Iron Supplementation and Eccentric Exercise

Eccentric muscle work is an essential part of human daily activities, such as walking, and in particular, when walking downhill or descending stairs. It is also a component of almost all of the athletic actions. The most notable and well-described effect of eccentric exercise is the muscle damage that peaks one to three days after exercise and is accompanied by several hematological, biochemical and physiological responses. Excessive production of reactive oxygen and nitrogen species (RONS) has been reported as a result of eccentric exercise. The typical approach so far, was to provide antioxidants to minimize oxidative stress, yet the effectiveness of such an approach is still under debate. Earlier studies reported positive effects of antioxidant supplementation on muscle performance, muscle damage and redox status, whereas more recently, well-received studies pointed towards the negative impact of antioxidant supplementation.

Iron is an essential element for the completion of numerous important biological functions, and also for optimal exercise performance. It is a vital component for the formation of oxygen-transport and iron-storage proteins hemoglobin and myoglobin, and for the most favorable function of many oxidative enzymes that affect the intracellular metabolism. Therefore, iron supplementation is commonly used to avoid exercise-induced perturbations of iron homeostasis and maintain the required iron stores that are necessary to address exercise needs or enhance physical performance. Iron is also characterized as a potent pro-oxidant, as it can lead to increased production of reactive oxygen and nitrogen species (RONS) that are involved in critical biological processes, such as gene expression, signal transduction and enzyme activity. Nevertheless, the role of iron on modifying redox responses after eccentric exercise has not yet been examined.

In a double blind, randomized cross over study that will be conducted in two cycles, healthy men and boys will receive either the iron supplement (37mg of elemental iron per day for three weeks before and one week after the eccentric exercise) or the placebo.

Blood samples will be collected: a) in adults prior to, at the end of first supplementation period, 24, 48,72 and 96 hours following an acute bout of eccentric exercise (5 sets x 15 max reps), and b) in children prior to, at the end of first supplementation period and 72 hours following the same exercise protocol. Blood drawings will be repeated at the same time points during the second supplementation cycle.

The aims of the present research are to investigate:

• The effect of an acute bout of eccentric exercise on muscle performance, redox status, and iron status.
• The effect of three weeks of iron supplementation on muscle performance, redox status, and iron status.
• The effect of four weeks of iron supplementation on muscle damage, muscle performance, and redox status after an acute eccentric exercise bout.
• The effect of age on muscle damage, muscle performance and redox status after an acute eccentric exercise bout and iron supplementation.