Effect of Energy Drink on Sport Performance and Psycho-Physiological Responses.

Physical Activity Clinical Trial

Official title:

Effects of Energy Drink on Performance and Psycho-Physiological Response to Physical Exercise

Clinical Trial Details — Status: Completed

Administrative data

• NCT number: NCT03936712
• Other study ID #: Hamdi Chtourou
• Status: Completed
• Phase: N/A
• Start date: January 1, 2017
• Est. completion date: January 12, 2017

Study information

• Verified date: May 2019
• Source: The Higher Institute of Sport and Physical Education of Sfax
• Contact: n/a
• Is FDA regulated: No
• Study type: Interventional

Clinical Trial Summary

This work aimed to examine the effects of drinking an "energy drink" upon (i) short-term maximal performance, (ii) reaction times and (iii) psychological factors (i.e., mood state, ratings of perceived exertion (RPE) and affective load) and on physiological parameters such as blood pressure, blood glucose, hematological parameters and other biochemical parameters.

Description:

A total of 22 healthy and regularly active physical-education male students from various sports disciplines volunteered to participate in this study. Potential participants were initially screened through telephone interviews based on the inclusion criteria: 18-40 years of age, BMI less than 25 kg/m2, and low (<1.5g/month ) and not regular caffeine users. Exclusion criteria included diagnosis of any chronic metabolic disease such as type 2 diabetes or cardiovascular disease, an auto-immune disease such as rheumatoid arthritis, lupus or type 1 diabetes, liver disease and the intake of any medications/ or dietary supplements known to influence blood glucose concentrations and/or blood pressures.

The study was conducted according to the declaration of Helsinki and the protocol was fully approved (identification code: 8/16) by the review board "Local committee of the Laboratory of Biochemistry, CHU Habib Bourguiba, Sfax, Tunisia." After a throughout explanation of the protocol and responses to all questions, participants signed a written informed consent.

Subjects were instructed to avoid nicotine, alcohol, dietary supplements, medications and all other stimulants and to maintain their normal dietary, sleep and physical activity patterns before test sessions. Caffeine and other caffeinated products (e.g., chocolate, caffeinated gums, caffeine containing beverages) were avoided for 48 hours and food for at least 4 hours before testing.

A double blind, placebo-controlled, counterbalanced, crossover design was adopted for this study. The randomized order of testing was determined using free online software (www.randomization.com). Neither staff nor participants were informed about the names of the two drinks, and blinding was strictly maintained by emphasizing to both staff and participants that both drinks adhered to healthy principles, and that each was advocated by certain sports medicine experts. Two familiarization sessions were completed before definitive test sessions in order to eliminate any learning effects on physical performance and reaction time measurements. During the second familiarization session, body mass and height were recorded. Each participant visited the laboratory for two formal test sessions, drinking a caffeine-containing ED (RB) and a caffeine and taurine free beverage drink (PL). All sessions were arranged in the early evening hours to avoid any time of day effects. The two definitive test sessions were separated by an interval of seven days to allow sufficient recovery between tests and to ensure caffeine washout. To avoid identification, two opaque and unmarked cans of RB or PL were ingested by each participant (i.e., 500 mL) in the presence of a researcher. The two drinks were similar in volume, texture, and appearance. One can of RB drink (i.e., 250ml) contained 80 mg of caffeine, 1 g of taurine, 27 g of carbohydrates, 0.6 g of protein, 5 mg vitamin B6 and 487 kJ of energy. The PL drink was prepared by an agri-food engineer; it did not contain any caffeine or taurine, but comprised carbonated water, carbohydrates, citric acid lemon juice reconstituted from concentrate (1 %), supplemented by flavorings, of sodium citrate, acesulfame K, sucralose, potassium sorbate and RB (a flavoring that contains propylene glycol E1520 (0.23 mL).

Beverages were prepared, shaken and chilled in a refrigerator at 14h00 by an investigator who took no part in the test sessions or data analysis, but prepared the alphanumeric code identifying the tested drink. At 17h00, the cooled beverages were served in sealed plastic opaque water bottles and consumed using an opaque straw. Participants were instructed to drink the fluid quickly (within 1±0.5 min) 60 minutes before their test session and not to discuss or compare tastes or to make any assumptions about what they had ingested. The interval of 60 minutes was chosen as optimal for a complete caffeine absorption and thus a peaking of a caffeine concentration .

Subjects were supervised by staff to ensure that they drank the entire quantity of fluid, and no exchange of bottles was allowed. The last standardized meal (i.e., lunch) before the beginning of the test session was taken at 13h00. Temperature and relative humidity of the laboratory were similar over the test sessions, with a temperature of around 22°C and a relative humidity between 45 and 55 %. During each test session (from 18h00), resting blood glucose and blood pressures were measured and the participants completed the POMS questionnaire.

A 5-min treadmill warm-up was performed. After that, the reaction time, and handgrip force were determined, and the 30-s Wingate test was performed. RPE scores, blood glucose and blood pressures were then measured, and the affective load was calculated. To investigate the effects of RB on the acute physiological and psychological responses to exercise, blood measures and psychological test measures were collected immediately pre- and post-exercise.

Recruitment information / eligibility

• Status: Completed
• Enrollment: 22
• Est. completion date: January 12, 2017
• Est. primary completion date: January 12, 2017
• Accepts healthy volunteers: Accepts Healthy Volunteers
• Gender: Male
• Age group: 18 Years to 40 Years

Eligibility

Inclusion Criteria:

• 18-40 years of age,

• BMI less than 25 kg/m2,

• low (<1.5g/month [20]) caffeine users

• not regular caffeine users.

Exclusion Criteria:

• chronic metabolic disease such as type 2 diabetes and cardiovascular disease

• auto-immune disease such as rheumatoid arthritis, lupus or type 1 diabetes,

• liver disease

• intake of any medications/ or dietary supplements known to influence blood glucose and/or blood pressures.

Related Conditions & MeSH terms

• Physical Activity

Intervention

Dietary Supplement:
• Energy Drink
Each participant visited the laboratory for two formal test sessions, drinking a caffeine-containing ED (RB) and a caffeine and taurine free beverage drink (PL). All sessions were arranged in the early evening hours to avoid any time of day effects. The two definitive test sessions were separated by an interval of seven days to allow sufficient recovery between tests and to ensure caffeine washout. To avoid identification, two opaque and unmarked cans of RB or PL were ingested by each participant (i.e., 500 mL) in the presence of a researcher. The two drinks were similar in volume, texture, and appearance. One can of RB drink (i.e., 250ml) contained 80 mg of caffeine, 1 g of taurine, 27 g of carbohydrates, 0.6 g of protein, 5 mg vitamin B6 and 487 kJ of energy.
• Placebo Drink
The PL drink was prepared by an agri-food engineer; it did not contain any caffeine or taurine, but comprised carbonated water, carbohydrates, citric acid lemon juice reconstituted from concentrate (1 %), supplemented by flavorings, of sodium citrate, acesulfame K, sucralose, potassium sorbate and RB (a flavoring that contains propylene glycol E1520 (0.23 mL).

Locations

Country	Name	City	State
n/a

Sponsors (1)

Lead Sponsor	Collaborator
The Higher Institute of Sport and Physical Education of Sfax

Outcome

Type	Measure	Description	Time frame	Safety issue
Primary	Change in Wingate-test physical performance from PL to RB condition	A calibrated mechanically-braked cycle ergometer (Monark 894; Stockholm, Sweden) interfaced with a microcomputer was utilized for the 30-s Wingate test. Subjects pedaled as fast as possible for 30-s against a constant load calculated according to the participant's body-mass (i.e., 8.7%). After maintaining a constant ~60rpm speed for 4-6-s against minimal resistance, the selected load was applied. The participant sat on the cycle throughout and was strongly encouraged to maximize pedaling rates and to maintain a high speed. Peak and mean power (i.e., average of power output the 30-s) were recorded. The fatigue index was calculated as follows: Fatigue index (%) = [(peak power-minimal power)/ peak power×100]. The ICC and SEM showed excellent reliability for peak power (ICC>0.98, absolute SEM <0.21), mean power (ICC>0.98, absolute SEM <0.23) and fatigue index (ICC>0.76, absolute SEM <1.99).	The performance in Wingate test was measured 1 hour following the consumption of supplementations in the first and second test sessions (RB session and PLA session) to assess possible beneficial effect of RB supplementation in physical performance
Primary	Change in Reaction Time Performance from PL to RB condition	A simple visual reaction time test assessed alertness and motor reaction-speed. Subjects responded as quickly as possible to presentation of a stimulus (the image of a black box) on a computer screen (15" LCD). When this appears, the participant should press the index finger on a computer key. The signal appeared in random order within 1-10-s time intervals. Each participant was allowed ten attempts and the mean reaction time was calculated, using React! V0.9 software.The ICC and SEM showed excellent reliability for reaction time (ICC>0.89, absolute SEM <0.14) measurement.	The reaction time performance was measured 1 hour following the consumption of supplementations in the first and second test sessions (RB session and PLA session) to assess possible beneficial effect of RB in reaction time performance
Primary	Change in Strength Physical Performance (i.e., Handgrip) from PL to RB condition	Handgrip strength was recorded by dynamometer (T.K.K. 5401; Takei, Tokyo, Japan). The maximal handgrip force was determined for the dominant hand. Participants exerted their maximal strength for 4-5-s. With the hand hanging downwards, the dynamometer was	Handgrip performance was measured 1 hour following the consumption of supplementations in the first and second test sessions (RB session and PLA session) to assess possible beneficial effect of RB supplementation in strength (i.e., Handgrip) performance
Primary	Change in Rating of Perceived Exertion (RPE) and Affective Load from PL to RB condition	The original Borg RPE scale rates exertion subjectively during or after physical exercise on a 15-point scale ranging from six (very very light) to twenty (very very hard). It was used to calculate the affective load; the affective load was obtained as the difference between the perceived exertion (negative affective response) and pleasure scores (positive affective response). For example, with an RPE score of six, the negative affective response is zero and the positive affective response is -14. However, if the RPE score rises to 20, the negative affective response is +14 and the positive affective response is zero. The potential affective load thus ranges from -14 to +14. A negative affective load score indicates the dominance of pleasant affective responses and a positive affective load represents the dominance of unpleasant affective responses.	RPE and Affective Load were measured immediately following the first and second training sessions (RB and PL sessions) to assess any beneficial effect of the consumed RB (1 hour before session) on fatigue and load perception
Primary	Change in Mood States (POMS) from PL to RB condition	The evaluation of mood states used the French language version of the POMS questionnaire. Responses to 65 adjectives (ranging from "Zero" (i.e., not at all) to "Four" (i.e., extremely) assessed immediate mood states in seven dimensions: tension, depression, anger, vigor, fatigue, confusion and interpersonal relationships.	POMS was measured immediately following the first and second training sessions (RB and PL sessions) to assess any beneficial effect of the consumed RB (1hour before session) on perception of tension, depression, anger, vigor, fatigue, and confusion
Primary	Change in Blood pressure and blood glucose from pre- to post-training session using RB condition	Blood glucose was measured using the electrochemical sensor Rightest GM260 Blood Glucose Monitoring System (Bionime Corporation, Taichung City, Taiwan). The finger tip was pricked with a lancing device, and a specific test strip was soaked with blood was inserted into the measuring apparatus, with an estimate appearing within 5 seconds. Blood pressure was measured by the same physician using a stethoscope (Spengler, Germany) and sphygmomanometer (Spengler, Germany).	Blood pressure and blood glucose were measured 1 hour after RB supplementation (correspond to pre-training session) and also immediately following the training session to assess any exercise effect on blood pressure/glucose responses during RB condition
Primary	Change in Blood pressure and blood glucose from pre- to post-training session using PL condition	Blood glucose was measured using the electrochemical sensor Rightest GM260 Blood Glucose Monitoring System (Bionime Corporation, Taichung City, Taiwan). The finger tip was pricked with a lancing device, and a specific test strip was soaked with blood was inserted into the measuring apparatus, with an estimate appearing within 5 seconds. Blood pressure was measured by the same physician using a stethoscope (Spengler, Germany) and sphygmomanometer (Spengler, Germany).	Blood pressure and blood glucose were measured 1 hour after PL supplementation (correspond to pre-training session) and also immediately following the training session to assess any exercise effect on blood pressure/glucose responses during PL condition
Primary	Change in hematological parameters from pre- to post-training session using RB condition	Haematological parameters (i.e., white blood cells (WBC), neutrophils (NEU), red blood cells (RBC), hemoglobin (HGB), hematocrit (HCT)and platelets (PLT) were determined using a multichannel automated blood cell analyser Beckman Coulter Gen system-2 (Coulter T540)	Hematological parameters were measured 1 hour after RB supplementation (correspond to pre-training session) and also immediately following the training session to assess any exercise effect on hematological responses during RB condition
Primary	Change in hematological parameters from pre to post training session using PL condition	Haematological parameters (i.e., white blood cells (WBC), neutrophils (NEU), red blood cells (RBC), hemoglobin (HGB), hematocrit (HCT)and platelets (PLT) were determined using a multichannel automated blood cell analyser Beckman Coulter Gen system-2 (Coulter T540)	Hematological parameters were measured 1 hour after PL supplementation (correspond to pre-training session) and also immediately following the training session to assess any exercise effect on hematological responses during PL condition
Primary	Change in muscle damage parameters from pre to post training session using RB condition	muscle damage markers: Creatinine kinase (CK), Alkaline phosphate (PAL), Gammaglutamyl (GGT), Lactate dehydrogenase (LDH), and c-reactive protein (CRP) were determined spectrophotometrically using Abott Architect Ci 4100.	Muscle damage parameters were measured 1 hour after RB supplementation (correspond to pre-training session) and also immediately following the training session to assess any exercise effect on muscle damage responses during RB condition
Primary	Change in muscle damage parameters from pre to post training session using PL condition	muscle damage markers: Creatinine kinase (CK), Alkaline phosphate (PAL), Gammaglutamyl (GGT), Lactate dehydrogenase (LDH), and c-reactive protein (CRP) were determined spectrophotometrically using Abott Architect Ci 4100.	Muscle damage parameters were measured 1 hour after PL supplementation (correspond to pre-training session) and also immediately following the training session to assess any exercise effect on muscle damage responses during PL condition
Primary	Change in oxidative stress parameters from pre to post training session using RB condition	Oxididative stress response (i.e., malondialdehyde (MDA), superoxide dismutase (SOD), glutathione peroxidase (GPx), Catalase (CAT), uric acid (UA)) and c-reactive protein (CRP)) were determined spectrophotometrically using Abott Architect Ci 4100.	Oxidative stress parameters were measured 1 hour after RB supplementation (correspond to pre-training session) and also immediately following the training session to assess any exercise effect on oxidative stress responses during RB condition
Primary	Change in oxidative stress parameters from pre to post training session using PL condition	Oxididative stress response (i.e., malondialdehyde (MDA), superoxide dismutase (SOD), glutathione peroxidase (GPx), Catalase (CAT), uric acid (UA)) and c-reactive protein (CRP)) were determined spectrophotometrically using Abott Architect Ci 4100.	Oxidative stress parameters were measured 1 hour after PL supplementation (correspond to pre-training session) and also immediately following the training session to assess any exercise effect on oxidative stress responses during PL condition