently show a greater EPOC response for higher intensity, intermittent exercise. [15]

See also

Related Research Articles

The muscular system is an organ system consisting of skeletal, smooth, and cardiac muscle. It permits movement of the body, maintains posture, and circulates blood throughout the body. The muscular systems in vertebrates are controlled through the nervous system although some muscles can be completely autonomous. Together with the skeletal system in the human, it forms the musculoskeletal system, which is responsible for the movement of the body.

<span class="mw-page-title-main">Aerobic exercise</span> Low to high intensity physical exercise

Aerobic exercise is physical exercise of low to high intensity that depends primarily on the aerobic energy-generating process. "Aerobic" is defined as "relating to, involving, or requiring oxygen", and refers to the use of oxygen to meet energy demands during exercise via aerobic metabolism adequately. Aerobic exercise is performed by repeating sequences of light-to-moderate intensity activities for extended periods of time. Examples of cardiovascular or aerobic exercise are medium- to long-distance running or jogging, swimming, cycling, stair climbing and walking.

<span class="mw-page-title-main">Exercise physiology</span>

Exercise physiology is the physiology of physical exercise. It is one of the allied health professions, and involves the study of the acute responses and chronic adaptations to exercise. Exercise physiologists are the highest qualified exercise professionals and utilise education, lifestyle intervention and specific forms of exercise to rehabilitate and manage acute and chronic injuries and conditions.

<span class="mw-page-title-main">Physical fitness</span> State of health and well-being

Physical fitness is a state of health and well-being and, more specifically, the ability to perform aspects of sports, occupations, and daily activities. Physical fitness is generally achieved through proper nutrition, moderate-vigorous physical exercise, and sufficient rest along with a formal recovery plan.

Basal metabolic rate (BMR) is the rate of energy expenditure per unit time by endothermic animals at rest. It is reported in energy units per unit time ranging from watt (joule/second) to ml O2/min or joule per hour per kg body mass J/(h·kg). Proper measurement requires a strict set of criteria to be met. These criteria include being in a physically and psychologically undisturbed state and being in a thermally neutral environment while in the post-absorptive state (i.e., not actively digesting food). In bradymetabolic animals, such as fish and reptiles, the equivalent term standard metabolic rate (SMR) applies. It follows the same criteria as BMR, but requires the documentation of the temperature at which the metabolic rate was measured. This makes BMR a variant of standard metabolic rate measurement that excludes the temperature data, a practice that has led to problems in defining "standard" rates of metabolism for many mammals.

<span class="mw-page-title-main">Anaerobic exercise</span> Physical exercise intense enough to cause lactate formation

Anaerobic exercise is a type of exercise that breaks down glucose in the body without using oxygen; anaerobic means "without oxygen". In practical terms, this means that anaerobic exercise is more intense, but shorter in duration than aerobic exercise.

<span class="mw-page-title-main">Exercise intensity</span>

Exercise intensity refers to how much energy is expended when exercising. Perceived intensity varies with each person. It has been found that intensity has an effect on what fuel the body uses and what kind of adaptations the body makes after exercise. Intensity is the amount of physical power that the body uses when performing an activity. For example, exercise intensity defines how hard the body has to work to walk a mile in 20 minutes.

<span class="mw-page-title-main">Strength training</span> Performance of physical exercises designed to improve strength

Strength training, also known as weight training or resistance training, involves the performance of physical exercises that are designed to improve strength and endurance. It is often associated with the lifting of weights. It can also incorporate a variety of training techniques such as bodyweight exercises, isometrics, and plyometrics.

<span class="mw-page-title-main">High-intensity interval training</span> Exercise strategy

High-intensity interval training (HIIT) is a training protocol alternating short periods of intense or explosive anaerobic exercise with brief recovery periods until the point of exhaustion. HIIT involves exercises performed in repeated quick bursts at maximum or near maximal effort with periods of rest or low activity between bouts. The very high level of intensity, the interval duration, and number of bouts distinguish it from aerobic (cardiovascular) activity, because the body significantly recruits anaerobic energy systems. The method thereby relies on "the anaerobic energy releasing system almost maximally".

Specific dynamic action (SDA), also known as thermic effect of food (TEF) or dietary induced thermogenesis (DIT), is the amount of energy expenditure above the basal metabolic rate due to the cost of processing food for use and storage. Heat production by brown adipose tissue which is activated after consumption of a meal is an additional component of dietary induced thermogenesis. The thermic effect of food is one of the components of metabolism along with resting metabolic rate and the exercise component. A commonly used estimate of the thermic effect of food is about 10% of one's caloric intake, though the effect varies substantially for different food components. For example, dietary fat is very easy to process and has very little thermic effect, while protein is hard to process and has a much larger thermic effect.

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Interval training is a type of training exercise that involves a series of high-intensity workouts interspersed with rest or break periods. The high-intensity periods are typically at or close to anaerobic exercise, while the recovery periods involve activity of lower intensity. Varying the intensity of effort exercises the heart muscle, providing a cardiovascular workout, improving aerobic capacity and permitting the person to exercise for longer and/or at more intense levels.

Lactate inflection point (LIP) is the exercise intensity at which the blood concentration of lactate and/or lactic acid begins to increase rapidly. It is often expressed as 85% of maximum heart rate or 75% of maximum oxygen intake. When exercising at or below the lactate threshold, any lactate produced by the muscles is removed by the body without it building up.

<span class="mw-page-title-main">Sports nutrition</span> Study and practice of nutrition to improve performance

Sports nutrition is the study and practice of nutrition and diet with regards to improving anyone's athletic performance. Nutrition is an important part of many sports training regimens, being popular in strength sports and endurance sports. Sports nutrition focuses its studies on the type, as well as the quantity of fluids and food taken by an athlete. In addition, it deals with the consumption of nutrients such as vitamins, minerals, supplements and organic substances that include carbohydrates, proteins and fats.

<span class="mw-page-title-main">Muscle hypertrophy</span> Enlargement or overgrowth of a muscle organ

Muscle hypertrophy or muscle building involves a hypertrophy or increase in size of skeletal muscle through a growth in size of its component cells. Two factors contribute to hypertrophy: sarcoplasmic hypertrophy, which focuses more on increased muscle glycogen storage; and myofibrillar hypertrophy, which focuses more on increased myofibril size. It is the primary focus of bodybuilding-related activities.

<span class="mw-page-title-main">Bioenergetic systems</span> Metabolic processes for energy production

Bioenergetic systems are metabolic processes that relate to the flow of energy in living organisms. Those processes convert energy into adenosine triphosphate (ATP), which is the form suitable for muscular activity. There are two main forms of synthesis of ATP: aerobic, which uses oxygen from the bloodstream, and anaerobic, which does not. Bioenergetics is the field of biology that studies bioenergetic systems.

<span class="mw-page-title-main">Cardiovascular fitness</span> Heart-related component of physical fitness

Cardiovascular fitness refers to a health-related component of physical fitness that is brought about by sustained physical activity. A person's ability to deliver oxygen to the working muscles is affected by many physiological parameters, including heart rate, stroke volume, cardiac output, and maximal oxygen consumption.

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The physiology of marathons is typically associated with high demands on a marathon runner's cardiovascular system and their locomotor system. The marathon was conceived centuries ago and as of recent has been gaining popularity among many populations around the world. The 42.195 km distance is a physical challenge that entails distinct features of an individual's energy metabolism. Marathon runners finish at different times because of individual physiological characteristics.

References

  1. Betts, J Gordon; Desaix, Peter; Johnson, Eddie; Johnson, Jody E; Korol, Oksana; Kruse, Dean; Poe, Brandon; Wise, James; Womble, Mark D; Young, Kelly A (June 8, 2023). Anatomy & Physiology. Houston: OpenStax CNX. 10.3 Muscle fibre contraction. ISBN   978-1-947172-04-3.
  2. "oxygen deficit, epoc, lactate threshold". www.unm.edu. Retrieved 2024-06-17.
  3. Scott, Christopher; Kemp, Richard (2005). "Direct and indirect calorimetry of lactate oxidation: Implications for whole-body energy expenditure". Journal of Sports Sciences. 23 (1): 15–9. doi:10.1080/02640410410001716760. PMID   15841591. S2CID   22784732.
  4. Saladin, Kenneth (2012). Anatomy & Physiology: The Unity of Form and Function. New York: McGraw Hill. p. 425. ISBN   978-0-07-337825-1.
  5. Bahr R (1992). "Excess postexercise oxygen consumption--magnitude, mechanisms and practical implications". Acta Physiologica Scandinavica. Supplementum. 605: 1–70. PMID   1605041.
  6. Bahr, R.; Høstmark, A. T.; Newsholme, E. A.; Grønnerød, O.; Sejersted, O. M. (1991). "Effect of exercise on recovery changes in plasma levels of FFA, glycerol, glucose and catecholamines". Acta Physiologica Scandinavica. 143 (1): 105–15. doi:10.1111/j.1748-1716.1991.tb09205.x. PMID   1957696.
  7. Bielinski, R; Schutz, Y; Jéquier, E (July 1985). "Energy metabolism during the postexercise recovery in man". The American Journal of Clinical Nutrition. 42 (1): 69–82. doi: 10.1093/ajcn/42.1.69 . PMID   3893093.
  8. Schuenke, Mark; Mikat, Richard; McBride, Jeffrey (2002). "Effect of an acute period of resistance exercise on excess post-exercise oxygen consumption: Implications for body mass management". European Journal of Applied Physiology. 86 (5): 411–7. doi:10.1007/s00421-001-0568-y. PMID   11882927. S2CID   12542325.
  9. 1 2 Børsheim, Elisabet; Bahr, Roald (2003). "Effect of Exercise Intensity, Duration and Mode on Post-Exercise Oxygen Consumption". Sports Medicine. 33 (14): 1037–60. doi:10.2165/00007256-200333140-00002. PMID   14599232. S2CID   43595995.
  10. Schmidt, Wilfred Daniel (1992). The effects of chronic and acute dehydration on high power exercise performance (Ph.D. dissertation). Purdue University. OCLC   13508540.[ page needed ]
  11. Tremblay, Angelo; Simoneau, Jean-Aimé; Bouchard, Claude (1994). "Impact of exercise intensity on body fatness and skeletal muscle metabolism". Metabolism. 43 (7): 814–8. doi:10.1016/0026-0495(94)90259-3. PMID   8028502.
  12. Scott, Christopher B; Croteau, Alicia; Ravlo, Tyler (2009). "Energy Expenditure Before, During, and After the Bench Press". Journal of Strength and Conditioning Research. 23 (2): 611–8. doi: 10.1519/JSC.0b013e31818c2845 . PMID   19197214. S2CID   1109400.
  13. Meirelles, Cláudia de Mello; Gomes, Paulo Sergio Chagas (2004). "Efeitos agudos da atividade contra-resistência sobre o gasto energético: revisitando o impacto das principais variáveis" [Acute effects of resistance exercise on energy expenditure: revisiting the impact of the training variables]. Revista Brasileira de Medicina do Esporte (in Portuguese). 10 (2): 122–30. doi: 10.1590/S1517-86922004000200006 .
  14. Reynolds, Jeff M; Kravitz, Len (2001). "Resistance training and EPOC". IDEA Personal Trainer. 12 (5): 17–9.
  15. Baker, Emily J.; Gleeson, Todd T. (1998). "EPOC and the energetics of brief locomotor activity in Mus domesticus". The Journal of Experimental Zoology. 280 (2): 114–20. doi: 10.1002/(SICI)1097-010X(19980201)280:2<114::AID-JEZ2>3.0.CO;2-R . PMID   9433798.

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