International Journal of Scientific and Research Publications, Volume 4, Issue 6, June 2014 1 ISSN 2250-3153 www.ijsrp.org Association between Body Mass Index and Cognitive Performance in Rugby Players Mohamed Ali Baccouche 1 , Ichraf Arous 1 , Hanen Sellami 2 , Ali Elloumi 3 1 Research Unit, High Institute of Sport and Physical Education, University of Sfax, Tunisia. 2 Department of Microbiology and Research Laboratory “Microorganismes et Pathologies Humaines”, Habib Bourguiba University Hospital, Medical School of Sfax, University of Sfax, Tunisia. 3 Labortory SYFACTE , Faculty of Letters and Humanities, University of Sfax, Tunisia. Abstract- Poor cardiovascular fitness has been implicated as a possible mechanism for obesity- related cognitive decline, though no study has examined whether BMI is associated with poorer cognitive function in persons with excellent fitness levels. The aim of this study is to investigate the relationship between body mass index and cognitive performance in rugby players. Thus, fifteen rugby players male aged 24.7 ± 0.9 voluntarily participated in this study, whose body mass index (BMI) was greater than 30. The intercorrelations matrix between BMI and the five ImPACT composite scores showed that BMI is negatively correlated with verbal memory (r= -0.181; p<0.01), visual memory (r= -0.172; p<0.01) and visual motor speed (r= - 0.103; p<0.05). Also, the results showed that there was no significant correlation between BMI and reaction time or between BMI and impulse control. The findings of the current study indicate that BMI is negatively associated with cognitive function in a sample expected to have better than average cardiovascular fitness. BMI was found to be associated with reduced cognitive performance in rugby players, but only in specific areas of functioning. Notably, measures of memory had the greatest associations with BMI while no association was found on measures related to executive function and attention. Index Terms- Body mass index, cognitive performance, rugby players I. INTRODUCTION verweight and obesity are a major public health issue. Despite increased awareness, the prevalence of obesity continues to rise in many countries. In 2008, an estimated 1.5 billion people worldwide were overweight (BMI ≥ 25–29.9 kg/m 2 ), with 500 million considered obese (BMI ≥ 30 kg/m2) [1]. Overweight and obese individuals are at elevated risk for numerous health problems, including cardiovascular disease, type 2 diabetes, musculoskeletal disorders, and even some forms of cancer [1, 2]. There is growing evidence that obesity is also associated with adverse neurocognitive outcomes including Alzheimer’ s disease [3], stroke, and vascular dementia [4]. Research also demonstrates an association between obesity and impaired cognitive functioning long prior to the onset of these conditions. Even after controlling for comorbid medical conditions, obese individuals exhibit deficits in multiple cognitive domains, including attention, executive function, and memory [5, 6]. The mechanisms for obesity-related cognitive dysfunction remain poorly understood. Neuroimaging studies link obesity to structural and functional changes, including greater atrophy, development of white matter hyperintensities [7], reduced neural connectivity [8], and decreased blood flow in frontal brain regions [9]. Other work demonstrates aspects of glycemic controls, including altered insulin sensitivity and insulin resistance, as important contributors to obesity-related cognitive dysfunction [10, 11]. Another likely contributor to obesity-related cognitive dysfunction is reduced cardiovascular fitness. Many obese individuals have poor cardiovascular fitness, perhaps attributable to low levels of physical activity found in this population [12, 13]. In turn, low levels of cardiovascular fitness are associated with reduced cognitive function in a variety of healthy and patient samples [14, 15], and improvements in cardiovascular fitness correspond to improved neuropsychological test performance [8, 14, 16, 17]. Similarly, a weight loss program combining diet and exercise was associated with improved neurocognitive functioning in obese adults [18]. The regular practice of physical activity is now recognized as an important element of good physical and mental health and this for all ages. The effect of physical activity on the brain, particularly on cognitive function is a recent approach. The most obvious benefits are observed in the elderly in whom physical activity helps people to slow cognitive decline associated with aging [19, 20, 21]. Childhood is a critical period in the development of certain cognitive functions [22, 23] and young people are confronted daily with learning situations. Thus, determining the effects of physical activity on cognitive functioning in children appears an important public health issue. However, a deterioration of the physical condition of young observed in recent decades [24]. Thus, further knowledge about the relationship between physical activity, cognitive functioning and physiological mechanisms underlying this relationship could guide the development of public health policy and education. The effects of physical activity induce a transient modification of the cognitive performance in children and adolescents [25]. This is the case of Pesce et al. [26] who examined the short- term memory and long term memory in students of 11 and 12 years who participated in either circuit training or a team sport. The two types of physical exercise were similar intensity and duration, that is to say approximately 40 minutes at an average of about 140 bpm FC. This research reveals that team sport has O