• Men playing ice hockeyEccentric vs. Concentric

    Eccentric muscle actions have considerable differences from concentric muscle actions. It has been demonstrated that the neuromuscular system can produce more force in eccentric actions, and at the same time have less electrical activity as measured by Electromyography (EMG) (11). 
    The practical application of these differences manifests itself in the realization that the loads used for resistance training are limited by concentric strength. Augmented Eccentric Loading (AEL) attempts to apply overload to the neuromuscular system by applying an increased eccentric load immediately followed by concentric actions with a reduced load.

    The chronic effects of augmented eccentric loading on muscle strength have been demonstrated in several studies, most showing that the strength gains are similar to or greater than traditional loading (1,3,4,5,7). Other methods of applying AEL are to acute strength performance, or acute high-velocity performance, such as jumps or throws (2,9,10). 
    The sheer number of acute training variables that can be manipulated in an AEL protocol makes it difficult to draw clear conclusions on its efficacy for acute performance, with both successful, and equivocal findings (2,9,10). However, it seems the existing body of literature suggests that AEL may be a worthwhile inclusion to the training of athletes.

    Several methods of augmented eccentric loading for acute performance have been suggested (8). 
    The most common way to apply augmented eccentric loading is the use of depth jumps. By dropping from a box, the mass of the body is allowed a longer time to accelerate, and thus a greater impulse is needed to change direction of the center of mass of the body upon contact with the ground.   
    This method is popular, as it forces the individual to have a high rate of force development because the time to develop enough force for the jump is finite. However, the high rate of loading in these types of jump is not always desirable, and other methods of applying a supramaximal eccentric load are available.

    Other than the application of increasing drop heights, AEL for jumps may be accomplished by holding dumbbells or kettlebells in the hands that are released at the bottom of the range of motion (ROM). This allows the concentric portion to be loaded with only body mass (Figure 1). 
    It should be noted that safety must be addressed so that the implements do not interfere with the jump landing. Elastic bands can also be used, and with the help of others the band tension can be released at the bottom of the ROM; again allowing for reduced load in the subsequent concentric action (8). A sample plyometric training program utilizing AEL is seen in Table 1.

    AEL Figure 1 
    Figure 1. Dumbbell AEL Depth Jumps (8) 

    (a) Beginning of dumbbell depth jump. (b) Landing phase of dumbbell depth jump. (c) Jumping phase of dumbbell depth jump.

    AEL Figure 1 
    Table 1. Sample Plyometric Training Program Using AEL (8) 

    Weight releasers are devices that can be suspended from the bar and loaded with weight (Figures 2 and 3). Their design allows for adjustments to the ROM, so that the bottom of the ROM will cause contact with the weight releaser and the floor, thus removing the extra load and allowing for a concentric action with less load. 
    These devices have been used successfully in several investigations (2,9,10). Since these devices may be somewhat uncommon, other methods may also be used in a similar manner. Empirically, some have used a power rack and spotting pins to allow the load to be suspended for a short period of time at the bottom of the ROM, in which helpers can remove some of the load from the barbell and allow for a lighter concentric action.  
    This may be useful for doing consecutive AEL repetitions, but the time between the eccentric and concentric actions as well as the requisite coordination between helpers and the athlete may make this method more difficult to implement. Recommendations for loading with weight releasers are included in Table 2.

    AEL Figure 1 
    Figure 2. Weight Releaser (8)  

    AEL Figure 1 
    Figure 3. Weight Releaser (8)  

    (a) Beginning of jump squat with weight releasers. (b) Jumping phase of jump squat following the release of the weight. (c) Landing phase of jump squat with weight releasers.

    AEL Figure 1 
    Table 2. Recommendations for Loading Weight Releasers (8)   

    Understanding the unique force generating characteristics of eccentric muscle actions is a key component in optimizing neuromuscular adaptations to training. The previously mentioned training means may offer coaches and athletes a new method to help them reach their performance goals. While research in this area is sparse, this type of loading still allows for overload, and at the very least is a unique training stress that can be easily implemented into an athlete’s training program.
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    1. Brandenburg, J, and Docherty, D. The effects of accentuated eccentric loading on strength, muscle hypertrophy, and neural adaptations in trained individuals. Journal of Strength and Conditioning Research 16: 25–32, 2002.
    2. Doan, B, Newton, R, Marsit, J, Triplet-McBride, N, Koziris, L, Fry, A, and Kraemer, W. Effects of increased eccentric loading on bench press 1RM. Journal of Strength and Conditioning Research 16: 9–13, 2002.
    3. Friedmann, B, Kinscherf, R, Vorwald, S, Muller, H, Kucera, K, Borisch, S, Richter, G, Bartsch, P, and Billeter, R. Muscular adaptations to computer-guided strength training with eccentric overload. Acta Physiologica Scandinavica 182: 77–88, 2004.
    4. Hortobagyi, T and Devita, P. Favorable neuromuscular and cardiovascular responses to 7 days of exercise with an eccentric overload in elderly women. Journal of Gerontol A Biol Sci Med Sci 55:B401–B410, 2000.
    5. Hortobagyi, T, Devita, P, Money, J, and Barrier, J. Effects of standard and eccentric overload strength training in young women. Medicine and Science in Sports and Exercise 33: 1206–1212, 2001.
    6. Howatson, G, and Van Someren, K. The prevention and treatment of exercise-induced muscle damage. Sports Medicine 38(6): 483–503, 2008.
    7. Kaminski, T, Wabbersen, C, and Murphy, R. Concentric versus enhanced eccentric hamstring strength training: Clinical implications. Journal of Athletic Training 33: 216–221, 1998.
    8. Moore, C, and Schilling, B. Theory and application of augmented eccentric loading. Strength Conditioning Journal 27(5): 20–27, 2005.
    9. Moore, C, Weiss, L, Schilling, B, Fry, A, and Li, Y. Acute effects of augmented eccentric loading on jump squat performance. Journal of Strength and Conditioning Research 21: 157–162, 2007.
    10. Sheppard, J, and Young, K. Using additional eccentric loads to increase concentric performance in the bench throw. Journal of Strength and Conditioning Research 24: 2853–2856, 2010.
    11. Westing, S, Cresswell, A, and Thorstensson, A. Muscle activation during maximal voluntary eccentric and concentric knee extension. European Journal of Applied Physiology 62(2): 104–108, 1991.