2015
The effect of glycemic index on plasma il-6 in sub-max exercise
Hasani S.H.1, Supapom S. 1, Mehranpour A.B. 1, Witid M. 2
1 Physical Education & Sport science Department, Islamic Azad University, mahallat, Iran, 2Faculty of Physical Education & Sport science, Srinakharinwirot University, Bangkok, Thailand
Abstract:
Purpose: This study examined the effect of a pre-exercise meal with different glycemic index (GI) on plasma IL-6 concentration and glucose metabolism during sub-max exercise (endurance performance run). Material: Ten men completed 1 h running at 70%-75% VO2max on a level treadmill on three occasions. In each trial, one of the three prescribed beverages as meal, i.e. high GI and low GL or placebo was consumed by the subjects 45 min before exercise. Blood samples were collected before, after, 1h and 24h after exercise. Result: Concentration of Plasma IL-6 in LGI group was less than HGI and Pla groups, IL-6 tended to significantly increase after exercise in groups (all P < 0.05), also there was significant difference for plasma IL-6 concentration between placebo and low glycemic groups in after exercise (P=.003) and Ihour after exercise (P=.005) . CK was significantly elevated at all- time points after exercise in 3 groups (all P < 0.05). Concentration of serum CK in LGI group was less than HGI and Pla groups but there not significantly. The consumption of the LGI beverage before exercise could minimize the increasing of plasma IL-6 concentration immediately after exercise and during the 1 h recovery period compared with the HGI beverage and Pla. Conclusion: This result suggested that the LGI beverage consumed as pre-exercise meal could modify the inflammatory response in prolonged exercise.
Keywords: Sub-max, exercise, glycemic, index, plasma.
Хасани С., Супапорн С., Мехранпоур А.Б., Витид М. Влияние гликемического индекса на плазму ^-6 в субмаксимальных упражнениях. Цель: исследование влияния предварительных упражнений и пищи с различным гликемическим индексом (ГИ) на плазму ^-6 концентрации и метаболизма глюкозы во время выполнения субмаксимальных упражнений (в длительном беге). Материал: 10 мужчин выполняли в течение 1 часа упражнения на беговой дорожке на уровне 70% -75% У02тах в трех тестах. В каждом тесте один из трех мужчин употреблял предлагаемые напитки с высоким ГИ и низким ГИ или плацебо за 45 мин до тренировки. Образцы крови собирали до и после 1 часа и через 24 часа после тренировки. Результат: Концентрация в плазме ^-6 в группе с низким ГИ было меньше, чем в группе с высоким ГИ и группе с приемом плацебо. ^-6, как правило, значительно увеличивается после тренировки в группах (все р<0,05). Также было отмечено значительное различие концентрации в плазме ^-6 между плацебо в группе с низким ГИ после тренировки (Р = 0,003) и через 1 час после тренировки (р = 0,005). Креатинкиназа был значительно повышен во всех временных точках после тренировки в 3 группах (все р <0,05). Концентрация сывороточного креатинкиназа в группе с низким ГИ была меньше, чем с высоким ГИ и группе с приемом плацебо, но имела несущественные отличия. Употребление напитка с низким ГИ перед тренировкой может свести к минимуму увеличение в плазме концентрации ^-6 сразу после тренировки и в течение 1 часа восстановительного периода по сравнению с напитком высоким ГИ и группе с приемом плацебо. Выводы: полученные результаты позволяют предположить, что напитки с низким ГИ, принимаемые перед выполнением упражнений, могут модифицировать воспалительную реакцию в длительных упражнениях.
субмаксимальный, упражнения, гликеми-ческий, индекс, плазма.
Хасат С., Супапорн С., Мехранпоур А.Б., Втд М. Вплив глiкемiчного шдексу на плазму 1Ь-6 в субмакси-мальних вправах. Мета: дослщження впливу попереджх вправ i Тж з рiзним глiкемiчним Ыдексом (Г1) на плазму ^-6 концентрацп i метаболiзму глюкози пщ час виконання субмаксимальних вправ (в тривалому б^). Матерал: 10 чоло-вшв виконували протягом 1 години впра-ви на бтовм дорiжцi на рiвнi 70% -75% У02тах в трьох тестах. В кожному тест один з трьох чоловшв вживав пропоно-важ напоТ з високим Г1 i низьким Г1 або плацебо за 45 хвилин до тренування. Зразки кровi збирали до i пюля 1 години i через 24 години пюля тренування. Ре-зультати: Концентра^я в плазмi ^-6 у груп з низьким Г1 була менше, жж у груп з високим Г1 i груп з прийняттям плацебо. ^-6, як правило, значно збтьшуеть-ся пюля тренування в групах (вс р<0,05). Також було вщзначено значне розхо-дження концентрацп в плазмi ^-6 мiж плацебо в груп з низьким Г1 пюля тренування (Р = 0,003) i через 1 годину пюля тренування (р = 0,005). Креатинкиназа був значно пщвищений у вах тимчасо-вих точках пюля тренування в 3 групах (вс р <0,05). Концентрация сироватко-вого креатинкиназа в груп з низьким Г1 була меншою, жж з високим Г1 i груп з прийняттям плацебо, але мала несуттeвi вщмЫностк Вживання напою з низьким Г1 перед тренуванням може звести до мь жмуму збтьшення в плазмi концентрацп ^-6 вщразу пюля тренування i протягом 1 години виновного перюду в порiвняннi з напоем високим Г1 i груп з прийняттям плацебо. Висновки: отримаж результа-ти дозволяють припустити, що напоТ з низьким Г1, прийнятi перед виконанням вправ, можуть модифкувати запальну реак^ю в тривалих вправах.
субмаксимальний, вправи, глiкемiчний, iндекс, плазма.
Introduction
Exercise can induce inflammation by raising the levels of IL-6 (Nieman et al., 2006). Intensity, duration, and the muscle mass involved in the exercise are factors known to influence the quantity of IL-6 found in plasma (Ostrowski et al., 2000). Carbohydrate(CHO) consumption before, during and after exercise can attenuate stress hormone response and improves exercise performance by enhancing blood glucose availability (Bishop et al., 2002; Febbraio et al., 2003; Nieman et al., 2003). Otherwise, CHO feeding before exercise cause a rapid increase in blood glucose and insulin can cause hypoglycemia in some individuals at the start of exercise (Foster et al., 1979; Kuipers et al., 1999).
This observation led to the investigation into the effect of different types and structures of CHO and their comparison on exercise performance (Guezennec et al., 1989, 1993; Koivisto et al., 1981). Numerous
© Hasani S.H., Supaporn S., Mehranpour A.B., Witid M., 2015 http://dx.doi.org/10.15561/18189172.2015.0509
studies have suggested that a low glycemic (LGI) meal consumed at different times, to prolonged exercise could maintain higher blood glucose concentrations, decrease plasma lactate concentrations during exercise and/or post-exercise, (Wee et al., 1999; DeMarco et al., 1999). Furthermore in prolonged exercise minimizing the glycemic and insulin response could sustain CHO supply during exercise. These responses could decrease the cortisol response, IL-6, TNF-a and other inflammatory biomarkers (Bishop et al., 2001), also there is some evidences that a diet whit high amount of glucose could increase pro-inflammatory cytokine (Kirwan et al., 2001). High glycemic (HGI) diet is the exacerbation of glucose spike that occurs immediately after eating (Pittas et al., 2006), this spike could alter glucose and insulin dynamics during exercise.
These data suggest that consuming food with different glycemic index could be effect on inflammatory responses in exercise. Despite the recent advances in researches are on the relation between immune suppression and CHO supplementation during prolong exercise or CHO as meal
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before exercise. Therefore, knowing about that which type of CHO be able to reduce inflammatory responses in exercise, could guide the athletes for choosing beneficial nutrition to improve their performance. More research is necessary to elucidate the relationship between systemic inflammation and GI diets in prolong exercise. Few studies, if any, have directly investigated the influence of a GI beverage on IL-6 response to prolonged exercise. There is clearly a pressing need to clarify the role of GI on IL-6 responses before prolonged exercise. Using an identical design and subject population, this study aimed to examine the effect of a pre-exercise beverage with different GI on IL-6 responses to a sub-max exercise. The aim of this study was determine whether there are differences in plasma IL-6 concentration and glucose metabolism between low and high GI beverage in sub-max exercise.
Materials and Methods
Subjects
Ten healthy endurance male runners (age 21±2 years; body mass 68±8 kg; high 176±6 cm; fat percentage (%)10±2; VO2max 56±21ml/kg per min and training experience 5±1years) were volunteered to participate in this study which was approved by the Ethical Committee of Qom University of medical science. Written informed consent was obtained from all subjects. They were also required to complete a general health questionnaire and were excluded if any medication had been taken during the 6 weeks prior to the study and if symptoms of upper respiratory infection had been experienced in the 4 weeks training and were accumulating at least 50 km of running distance per week. Subjects were asked to refrain from alcohol consumption 24 hours prior to sample collection.
Exercise familiarization
At least 1 week prior to main trial all subjects reported to the laboratory for becoming familiar with treadmill running and the experimental procedures, they were required to undertake vo2 max test via Bruce protocol. Before the main trials, participant kept a 3-day diary of their dietary intake before the main trial and energy intake and dietary composition were subsequently analyzed (The Food Processor 10.0, Esha).They were required to repeat the same diet before each main trial to minimize the variation in muscle and liver glycogen concentrations.
Experimental procedure
A standardized prolong exercise protocol, 1 h constant running at 70% -75% VO2max was used in this study (Fig. 1). This study is a counterbalanced cross-over design and the order of three trials were randomized, separated by at least14 days. Subjects were randomized to consume GI beverage High-GI (1 g of glucose/kg body mass in 400 ml water, GI = 83), Low-GI (1 g of fructose/kg body mass in 400 ml water, GI = 36) or placebo (an equal volume of flavor- and color-matched artificially sweetened placebo) (Gleeson et al., 1986) for 45 min pre-exercise .Blood samples (10 mL) were collected at baseline, before and immediately after exercise, 1 and 24 h after exercise.
On the day of the main trial, subjects reported to the laboratory at about 8:00 am after an overnight fast of
12 h. After collection of the baseline blood samples the participants were consumed either the GI beverage (High-GI, Low-GI) or placebo. They remained seated in a quiet section of the laboratory for 45 min with minimal level of activity and after 45 min resting period, they were started training: standardized 5 min warm-up at 60% VO2 max was performed. Then subjects were run on the treadmill at a fixed speed of 70% -75%VO2 max for 1 h. All of the trials were performed under similar conditions of barometric pressure, temperature, and relative humidity. No food was been allowed until after the final blood sample were be taken.
Blood sampling:
10 ml venous blood was drawn from an antecubital vein in the forearm at each time point : 1- Fast blood sample (F.B.S),2 - Pre-exercise (PRE-ex), 3-Immediately post-exercise (POST) 4- 1 h after exercise (POST-60 min) 5- 24 hour after exercise, into two different evacuated collection tubes (Vacutainer; Becton Dickinson, Mountain View, CA). The first (5 ml) venous blood sample was drawn into a vacuum tube with clot activator and serum separator for collection of serum to analyze glucose by BIOSEN C (EKF Diagnostic GmbH, West Germany) and CK by SYNCHRON® System(s) (Beckman Coulter, Inc. USA). The second (5 ml) venous blood sample was taken in to K3 EDTA vacutainers .5ml blood sample was spun at 1500 g for 10 min at 4°C to obtain plasma which was immediately stored at -70 °C before being analyzed for IL-6 . IL-6 was determined with the use of quantitative sandwich type enzyme-linked immunosorbant assay (ELISA) kits from R&D systems (Minneapolis, MN). All standards and solutions were prepared, and procedures were followed according to the kit specifications. Samples were diluted when necessary to ensure that the measurement fell within the range of the standard curve.
Data analysis
All collected data will be presented as mean and standard deviation (Mean ± SD). Repeated measures 5 x 3 (time x groups) ANOVAs was used to assess metabolic and immune differences between groups. Any significant F ratios shown were assessed using Bonferroni correction test. Assumptions of homogeneity and sphericity in the data were checked. Statistical significance was accepted at p < 0.05. The data was analyzed by using the statistical package SPSS, PC program, version 19.0 (SPSS Inc., USA).
Results:
10 Subjects completed 3 sessions of endurance exercise (Table 1) running at a fixed speed of 70% -75%VO2 max for 1 h on the treadmill.
Table1
Individual characteristic: N = 10.Values = mean ± SD.
VO2max = predicted maximal oxygen consumption.
Characteristics M± SD
Age (yrs) 21±2
Height (cm) 176±6
Body mass (kg) 68±8
Fat percentage (%) 10±2
VO2max (ml.kgr'.min-1) 56±2
Training experience (yrs) 5±1
s
2015
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Markers of inflammation
Plasma IL-6 concentration and CK were measured as indicators of inflammation as a result of muscle damage. At the baseline, there was no significant difference for IL-6 between trials. Concentration of Plasma IL-6 in LGI group was less than HGI and Pla groups, IL-6 tended to significantly increase after exercise in 3 groups (all P < 0.05), also there was significant difference for plasma IL-6 concentration between placebo and low glycemic groups in after exercise (P=.003) and 1hour after exercise (P=.005) The IL-6 data are presented in figure (Fig.1). For CK at the baseline, there was no significant difference between trials. Concentration of serum CK in LGI group was less than HGI and Pla groups. CK was significantly elevated above baseline values at all- time points after exercise in 3 groups (all P < 0.05), but there was no significant difference for CK between 3 groups (Fig.2).
Blood glucose
At the baseline, there was no significant difference for glucose between trials. Concentration of glucose in HGI group was more than LGI and Pla groups,the serum concentration of glucose increased significantly above baseline values at before exercise and decrease significantly after exercise in LGI and HGI groups (all P < 0.05) . Furthermore there was significant difference for glucose between placebo with low glycemic groups (P=0.00) and placebo with high glycemic in before exercise (P=0.00), also placebo with low glycemic groups (P=0.00) and placebo with high glycemic in after exercise (P = 0.01) (Fig.3).
Discussion
To our knowledge, this may be the first study that directly determined the role of GI as beverage on immune
responses during endurance exercise. The major finding of the present study revealed that the consumption of a LGI beverage, before endurance exercise decreased the elevation of plasma IL-6 concentrations immediately after exercise and during the 1 h recovery period compared with the HGI and Pla groups. These responses were accompanied by an attenuated increase in serum CK concentrations in LGI group compared with the HGI and Pla groups at the end of the 1 h recovery period.
It has been reported that the noticeable increase in circulating IL-6 concentrations are related to exercise intensity, duration, mass of muscle involved, and endurance capacity (Bishop et al., 2001; Matthys et al., 1995). In the present study, IL-6 increased immediately after exercise significantly. Recent studies demonstrate that IL-6 is produced by skeletal muscles contraction during exercise and this release also related to contraction and low muscle glycogen (Bishop et al., 1999). On the other hand most studies of CHO intervention have used continuous prolonged exercise of fixed intensity (%VO2max) and duration and CHO ingestion in this situation is effective in minimizing perturbations in circulating stress hormones and immune responses ( Bishop et al.,2001; Li et al.,2004). CHO ingestion attenuated elevations in plasma IL-6 during both running and cycling mainly because of its effect at the post-transcriptional level of IL-6 (Nieman et al., 1998; Pedersen et al., 2008; Nehlsen et al., 1997), whereas low muscle glycogen concentrations further enhanced IL-6mRNA and the transcription rate for IL-6 (Steensberg et al., 2003). Therefore, muscle glycogen content appears to be an important stimulus for IL-6 which acts as an energy sensor. However, in our finding IL-6 in LGI group was significantly less than HGI and Pla
Fig. 1 Mean concentration of plasma IL-6 for Pla, LGI and HGI diet groups at the various time points. Significant differences between Pla and LGI (treatment effect) are indicated with (**) where P <0.05; where P < 0.05; Significant differences from baseline (time effect) are denoted by (*) where P < 0.05. Solid black bar represents resistance exercise bout; Pla = placebo, LGI = Low glycemic index, HGI = High glycemic index. Values are mean ± SE.
IПЕДАГОГ1КА I та медико_б'олог'чн'
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виховання i спорту _
ПСИХОЛОГ1Я
Fig. 2. Mean concentration of serum CK for Pla, LGI and HGI diet groups at the various time points. Significant differences from baseline (time effect) are denoted by (*) where P < 0.05. Values are mean ± SE. Pla placebo, LGI = Low glycemic index, HGI = High glycemic index.
Fig. 3. Mean concentration of serum glucose for Pla, LGI and HGI diet groups at the various time points. Significant differences between Pla and LGI (treatment effect) are indicated with (**)where P <0.05; Significant differences between Pla and HGI (treatment effect) are indicated with (X) where P < 0.05 Significant differences from baseline (time effect) are denoted by (*) where P < 0.05. Solid black bar represents resistance exercise bout; Pla = placebo, LGI = Low glycemic index, HGI = High glycemic index. Values are mean ± SE.
32015
n
groups. In endurance exercise minimizing the glycemic response could sustain CHO supply during exercise, that cause to decrease the cortisol response, IL-6 and other inflammatory biomarkers (Bishop et al., 2001), however a HGI diet could increase pro-inflammatory cytokine (Kirwan et al., 2001). HGI diet is the exacerbation of glucose spike that occurs immediately after eating this spike could alter glucose and insulin dynamics during exercise (Pittas et al., 2006), which was in agreement with the findings in our present study.
Creatine kinasis (CK) is an enzyme normally found only in skeletal muscle that used as an indirect marker of muscle damage in the present study. CK was measured during the time in three conditions and increasing observed over the time. Concentration of serum CK in LGI group was less than HGI and Pla groups but there were no significant changes in CK between conditions. The phenomena of peak CK at 48 hours post-exercise as seen in the LGI group is also not uncommon (Malm et al. 2004). This difference could be a result of a gradually increase in insulin following consumption of a LGI diet
versus the HGI diet before exercise. Insulin is a powerful promoter of protein synthesis (Cockburn et al., 2010). On the other hand CK can be elevated for several days in individuals (Miles et al., 2010) because of this our protocol couldn't have significant effect on CK concentration.
Conclusion
The consumption of the LGI beverage before exercise could minimize the increasing of plasma IL-6 concentration immediately after exercise and during the 1 h recovery period compared with the HGI beverage and Pla. This acute improvement is consistent with studies that have noticed to the benefits of a LGI diet as most evident in individuals who follow this diet long-term. This result suggested that the LGI beverage consumed as pre-exercise meal could modify the inflammatory response in prolonged exercise. Further research is needed to establish the connection between glucose kinetics of GI meal and immune function.
Conflict interests
The authors declare they have no conflict interests.
References
Bishop N.C., Blannin A.K., Robson P. J. The effects of carbohydrate supplementation on immune responses to a soccer-specific exercise protocol. Journal of Sports Science, 1999, vol.17, pp. 787-796.
Bishop N.C., Walsh N.P., Haines D.L. Pre exercise carbohydrate status and immune responses to prolonged cycling. II. Effect on plasma cytokine concentration. International Journal of Sport Nutrition and Exercise Metabolism, 2002, vol.11, pp. 503-512.
Bishop N.C., Walsh N.P., Haines D.L. Pre-exercise carbohydrate status and immune responses to prolonged cycling: I. Effect on neutrophil degranulation. International Journal of Sport Nutrition and Exercise Metabolism, 2001, vol.11, pp. 490-503.
Cockburn E., Robson-Ansley P., Hayes P.R. Effect of milk volume consumed on the attenuation of exercise-induced muscle damage. European Journal of Applied Physiology, 2011, vol.51, pp. 618-5.
DeMarco H.M., Sucher K.P., Cisar C.J. Pre-exercise carbohydrate meals: Application of glycemic index. Medicine and Science in Sports and Exercise, 1999, vol.31, pp. 164-170.
Febbraio M.A., Steensberg A., Keller C. Glucose ingestion attenuates interleukin-6 release from contracting skeletal muscle in humans. Journal of Physiology, 2003, vol.549(Pt 2), pp. 607-612.
Foster C.D., Costill W., Fink M. Effects of pre-exercise feedings on endurance performance. Medicine and Science in Sports and Exercise, 1979, vol.11, pp. 1-5.
Guezennec C.Y., Satabin P., Duforez F. The role of type and structure of complex carbohydrates response to physical exercise. International Journal of Sports Medicine, 1993, vol.14, pp. 224-231.
Guezennec C.Y., Satabin P., Duforez F. Oxidation of corn starch, glucose and fructose ingested before exercise. Medicine and Science in Sports and Exercise, 1989, vol.21, pp. 45-50.
Kirwan J.P., O'Gorman D.J., Cyr-Campbell D. Effects of a moderate glycemic meal on exercise duration and substrate utilization. Medicine and Science in Sports and Exercise, 2001, vol.33, pp. 1517-1523.
Koivisto V.A., Karonen S.L., Nikkila E.A. Carbohydrate ingestion before exercise: Comparison of glucose, fructose, and sweet placebo. Journal of Applied Physiology, 1981, vol.51, pp. 783-787.
Kuipers H., Fransen E.J., Keizer H.A. Pre-exercise ingestion of carbohydrate and transient hypoglycemia during exercise. International Journal of Sports Medicine, 1999, vol.20, pp. 227-231.
Li T.L., Wu C.L., Gleeson M. The effects of preexercise high carbohydrate meals with different glycemic indices on blood leukocyte redistribution, IL-6, and hormonal responses during a subsequent prolonged exercise. International Journal of Sport Nutrition and Exercise Metabolism, 2004, vol.14, pp. 647-656.
Matthys P., Mitera T., Heremansl H. Anti-gamma interferon and anti-interleukin-6 antibodies affect staphylococcal enterotoxin B-induced weight loss, hypoglycemia, and cytokine release in D-galactosamine-sensitized and unsensitized mice. Infection and Immunity, 1995, vol.63, pp. 1158-1164.
Miles M.P., Depner C.M. Kirwan R.D. Influence of macronutrient intake and anthropometric characteristics on plasma insulin after eccentric exercise. Metabolism: clinical and experimental, 2010, vol.59, pp. 1456-1464.
Miles M.P., Pearson S.D., Andring J.M. Effect of carbohydrate intake during recovery from eccentric exercise on interleukin-6 and muscle-damage markers. International Journal of Sport Nutrition and Exercise Metabolism, 2007, vol.17, pp. 507-520.
Nehlsen-Cannarella S.L., Fagoaga O.R., Nieman D.C. Carbohydrate and the cytokine response to 2.5 h of running. Journal of Applied Physiology, 1997, vol.82, pp. 1662-1667.
Nieman D.C., Johanssen L., Lee J.W. Immune response to heavy exertion. Journal of Applied Physiology, 1998, vol.82, pp. 1385-1394.
Nieman D.C., Davis J.M., Henson D.A. Muscle cytokine mRNA changes after 2.5 h of cycling: influence of carbohydrate. Medicine and Science in Sports and Exercise. 2004, vol.37, pp. 1283-1290.
Nieman D.C., Dumke C.L., Henson D.A. Muscle damage is linked to cytokine changes following a 160-km race. Brain, Behavior and Immunity, 2006, vol.19, pp. 398-403.
Ostrowski K., Schjerling P., Pedersen B.K. Physical activity and plasma interleukin-6 in humans-effect of intensity of exercise. European Journal of Applied Physiology, 2000, vol.83, pp. 512-5.
Pedersen B.K., Febbraio M.A., Ullum H. Muscle as an endocrine organ: focus on muscle-derived interleukin-6. Physiology Review, 2008, vol.88, pp. 1379-1406.
Pittas A., Roberts S., Das S. The effects of the dietary glycemic load on type 2 diabetes risk factors during weight loss. Obesity, 2006, vol.65, pp. 2200-2209.
Steensberg A., Fischer C.P., Keller C. IL-6 enhances plasma IL-1ra, IL-10, and cortisol in humans. American Journal of Physiology, Endocrinal Metabolism, 2003, vol.285, pp. E433-E437.
Wee S.L., Williams C., Gray S. Influence of high and low glycemic index meals on endurance running capacity. Medicine and Science in Sports and Exercise, 1999, vol.31, pp. 393-399.
IПЕДАГОГ1КА I та медико_б'олог'чн'
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Информация об авторах: Хасани С.: http://orcid.org/0000-0002-7935-106X; sareh.hasani59@ gmail.com; Исламский Азад университет п/я: 1666976113, No 75, 4 Голестан, Пасдаран Аве, Тегеран, Иран.
Супапорн С.: orcid.org/0000-0003-3245-1263; sareh.hasani59@ gmail.com; Шринакхаринвирот университет; 2 Пхра Чан Аллея, Пхра Бором Маха Ратчаванг, Пхра Накхон, Бангкок, 10200, Таиланд.
Мехранпоур А.Б.: orcid.org/0000-0002-8797-8313; mehranpour49@ gmail.com; Шринакхаринвирот университет; 2 Пхра Чан Аллея, Пхра Бором Маха Ратчаванг, Пхра Накхон, Бангкок, 10200, Таиланд.
Витид М.: orcid.org/0000-0001-8888-8398; sareh.hasani59@gmail. com; Шринакхаринвирот университет; 2 Пхра Чан Аллея, Пхра Бором Маха Ратчаванг, Пхра Накхон, Бангкок, 10200, Таиланд.
Цитируйте эту статью как: Хасани С., Супапорн С., Мехранпоур А.Б., Витид М. Влияние гликемического индекса на плазму IL-6 в субмаксимальных упражнениях // Педагопка, психолопя та медико-бюлопчш проблеми фiзичного виховання i спорту. - 2015. - N 5. - С. 49-54. http://dx.doi.org/10.15561/18189172.2015.0509
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Дата поступления в редакцию: 05.04.2015 Принята: 25.04.2015; Опубликована: 30.04.2015
Information about the authors: Hasani S.H.: http://orcid.org/0000-0002-7935-106X; sareh.hasani59@ gmail.com; Islamic Azad University; P.O.BOX: 1666976113, No 75, 4th Golestan St., Pasdaran Ave, Tehran, Iran.
Supaporn S.: orcid.org/0000-0003-3245-1263; sareh.hasani59@gmail. com; Srinakharinwirot University of Bangkok; 2 Phra Chan Alley, Phra Borom Maha Ratchawang, Phra Nakhon, Bangkok, 10200, Thailand.
Mehranpour A.B.: orcid.org/0000-0002-8797-8313; mehranpour49@ gmail.com; Srinakharinwirot University of Bangkok; 2 Phra Chan Alley, Phra Borom Maha Ratchawang, Phra Nakhon, Bangkok, 10200, Thailand.
Witid M.: orcid.org/0000-0001-8888-8398; sareh.hasani59@gmail.com; Srinakharinwirot University of Bangkok; 2 Phra Chan Alley, Phra Borom Maha Ratchawang, Phra Nakhon, Bangkok, 10200, Thailand.
Cite this article as: Hasani S.H., Supaporn S., Mehranpour A.B., Witid M. The effect of glycemic index on plasma il-6 in sub-max exercise. Pedagogics, psychology, medical-biological problems of physical training and sports, 2015, vol.5, pp. 49-54. http://dx.doi. org/10.15561/18189172.2015.0509
The electronic version of this article is the complete one and can be found online at: http://www.sportpedagogy.org.ua/html/arhive-e.html
This is an Open Access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited (http:// creativecommons.org/licenses/by/3.0/deed.en).
Received: 05.04.2015
Accepted: 25.04.2015; Published: 30.04.2015