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Nutrición Hospitalaria

versión On-line ISSN 1699-5198versión impresa ISSN 0212-1611

Nutr. Hosp. vol.36 no.6 Madrid nov./dic. 2019  Epub 24-Feb-2020

http://dx.doi.org/10.20960/nh.02718 

Trabajos Originales

Consumption of meat, eggs and dairy products is associated with aerobic and anaerobic performance in Brazilian athletes – A cross-sectional study

El consumo de carne, huevos y productos lácteos se asocia al rendimiento aeróbico y anaeróbico en los deportistas brasileños: un estudio transversal

Luis Felipe Gomes1  , Hellen Clair Garcez Nabuco2  , Sérgio Itacarambi Guasque Faria3  , Allan da Mata Godois4  , Vânia Letícia Souza Fernandes1  , Fabrício César de Paula Ravagnani5  , Christianne de Faria Coelho Ravagnani6 

1Universidade Federal de Mato Grosso. Mato Grosso, Brazil.

2Instituto Federal de Ciencia e Tecnologia de Mato Grosso. Cuiabá, Mato Grosso, Brazil.

3Universidade de Cuiabá. Mato Grosso, Brazil.

4Centro Universitário de Várzea Grande. Mato Grosso, Brazil.

5Instituto Federal de Mato Grosso do Sul. Mato Grosso do Sul. Brazil.

6Universidade Federal de Mato Grosso do Sul. Mato Grosso do Sul, Brazil.

Abstract

Objective:

to associate food consumption according to the groups that make up the food pyramid with the aerobic and anaerobic performance of Brazilian athletes.

Method:

a cross-sectional study of 168 athletes with a mean age and BMI of 20.84 ± 7.74 years and 22.88 ± 3.1 kg/m2, respectively.

Results:

maximum power output was significantly associated with the meat and eggs groups (β = 0.31; p < 0.05). VO2max exhibited a positive relationship with the fruit group (β = 0.29; p < 0.05). A significant inverse relation between VO2max and the legumes group was observed (β = −0.76; p < 0.05). The meat and eggs group and the dairy products group had an inverse and significant association with VO2max (β = −0.43; p < 0.01).

Conclusions:

consumption of meat and eggs showed a positive association with anaerobic performance, whereas the same group and the dairy products group had a negative association with aerobic performance.

Key words: Food groups; VO2max; Diet; Food pyramid

Resumen

Objectivo:

asociar el consumo de alimentos según los grupos que componen la pirámide de alimentos con el rendimiento aeróbico y anaeróbico de deportistas brasileños.

Método:

estudio transversal de 168 deportistas con una media de edad e IMC de 20,84 ± 7,74 años y 22,88 ± 3,1 kg/m2, respectivamente.

Resultados:

la potencia máxima se asoció significativamente con el consumo de los grupos de carne y huevos (β = 0,31; p < 0,05). El VO2max mostró una relación positiva con el grupo de la fruta (β = 0,29; p < 0,05). Se observó una relación inversa significativa entre el VO2max y el grupo de las leguminosas (β = −0,76; p < 0,05). El grupo de carnes y huevos y el grupo de productos lácteos tuvieron una asociación inversa y significativa con el VO2max (β = −0,43; p < 0,01).

Conclusiones:

el consumo de carne y huevos mostró una asociación positiva con el rendimiento anaeróbico, mientras que el mismo grupo y los productos lácteos se asociaron de forma negativa al rendimiento aeróbico.

Palabras clave: Grupos de alimentos; VO2max; Dieta; Pirámide alimenticia

INTRODUCTION

Proper diet to the amount of physical work should be the starting point for maximum performance for high-performance athletes (1). The adequacy of energy and nutrient consumption is essential to maintaining performance, body composition and health in these individuals (2,3). Nutrition, when well targeted, can reduce fatigue, allowing the athlete to train longer or to recover better between workouts; reduce or assist in recovery from injury; increase energy deposits for competition; and finally help the general health of the athlete (4).

Qualitative food consumption, that is, the consumption seen in portions of the various food groups can affect both the nutritional status and the dietary nutrient supply (5). One of the common behaviors among athletes is the partial or total restriction of certain food groups, resulting in a consumption below that recommended for some nutrients (6) responsible for the regulation of energy metabolism, glucose and oxidative and muscle contraction, thus affecting performance (3,7).

A number of studies involving athletes are concerned with the quantitative consumption of nutrients and their effects on physical performance (8-10), but as far as we know, there are no studies that use food consumption by food groups for this same purpose and population. In 2013, Radavelli-Bagatini et al. (11) showed the association of milk consumption and milk products with performance (gripstrength, timed up and go, slow timed up and go, and self-reported falls) in the elderly. A similar study with adolescents showed that fruit and vegetable consumption was positively associated with muscle strength and potency (12). The results of this type of research may point to both the performance and the health of the population studied, suggesting the adequacy of food consumption to maintain good performance and health maintenance (13,14).

Thus, the objective of this study was to evaluate the association between the intake of the foods in the Brazilian food pyramid groups and the physical aerobic and anaerobic performance of Brazilian athletes. The present study will allow the establishment of relationships among food groups and performance in terms of potency, fatigue index and oxygen volume (VO2max), and will make it possible in the future to establish dietary guidelines specifically formulated for athletes needs.

METHODS

PARTICIPANTS

This was a cross-sectional study carried out at the Núcleo de Aptidão Física, Informática, Metabolismo, Esporte e Saúde (Nafimes, Center for Physical Fitness, Informatics, Metabolism, Sports, and Health) from 2014 to 2016. The sample was composed of 168 athletes of both genders, who competed in fifteen different sports (athletics, cycling, bodybuilding, soccer, American football, futsal, Brazilian jiu-jitsu, judo, karate, kung fu, mixed martial arts (MMA), swimming, taekwondo, triathlon and volleyball).

Athletes were contacted directly via phone calls or e-mail, and through indications from coaches or sporting federations. Convenience sampling was used, i.e., the participant athletes were selected based on availability and accessibility after contacting sports federations, clubs and coaches. Individuals who trained with competitive objectives, participated in regional and international events, or had a weekly training load equal to or greater than 6 hours were considered athletes (15). Athletes who did not respond to two 24-hour recalls (R24h) were excluded. All athletes (adults and under 18) and those responsible for athletes under the age of 18 years were informed of the study objectives and signed an informed consent form. Demographic (age and sex) and training (type of sport, volume, training phase) information was obtained through a questionnaire. This investigation was conducted according to the Declaration of Helsinki and was approved by the local University Ethics Committee (no. 488.198).

BODY COMPOSITION

Body mass was measured to the nearest 0.1 kg using a calibrated electronic scale, and height was measured using a stadiometer to the nearest 0.1 cm. The participants wore light clothing without shoes. Body mass index (BMI) was calculated as the body mass in kilograms divided by the square of the height in meters.

DIETARY INTAKE

Food intake was assessed by the 24-hour dietary recall method applied on two non-consecutive days of the week, with the aid of a photographic record taken during an interview (16). The homemade measurements of the nutritional values of foods and supplementations were converted into grams and milliliters by the online software Virtual Nutri Plus (Keeple®, Rio de Janeiro, Brazil). Some foods were not found in the program database and therefore items were added from food tables (17). Participants who used dietary supplements were instructed to report the brand and quantity consumed in order to ensure a higher accuracy of the macronutrient values present in each product. For the determination of food portions, the criterion of the Brazilian food pyramid was used (18). Foods are distributed in the food pyramid within eight groups, and each food group has a portion with a certain amount of calories. In this way, the foods consumed were quantified as total calories and later transformed into portions according to their characteristics. For supplements, the source of the nutrient with the highest prevalence in these was used to identify which group they belonged to, and to account for the caloric equivalent of their respective group.

AEROBIC AND ANAEROBIC PERFORMANCE

Anaerobic performance (maximum power) was obtained by using the Running Anaerobic Sprint Test (RAST), consisting of maximum sprints of 35 meters with 10 seconds of recovery between each sprint. The time recording was performed by photocells at each effort to determine the power generated at each run (HIDROFIT model PTL-BM 2 SK-D, software Multisprint full version 3.5.7, Brazil) (19). The RAST results provide an estimate of the neuromuscular and energetic determinants of maximal anaerobic performance (19).

Power produced in each sprint was calculated by the formula (19):

Power (watts) = (body mass x distance2)/time3

Maximum power (w.kg-1) = highest power produced in the six races.

The aerobic performance (VO2max) was obtained by means of the 20-m shuttlerun test consisting of one-minute continuous run steps, with increased velocity during the test. It is requested that the individual run in an area of 20 meters marked in two points, maintaining the pace of running with a sound signal that is emitted. The test stops when the participant fails and cannot pass by a 20-meter point before the beep occurs twice in a row (20).

The maximum volume of expired oxygen was estimated in mL.kg-1.min-1 using the equations proposed by Léger et al. (1988) (21), as described below:

– From 6 to 18 years: VO2max (mL.kg-1.min-1) = 31.025 + (3.238 x speed in km.h in the last completed stage) - (3.248 x age in years rounded down) + (0.1536 x speed in km.h-1 in the last stage completed x age in years rounded down).

– Over 18 years: VO2max (mL.kg-1.min-1) = -27.4 + (6.0 x speed in km.h in the last completed stage).

STATISTICAL ANALYSIS

The Kolmogorov-Smirnov test was used to verify data distribution. Descriptive statistics are presented as mean and standard deviation. Differences in general characteristics, eating habits, and average training time according to sex were determined using the Mann-Whitney U-test, and the Kruskal-Wallis test was performed to evaluate the other analyses. For all statistical analyses, significance was accepted at p < 0.05. The data were analyzed using the SPSS software, version 20.0 (SPSS, Inc., Chicago, IL, USA). Differences in general according to sex and modalities were determined using the Mann-Whitney U-test or Student’s t-test for independent samples. The values of maximum power and VO2max were separated into tertiles and compared using the Kruskal-Wallis test.

For verification of the crude relationship between consumption of food groups and personal and training characteristics (independent variables) and maximum power and VO2max (dependent variables) a linear regression (bivariate analyses) was performed. A multiple regression analysis was conducted to further test whether food groups (independent variables) were related to performance parameters (dependent variables), after adjusting for potential covariates such as hours of training, sex, BMI, and food intake (total calorie consumption/kg, g/kg of protein, g/kg of carbohydrates, and g/kg of lipids). For all statistical analyses significance was accepted at p < 0.05. The data were analyzed using the statistical package “R”, version 3.4.2 (New Zealand).

RESULTS

The main characteristics of the athletes are presented in table I. When compared to women, men showed higher values in the variables age (p = 0.000), weight (p = 0.000), height (p = 0.000), BMI (p = 0.000), training hours (p = 0.004), consumption (p = 0.000), maximum power (p = 0.000), and VO2max (p = 0.000). Table II presents the characteristics of the athletes according to sports modalities.

Table I. Descriptive characteristics of athletes by sex 

Values presented as mean ± standard deviation. BMI: body mass index; VO2max: maximum oxygen consumption.

Table II. Characteristics of participants of the study by modality 

Values presented as mean ± standard deviation.

*The mean value was not calculated because there was only one subject.

Table III shows the values for the portions of food consumed according to their respective food groups, and the contribution of nutritional supplements to the adequacy of the groups according to the recommendations proposed in the food pyramid. There was no significant difference between the “with supplements” and “without supplements” diets for all the food groups analyzed.

Table III. Consumption of food groups according to modality and contribution of dietary supplements 

*The mean was not calculated because there was only one subject. With supplement: column with the supplement consumption counted in the diet; Without supplement: column without supplement consumption counted in the diet; -: there was no supplement consumed.

When analyzing food intake by food groups regarding maximum power (Table IV), as was expected, t weight and height differed between groups (T1 < T2 < T3). Regarding hours of training and age, we noticed that participants in tertiles T2 and T3 presented higher scores when compared with T1. It can also be seen that the meats and eggs (T1 < T2 and T3) and legumes (T1 < T3) groups presented significant differences between their respective tertiles.

Table IV. Consumption of nutrients and portions of food groups according to tertiles of maximum power output for the athletes 

Values expressed as mean ± standard deviation. kg: kilograms; m: meters; kg/m2: kilograms divided by meters squared; g/kg/d: grams per kilogram of weight per day; w/kg: watts per kilogram of weight. Means followed by the same letter do not differ at the 5% level (p < 0.05) of significance by the Kruskal-Wallis test.

Table V shows the tertiles obtained for VO2max. Height differed between groups (T1 < T2 < T3). Regarding hours of training, we noticed that participants in tertiles T1 and T2 presented lower scores when compared with T3. It has also been observed that in calorie intake the participants of tertiles T2 and T3 presented higher scores when compared with T1. As regards protein intake, T2 differed from T1 and T3 (T1 = T3 < T2).

Table V. Consumption of food groups according to tertiles of VO2max for the athletes 

Values presented as mean ± standard deviation. m = meters; kg/m2: kilograms divided by meters squared; g/kg/d: grams per kilogram of weight per day; w/kg: watts per kilogram of weight. Means followed by the same letter do not differ from each other at the level of 5% (p < 0.05) of significance by the Kruskal-Wallis test.

Table VI shows the linear regression model between maximum power and food groups. Maximum power was significantly associated with consumption of foods in the meat and eggs groups in the last model, adjusted for other possible confounding variables (Model 06).

Table VI. Value of beta (β) and p-value for maximum power output (w/kg) according to the food groups 

Simple linear regression (Model 1); coefficient adjusted for training hours (Model 2); coefficient adjusted for training hours and sex (Model 3); coefficient adjusted for training hours, sex, and BMI (Model 4); coefficient adjusted for training hours, sex, BMI, and consumption of kcal/kg of weight (Model 5); coefficient adjusted for carbohydrates (g/kg/d), proteins (g/kg/d) and lipids (g/kg/d) (Model 6).

Table VII displays the linear regression model between aerobic performance and food groups. VO2max exhibited a positive relationship with the fruit group (β = 0.29; p < 0.05). These relationships remained significant after adjustment for the covariables hours of training, sex, and BMI (β = 0.19; p < 0.05). A significant inverse relation between VO2max and the legumes group was observed after adjusting for hours of training, gender, BMI, and consumption of kcal/kg of body weight (β = -0.76; p < 0.05). The group of meats and eggs and the group of dairy products had an inverse and significant association with VO2max after adjusting for hours of training, gender, BMI, consumption of kcal/kg of body weight, carbohydrate intake (g/kg/d), protein intake (g/kg/d), and lipid intake (g/kg/d) (β = -0.76, p < 0.05; β = -0.44, p < 0.05; and β = -0.43, p < 0.01, respectively).

Table VII. Value of beta (β) and p-value for VO2max (w/kg) according to the food roups 

Simple linear regression (Model 1); coefficient adjusted for training hours (Model 2); coefficient adjusted for training hours and sex (Model 3); coefficient adjusted for training hours, sex, and BMI (Model 4); coefficient adjusted for training hours, sex, BMI, and consumption of kcal/kg of weight (Model 5); coefficient adjusted for carbohydrates (g/kg/d), proteins (g/kg/d) and lipids (g/kg/d) (Model 6).

DISCUSSION

According to the findings of the present investigation, the highest consumption of meat, eggs and legumes was observed in the upper tertiles of potency, and fruits were ingested in greater quantity in the higher tertiles of VO2max. After adjusting for confounding factors, meat and egg consumption was positively associated with anaerobic performance, whereas the same group and dairy products were negatively associated with aerobic performance.

To the authors’ knowledge, to date, this is the first study to investigate the association between dietary intake and physical performance in a population of athletes. The novelty of the study precludes a direct comparison with the literature. Overall, a proper diet is a key factor for adaptation and improved physical performance.

Meats are the best food sources of proteins with high biological value (22,23), are a good source of micronutrients such as zinc, iron, and vitamin B(24), and have better bioavailability when compared to plant sources of these nutrients (25). In addition, albumin has a high biological value, and contains amino acids that aid in the synthesis of creatine (26) and in pH control, favoring greater resistance to fatigue (27-29) and possibly the best anaerobic performance observed in our study.

In aerobic performance the consumption of meat, eggs and dairy products was inversely associated with VO2max after adjustment for different confounding factors. Moreover, the athletes in the present study consumed carbohydrates in amounts inferior to the national recommendations for athletes (1), and cereal portions in the lower limit proposed in the Brazilian food pyramid (18). This dietary profile is similar to that observed in an earlier study by our study group in another cohort of athletes (30), who consumed protein-rich diets neglecting carbohydrate intake and total calories. This possibly affected the aerobic performance of the athletes in our study, justifying the negative association obtained for the food groups of meat and eggs and dairy products, whose main nutrient is protein.

In the group of milk and dairy products 11 modalities were below the proposed recommendation (athletics, cycling, futsal, soccer, Brazilian jiu-jitsu, judo, karate, kung fu, MMA, swimming, and volleyball) and 4 modalities were above (bodybuilding, American football, taekwondo, and triathlon). The values corresponding to the group of sugars and sweets were: 2 modalities as recommended (American football, kung fu) and 13 above recommendations (athletics, cycling, bodybuilding, soccer, futsal, Brazilian jiu-jitsu, judo, karate, MMA, swimming, taekwondo, triathlon, and volleyball).

Regarding oils 03 modalities were below recommendations (athletics, MMA, and taekwondo), 07 were within recommendations (bodybuilding, soccer, Brazilian jiu-jitsu, judo, swimming, triathlon, and volleyball) and 05 were above the recommended values (cycling, soccer, futsal, karate, kung fu). When supplements were removed from the calculation of portions, the only food group that obtained a change in the classification as related to the food pyramid was that of dairy products, where the modality of bodybuilding entered the classification below recommended values.

The consumption of legumes was negatively associated with VO2max in the Model 5 of adjustment. This inverse association was a significant one and could be based on the assumption that legumes have an antinutritional factor called phytic acid. Phytic acid may be related to reduced bioavailability and absorption of some micronutrients (31), especially calcium and zinc (32). Calcium is closely related to energy metabolism and muscle contraction (33), while zinc is required for the activity of more than 300 enzymes and, if consumed in low amounts, can alter the individual’s eating behavior and compromise aerobic fitness (34).

In addition, legumes are important sources of protein in the diet of vegetarians (35). In the present study the foods that mostly represented the legume group were beans.

After adjustment for macronutrients (carbohydrates, proteins, lipids), the association between legumes and VO2max lost its significance, indicating the possibility that it is the macronutrients and not the legumes themselves that are responsible for the associations observed in our study.

On the other hand, the legumes group was significantly more consumed in the tertile of better anaerobic performance (T3) when compared to the tertile of low anaerobic performance (T1). This difference can be explained by the fact that legumes are considered a good source of protein (35) and this nutrient in turn is associated with anaerobic performance (36 37-38).

According to the Brazilian food pyramid, the T1 group (low performance) and the T3 group (high performance) presented the same classification of consumption for most of the food groups but with values of different consumed portions, suggesting that small changes in the diet can make a difference between athletes with a low performance and athletes with a high performance. In our study, supplements did not alter the adequacy of dietary intake, partially corroborating a study with Brazilian athletes (30).

For fruits, T1 was the only tertile where consumption was as recommended in the food pyramid; the other tertiles (T2 and T3) were above recommendations. Vegetables and dairy products were in all tertiles below recommendations. Regarding the groups of meats and eggs, legumes, and sugars all tertiles were above the issued recommendations.

Men consumed cereals in appropriate portions and fruit above the food pyramid’s recommendations. Among female athletes, cereal intake was low and fruit intake was within the recommended range. Oils and fats were consumed in adequate amounts by both sexes

In general, the cereal and oil groups were within the recommendations (05 to 09 servings and 01 to 02 servings, respectively), while the fruit, meat, legume, and sugar groups were above the recommendations of the food pyramid as adapted to the Brazilian population (03 to 05 servings, 01 to 02 servings, 01 serving, and 01 to 02 servings, respectively). The vegetable and dairy groups (recommendation of 04 to 05 servings, and of 03 servings, respectively) were below the recommended values.

Of the 15 assessed modalities, 5 showed cereal consumption below the recommended amounts (athletics, cycling, futsal, Brazilian jiu-jitsu, and taekwondo), 8 were in accordance with the issued recommendations (soccer, American football, judo, karate, kung fu, swimming, and triathlon) and 2 were above the recommended values (bodybuilding and MMA). Regarding the consumption of fruits, 4 modalities presented consumption below the recommendations (athletics, bodybuilding, MMA, and taekwondo), 3 were within the recommended amounts (futsal, karate, and volleyball) and 8 were above the recommended values (cycling, soccer, American football, Brazilian jiu-jitsu, judo, kung fu, swimming, and triathlon). All modalities reported an intake of vegetables below the available recommendations. The meat group had only one modality within the recommendation (cycling) whereas the other modalities were above the recommended values. Seven modalities consumed legumes below the recommended amount (cycling, bodybuilding, American football, futsal, judo, MMA, and triathlon) and 8 consumed them above recommendations (athletics, soccer, Brazilian jiu-jitsu, karate, kung fu, taekwondo, swimming, and volleyball).

The present study does have limitations that should be acknowledged. This study used a cross-sectional design, which does not allow the establishment of cause-and-effect relationships. Our sample was comprised of predominantly male athletes, thus limiting the generalization of these results to women. Other limitation of this study was that we were unable to obtain a homogeneous distribution of athletes within each modality, so as to more accurately investigate the influence of this variable on eating habits. Despite these limitations, a strong point of our study is its sample size (168 athletes) and the adjustments for potential confounders in the association between intake of food groups and performance parameters. It should be noted that performances were separated into “aerobic” and “anaerobic” classes for didactic purposes, since both occur intermittently during exertion, albeit with predominance of one over the other.

The fact that this study is the only one to relate the various food groups to the physical performance of athletes denotes that there is still much to research. Future investigations considering sport modalities and modality-specific tests to measure aerobic and anaerobic fitness may help in the construction of this body of knowledge.

Through the information gathered in this study, nutritionists will have greater support when advising on the choice and quantity to be consumed for each food group, knowing the potential of each one of them. For example, the prescription of meat and eggs consumption may exert a positive or negative effect on physical performance depending on the sport practised by a given athlete. It is important to note that even with the controversial results regarding the performance of athletes with different dietary macronutrient profiles, it is important to have a balanced and cautious diet. Given the low bioavailability of certain nutrients found in plant sources, extra attention should be payed to the food and even the supplementation that is recommended for athletes whose diet is based on plant sources.

CONCLUSION

The consumption of meat and eggs showed a positive association with anaerobic performance, whereas the same group and dairy products had a negative association with aerobic performance. This type of result suggests that the same alimentary profile that assists a certain skill may harm another, so special attention on the part of the professionals involved is required when drafting a dietary plan. The consumption of the various food groups was shown to be one of the possible factors involved in an athlete’s physical performance. In addition, our study researched a scarcely explored subject, thus highlighting the need for further research in this field.

REFERENCES

1. Sociedade Brasileira de Medicina do Esporte. Modificações dietéticas, reposição hídrica, suplementos alimentares e drogas: comprovação de ação ergogênica e potenciais riscos para a saúde. Revista Brasileira de Medicina do Esporte 2009. [ Links ]

2. Papadopoulou SK, Gouvianaki A, Grammatikopoulou MG, Maraki Z, Pagkalos IG, Malliaropoulos N, et al. Body Composition and Dietary Intake of Elite Cross-country Skiers Members of the Greek National Team. Asian J Sports Med 2012;3(4):257-66. DOI:10.5812/asjsm.34548. [ Links ]

3. Rodriguez NR, DiMarco NM, Langley S. Position of the American Dietetic Association, Dietitians of Canada, and the American College of Sports Medicine: Nutrition and athletic performance. J Am Diet Assoc 2009;109(3):509-27. DOI:10.1016/j.jada.2009.01.005. [ Links ]

4. Roy BD. Milk: the new sports drink? A Review. J Int Soc Sports Nutr 2008;5:15. DOI:10.1186/1550-2783-5-15. [ Links ]

5. Filha EO, Araújo JS, Barbosa JS, Gaujac DP, Santos CFS, Silva DG. Consumo dos grupos alimentares em crianças usuárias da rede pública de saúde do município de Aracaju, Sergipe. Revista Paulista de Pediatria 2012;30:529-36. DOI:10.1590/S0103-05822012000400011. [ Links ]

6. Farajian P, Kavouras SA, Yannakoulia M, Sidossis LS. Dietary intake and nutritional practices of elite Greek aquatic athletes. Int J Sport Nutr Exerc Metab 2004;14(5):574-85. DOI:10.1123/ijsnem.14.5.574. [ Links ]

7. Lukaski HC. Vitamin and mineral status: effects on physical performance. Nutrition 2004;20(7-8):632-44. DOI:10.1016/j.nut.2004.04.001. [ Links ]

8. Hargreaves M, Hawley JA, Jeukendrup A. Pre-exercise carbohydrate and fat ingestion: effects on metabolism and performance. J Sports Sci 2004;22(1):31-8. DOI:10.1080/0264041031000140536. [ Links ]

9. Ivy JL, Res PT, Sprague RC, Widzer MO. Effect of a carbohydrate-protein supplement on endurance performance during exercise of varying intensity. Int J Sport Nutr Exerc Metab 2003;13(3):382-95. DOI:10.1123/ijsnem.13.3.382. [ Links ]

10. Lima-Silva AE, Pires FO, Bertuzzi R, Silva-Cavalcante MD, Oliveira RS, Kiss MA, et al. Effects of a low- or a high-carbohydrate diet on performance, energy system contribution, and metabolic responses during supramaximal exercise. Appl Physiol Nutr Metab 2013;38(9):928-34. DOI:10.1139/apnm-2012-0467. [ Links ]

11. Radavelli-Bagatini S, Zhu K, Lewis JR, Dhaliwal SS, Prince RL. Association of dairy intake with body composition and physical function in older community-dwelling women. J Acad Nutr Diet 2013;113(12):1669-74. DOI:10.1016/j.jand.2013.05.019. [ Links ]

12. Neville CE, McKinley MC, Murray LJ, Boreham CA, Woodside JV. Fruit and vegetable consumption and muscle strength and power during adolescence:a cross-sectional analysis of the Northern Ireland Young Hearts Project 1999-2001. J Musculoskelet Neuronal Interact 2014;14(3):367-76. [ Links ]

13. Gracia-Marco L, Bel-Serrat S, Cuenca-García M, González-Gross M, Pedrero-Chamizo R, Manios Y, et al. Amino acids intake and physical fitness among adolescents. Amino acids 2017;49(6):1041-52. DOI:10.1007/s00726-017-2393-6. [ Links ]

14. Qureshi MM, Singer MR, Moore LL. A cross-sectional study of food group intake and C-reactive protein among children. Nutrition & metabolism 2009;6:40. DOI:10.1186/1743-7075-6-40. [ Links ]

15. Araujo CG, Scharhag J. Athlete:a working definition for medical and health sciences research. Scand J Med Sci Sports 2017;26(1):4-7. [ Links ]

16. Monego ET, Peixoto MRG, Santiago RAC, Gil M, Cordeiro MM, Campos MI, et al. Alimentos Brasileiros e Suas Porções: Um Guia para Avaliação do Consumo Alimentar Rio de Janeiro: Rúbio;2013. [ Links ]

17. Pinheiro ABV, Lacerda EMA, Benzecry EH, Gomes MCS, da Costa VM. Tabela para Avaliação de Consumo Alimentar em Medidas Caseiras: Atheneu;2009. [ Links ]

18. Phillipi ST, Latterza AR, Cruz ATR, Ribeiro LC. Pirâmide Alimentar Adaptada: Guia para escolha dos alimentos. Revista de Nutrição 1999;12(1):65-80. DOI:10.1590/S1415-52731999000100006. [ Links ]

19. Zagatto AM, Beck WR, Gobatto CA. Validity of the running anaerobic sprint test for assessing anaerobic power and predicting short-distance performances. J Strength Cond Res 2009;23(6):1820-7. DOI:10.1519/JSC.0b013e3181b3df32. [ Links ]

20. Mayorga-Vega D, Aguilar-Soto P, Viciana J. Criterion-Related Validity of the 20-M Shuttle Run Test for Estimating Cardiorespiratory Fitness: A Meta-Analysis. J Sports Sci Med 2015;14(3):536-47. [ Links ]

21. Leger LA, Mercier D, Gadoury C, Lambert J. The multistage 20 metre shuttle run test for aerobic fitness. J Sports Sci 1988;6(2):93-101. DOI:10.1080/02640418808729800. [ Links ]

22. Koeth RA, Wang Z, Levison BS, Buffa JA, Org E, Sheehy BT, et al. Intestinal microbiota metabolism of L-carnitine, a nutrient in red meat, promotes atherosclerosis. Nature medicine 2013;19(5):576-85. DOI:10.1038/nm.3145. [ Links ]

23. Pekala J, Patkowska-Sokola B, Bodkowski R, Jamroz D, Nowakowski P, Lochynski S, et al. L-carnitine--metabolic functions and meaning in humans life. Curr Drug Metab 2011;12(7):667-78. DOI:10.2174/138920011796504536. [ Links ]

24. Sharma S, Sheehy T, Kolonel LN. Contribution of meat to vitamin B(1)(2), iron and zinc intakes in five ethnic groups in the USA: implications for developing food-based dietary guidelines. J Hum Nutr Diet 2013;26(2):156-68. DOI:10.1111/jhn.12035. [ Links ]

25. Allen LH. To what extent can food-based approaches improve micronutrient status? Asia Pac J Clin Nutr 2008;17( Suppl 1):103-5. [ Links ]

26. Cooper R, Naclerio F, Allgrove J, Jimenez A. Creatine supplementation with specific view to exercise/sports performance: an update. Journal of the International Society of Sports Nutrition 2012;9(1):33. DOI:10.1186/1550-2783-9-33. [ Links ]

27. Baguet A, Bourgois J, Vanhee L, Achten E, Derave W. Important role of muscle carnosine in rowing performance. J Appl Physiol 1985;109(4):1096-101. DOI:10.1152/japplphysiol.00141.2010. [ Links ]

28. Parkhouse WS, McKenzie DC. Possible contribution of skeletal muscle buffers to enhanced anaerobic performance: a brief review. Med Sci Sports Exerc 1984;16(4):328-38. [ Links ]

29. Varanoske AN, Hoffman JR, Church DD, Wang R, Baker KM, Dodd SJ, et al. Influence of Skeletal Muscle Carnosine Content on Fatigue during Repeated Resistance Exercise in Recreationally Active Women. Nutrients 2017;9(9):988. DOI:10.3390/nu9090988. [ Links ]

30. Rodrigues VB, Ravagnani CDFC, Nabuco HCG, Ravagnani FCDP, Fernandes VLS, Espinosa MM. Adequacy of energy and macronutrient intake of food supplements for athletes. Revista de Nutrição 2017;30:593-603. DOI:10.1590/1678-98652017000500005. [ Links ]

31. Silva MR, Silva MAAP. Aspectos nutricionais de fitatos e taninos. Revista de Nutrição 1999;12:21-32. DOI:10.1590/S1415-52731999000100002. [ Links ]

32. Gupta RK, Gangoliya SS, Singh NK. Reduction of phytic acid and enhancement of bioavailable micronutrients in food grains. J Food Sci Technol 2015;52(2):676-84. DOI:10.1007/s13197-013-0978-y. [ Links ]

33. Williams MH. Dietary Supplements and Sports Performance: Minerals. Journal of the International Society of Sports Nutrition 2005;2(1):43. DOI:10.1186/1550-2783-2-1-43. [ Links ]

34. Micheletti A, Rossi R, Rufini S. Zinc status in athletes: relation to diet and exercise. Sports Med 2001;31(8):577-82. DOI:10.2165/00007256-200131080-00002. [ Links ]

35. Polak R, Phillips EM, Campbell A. Legumes: Health Benefits and Culinary Approaches to Increase Intake. Clinical diabetes: a publication of the American Diabetes Association 2015;33(4):198-205. DOI:10.2337/diaclin.33.4.198. [ Links ]

36. Artioli GG, Bertuzzi RC, Roschel H, Mendes SH, Lancha AH Jr, Franchini E. Determining the contribution of the energy systems during exercise. Journal of visualized experiments 2012;(61):3413. DOI:10.3791/3413. [ Links ]

37. Laskowski R, Antosiewicz J. Increased adaptability of young judo sportsmen after protein supplementation. J Sports Med Phys Fitness 2003;43(3):342-6. [ Links ]

38. Wilborn CD, Taylor LW, Outlaw J, Williams L, Campbell B, Foster CA, et al. The Effects of Pre- and Post-Exercise Whey vs. Casein Protein Consumption on Body Composition and Performance Measures in Collegiate Female Athletes. J Sports Sci Med 2013;12(1):74-9. [ Links ]

Gomes LF, Nabuco HCG, Faria SIG, Godois AM, Fernandes VLS, Ravagnani FCP, Ravagnani CFC. Consumption of meat, eggs and dairy products is associated with aerobic and anaerobic performance in Brazilian athletes – A cross-sectional study. Nutr Hosp 2019;36(6):1375-1383.

Received: May 31, 2019; Accepted: September 27, 2019

Correspondence: Hellen Clair Garcez Nabuco. Antônio Cesário de Figueiredo, 460. 78032-143 Cuiabá, Mato Grosso, Brazil e-mail: hellen.nabuco@cba.ifmt.edu.br

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