An athlete is defined as an individual, whether amateur or professional, who receives regular exercise training and participates in official sports competitions, whether young or adult (1). Volleyball is a complex team sport with an average match duration of 60-90 minutes, which imposes different physical and cognitive demands (2). Volleyball is a sport that requires explosive power, endurance and speed. Volleyball athletes use their physical capacities, such as jumping, quick changes of direction and focus, to the maximum. Research shows that volleyball players train three to five days a week and participate in special exercises to increase their muscular endurance and conditioning (3). Volleyball, an open skill sport, requires motor movements characterized by effective visual search and action anticipation in dynamic and complex environments (4). Increased ability for action anticipation is closely associated with the ability to effectively "read the game" and having superior game intelligence (5), which is a prerequisite for successfully applying techniques and tactics (4). Consequently, physical performance, including vertical jump, short-distance agility, and spiking, as well as perceptual-cognitive performance, are key determinants of volleyball performance (6). Fatigue is common in sports, especially in high-intensity, long-duration activities such as volleyball (7). A comprehensive understanding of how fatigue affects action anticipation and physical performance is crucial to developing effective training strategies for top-level volleyball players (8).
Female athletes may have different hormonal structures, training responses, and muscle recovery processes. In this context, it is thought that muscle recovery is slower in female athletes and that they may face a higher risk of inflammation. It is stated that the anterior cruciate ligament injury rates are four to eight times higher in women than in men (9). It is thought that female volleyball players need additional support to prevent muscle damage during their weekly training and match periods, especially during intense training periods (8).
Omega-3 polyunsaturated fatty acids (PUFA) cannot be produced by the human body, so it is important to get them through diet or supplements. There are three main omega-3 fatty acids: alpha-linolenic acid (ALA, 18:3 n-3), eicosapentaenoic acid (EPA, 20:5 n-3), and docosahexaenoic acid (DHA, 22:6 n-3). ALA is found in plant-based sources such as flaxseed, chia seeds, and walnuts, while EPA and DHA are primarily found in seafood and fatty fish such as salmon, tuna, and mackerel (10). The benefits of omega-3 fatty acids are wide-ranging. Omega-3s are thought to have anti-inflammatory and anti-thrombotic properties, lower plasma triglycerides and low-density lipoprotein cholesterol, improve vasomotor and endothelial function, and inhibit cell growth factors (11). Studies have confirmed that omega-3 supplements strengthen memory, reduce symptoms of depression, prevent age-related cognitive decline, and are effective in treating depression (10,12,13).
In athletes, omega-3 fatty acids are particularly notable for their properties such as accelerating muscle repair and recovery, reducing post-exercise inflammation, and increasing endurance. Recently, it has been accepted that omega-3 may play a role in these processes, not only counteracting exercise-induced inflammation but also improving muscle health and energy utilization, and may be used as an ergogenic supplement. It has been shown that it can contribute to a faster recovery process in athletes by reducing post-exercise inflammation and muscle damage, and that it can have positive effects on endurance athletes by increasing muscle protein synthesis in athletes (14). It has been shown that regular omega-3 intake in athletes reduces inflammation levels, supports cardiovascular health, and has positive effects on general health (15). A randomized controlled trial has shown that omega-3 reduces exercise-induced muscle damage in athletes (16).
A review has shown that omega-3 use in team athletes has positive effects on athlete performance (17). Meta-analysis studies have reported that omega-3 use in endurance athletes reduces inflammation and muscle damage markers (18) and muscle pain after exercise (19). It has been stated that omega-3 supplements applied to athletes of both genders are beneficial for skeletal muscle adaptations and body recomposition (20). It has been concluded that omega-3 supplements applied to professional rugby athletes help reduce muscle pain and better preserve explosive power (21). It has been stated that omega-3 fatty acid supplements given to male athletes do not have a significant effect on improving muscle damage (22). It has been reported that omega-3 enriched chicken egg supplements to male athletes reduce oxidative stress and have positive effects against physical stress (23). Studies on female athletes are quite limited in the scientific literature. A randomized controlled study conducted with female athletes has indicated that omega-3 supplements may be effective in the recovery process after training (24).
The effects of omega-3 intake on body composition are still unclear, but they appear to increase muscle synthesis (25, 26) or limit muscle loss (27). A randomized controlled trial has shown that omega-3 supplementation in athletes has positive effects on muscle gain and fat loss (28). In addition, there is no clear standard in the literature regarding EPA and DHA ratios. While most studies have preferred 60% EPA and 40% DHA ratios, some studies have changed these ratios according to the physiological needs of athletes. In particular, it is known that high EPA ratios support inflammation-reducing effects, while DHA has neurological benefits. However, most studies conducted on female athletes have not examined the effects of these proportional differences (29). This is considered an important deficiency in the literature.
This planned study aims to determine the effects of omega-3 supplementation on exercise performance, body composition and appetite status in female volleyball players with a single-blind, randomized and placebo-controlled design.
Hypotheses:
H0a: Given omega-3 supplementation has no effect on exercise performance in women's volleyball team athletes.
H1a: Given omega-3 supplementation has an effect on exercise performance in women's volleyball team athletes.
H0b: Given omega-3 supplementation has no effect on body composition in women's volleyball team athletes.
H1b: Given omega-3 supplementation has an effect on body composition in women's volleyball team athletes.
H0c: Given omega-3 supplementation has no effect on appetite in women's volleyball team athletes.
H1c: Given omega-3 supplementation has an effect on appetite in women's volleyball team athletes.
