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Recovery in football
Several forms of recovery exist and depending on the time, equipment and staff available, post-exercise recovery strategies may vary.
Usually, recovery procedures can be divided into active and passive recovery.
Active recovery
- Low/intensity exercise at various percentage of VO2max (1-6) - see references below
- Running (7, 8)
- Cycling
- Resistance training
- Water exercise (1)
- Stretching (7, 8)
Passive recovery
- Stretching
- Cryotherapy/Water immersion (cold, warm, contrast) (9, 10)
- Eating/Hydration (8, 11-13)
- Massage (2, 3, 14-16)
- Rest/sleep (3-6, 15)
- Sauna (17)
- Electrostimulation (1)
- Equipment (compression socks etc.) (18-20)
Combined methods
- Massage and active methods (2)
Active versus passive recovery
There are several studies which investigated the effect of active vs. passive recovery.
It seems that active recovery was superior over passive recovery in removal of lactate (2, 5, 6, 15, 16, 21-24). However, the success of active recovery seemed to depend on the intensity of
activity (1-6, 23).
A possible downfall of active recovery seemed to be the smaller (24) and/or a negative effect (25, 26) on glycogen resynthesis (the re-establishment of glycogen stores from glucose). The highest
rate of glycogen resynthesis was seen during the initial two hours (27) post-exercise (and simple sugars seemed to be better suited compared to complex sugars during that time (28)). However, the
rate of glycogen resynthesis was also dependent on the type of exercise and reported higher in short term high intensity and resistance exercise compared to prolonged exercise (29).
However, combined methods were also shown more effective than active and passive recovery (2).
With the mentioned information in mind it seems important to look for certain aspects/variables/exercises and possible time-frames to decide over recovery procedures. We have therefore defined
two categories.
A) Physical performance
| Physical performance | Active recovery | Passive recovery |
| Sprint ability | ~ 5 h (30) |
|
| High intensity exercise | shorter | longer (4, 31) |
| Repeated sprint ability | ~ 48 h (7) | |
| Isokinetic knee extension | ~ 27 h (30) | |
| Isokinetic knee flexion | ~ 51 h (30) |
|
B) Physiological variables
| Physiological variable | Active recovery | Passive recovery |
| Lactate removal |
|
~ 45 min (24) |
| Gycogen resynthesis |
~ 48 h (7) ~ 69 h (30) |
~ 1 hour - 80% of pre-exercise values (12) ~ 2 hours - 60% of pre-exercise values (25) |
| Muscle soreness |
References
1. Tessitore, A., et al. Effectiveness of active versus passive recovery strategies after futsal games. J.
Strength. Cond. Res. 22(5): 1402-1412, 2008.
2. Monedero, J. and B. Donne. Effect of recovery interventions on lactate removal and subsequent
performance. Int. J. Sports. Med. 21(8): 593-597, 2000
3. Lane, K. N. and H. A. Wenger. Effect of selected recovery conditions on performance of repeated bouts
of intermittent cycling separated by 24 hours. J. Strength. Cond. Res. 18(4): 855-860, 2004.
4. Dupont, G., et al. Passive versus active recovery during high-intensity intermittent exercises. Med. Sci.
Sports. Exerc. 36(2): 302-308, 2004
5. Bonen, A. and A. N. Belcastro. Comparison of self-selected recovery methods on lactic acid removal
rates. Med Sci Sports. 8(3): 176-178, 1976
6. Taoutaou, Z., et al. Lactate kinetics during passive and partially active recovery in endurance and sprint
athletes. Eur. J. Appl. Physiol. Occup. Physiol. 73(5): 465-470, 1996
7. Reilly, T. and M. Rigby, Effect of an active warm-down following competitive soccer, in Science and
football IV, Spinks W, Reilly T, and Murphy A, Editors. 2002, Routledge: London. p. 226-229
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619-627, 2005
9. Wilcock, I. M., J. B. Cronin and W. A. Hing. Physiological response to water immersion: a method
for sport recovery? Sports. Med. 36(9): 747-765, 2006.
10. Kinugasa, T. and A. E. Kilding. A comparison of post-match recovery strategies in youth soccer players.
J. Strength. Cond. Res. 23(5): 1402-1407, 2009.
11. Clarke, N. D., et al. Strategies for hydration and energy provision during soccer-specific exercise. Int. J.
Sport. Nutr. Exerc. Metab. 15(6): 625-640, 2005
12. Pedersen, D. J., et al. High rates of muscle glycogen resynthesis after exhaustive exercise when
carbohydrate is coingested with caffeine. J. Appl. Physiol. 105(1): 7-13, 2008.
13. Casey, A., et al. Glycogen resynthesis in human muscle fibre types following exercise-induced
glycogen depletion. J. Physiol. 483 (Pt 1): 265-271, 1995.
14. Robertson, A., J. M. Watt and S. D. Galloway. Effects of leg massage on recovery from high intensity
cycling exercise. Br J Sports Med. 38(2): 173-176, 2004.
15. Gupta, S., et al. Comparative study of lactate removal in short term massage of extremities, active
recovery and a passive recovery period after supramaximal exercise sessions. Int. J. Sports. Med. 17(2): 106-110, 1996.
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blood lactate clearance after supramaximal leg exercise. J. Athl. Train. 33(1): 30-35, 1998
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performance following high-intensity sprint and plyometric exercise. J. Sci. Med. Sport. 13(1): 136-140, 2010.
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recovery on consecutive days. Int. J. Sports. Physiol. Perform. 3(4): 454-468, 2008
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thermoregulation during simulated team sport activity in temperate environmental conditions. J. Sci. Med. Sport. 12(2): 303-309, 2009.
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intensive exercise. Med. Sci. Sports. Exerc. 28(4): 450-456, 1996.
22. Bond, V., et al. Effects of active and passive recovery on lactate removal and subsequent isokinetic
muscle function. J. Sports. Med. Phys. Fitness. 31(3): 357-361, 1991.
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1622-1629, 1985
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