Healthy Adult Male
Conditions
Keywords
basic science
Brief summary
The goal of this study is to learn if low-dose caffeinated coffee improves repeated sprint performance and affects energy system contributions in combat sports athletes. The main questions it aims to answer are: * Does low-dose caffeinated coffee (1.5 or 3 mg·kg-¹) improve peak power, mean power, and fatigue index during repeated sprint tests? * What physiological responses (heart rate, blood lactate, perceived exertion, and energy system contributions) do participants have when consuming caffeinated coffee? Researchers compared caffeinated coffee at two doses (1.5 and 3 mg·kg-¹ body mass) to a placebo (decaffeinated coffee of identical taste and appearance) to see if low
Detailed description
This investigation examined whether acute ingestion of low-dose caffeine delivered through commercially available regular coffee would alter repeated sprint capacity and metabolic energy system dynamics in athletes who compete in combat disciplines. A within-subject, double-blind, placebo-controlled crossover framework was adopted to ensure methodological rigor and minimize order and expectation biases. Eligible participants were physically active male combat sports competitors (n = 15; aged 18-25 years) with a documented competitive history spanning at least five years at the regional and national levels. Volunteers were excluded if they reported recent use of performance-modifying agents, stimulant or psychotropic medications, tobacco products, or any diagnosed condition affecting cardiovascular, metabolic, or musculoskeletal function. To standardize caffeine baseline, all participants were instructed to abstain from caffeinated products for a minimum of two weeks prior to the study onset and throughout the entire data collection period. Each participant attended the laboratory on four separate occasions. The initial visit served as a familiarization session and included anthropometric assessment. The subsequent three sessions were assigned in a randomized, counterbalanced order, with a minimum 48-hour recovery interval separating each visit. During these sessions, participants received one of three coded supplementation conditions - placebo (decaffeinated coffee), low-dose caffeine (1.5 mg·kg-¹ body mass), or moderate-low-dose caffeine (3 mg·kg-¹ body mass) - each dissolved in 250 mL of hot water and consumed over a 10-minute period. The caffeine content of both the caffeinated and decaffeinated coffee products (Nescafe Gold) was verified by an accredited food analysis laboratory. To maintain identical volume, appearance, and taste across all conditions, decaffeinated and caffeinated coffees were blended in varying proportions for each dose level. Supplementation was administered 60 minutes before the commencement of exercise testing. Performance testing comprised a standardized cycling-based repeated sprint protocol: six 10-second maximal effort sprints, each separated by a 30-second passive recovery period, performed on a mechanically braked cycle ergometer (Monark 894E) with resistance set at 10% of individual body mass. A structured warm-up preceded each testing bout. Primary performance variables derived from sprint testing included peak power output, mean power output, and fatigue index. Perceptual and physiological responses were documented via the Borg rating of perceived exertion scale, peak heart rate, and capillary blood lactate concentration measured at rest and immediately following the final sprint. Breath-by-breath oxygen uptake data were collected continuously using a portable metabolic system (COSMED K5) to facilitate estimation of energy system contributions. The relative and absolute contributions of the phosphocreatine (ATP-PCr), glycolytic, and oxidative metabolic pathways were quantified using established indirect methods. Excess post-exercise oxygen consumption (EPOC) kinetics were modeled with mono-exponential curve fitting to isolate the fast EPOC component, which served as a proxy for PCr resynthesis. Glycolytic contribution was estimated from the net change in blood lactate concentration, applying an established oxygen-equivalent conversion factor. Oxidative metabolism was derived from the net elevation in VO₂ above resting values during exercise. Total energy expenditure was computed as the cumulative sum of all three pathway contributions. To control for dietary and diurnal confounders, participants replicated identical pre-test meal patterns documented during the first testing session, and all laboratory visits were conducted between 08:00 and 11:00 h. Dietary adherence was verified through structured diet logs reviewed by the research team. Data were analyzed using one-way repeated-measures ANOVA with Bonferroni-adjusted pairwise comparisons, and partial eta squared (η²p) was reported as the measure of effect magnitude. The study received full ethical clearance from the Trabzon Eurasia University Ethics Committee and was conducted in accordance with the principles outlined in the Declaration of Helsinki. Informed consent form obtained from all the participants.
Interventions
OTHERCycling Repeated Sprint Test (6 × 10 s)
A standardized cycling-based repeated sprint protocol consisting of six 10-second maximal-effort sprints, each separated by a 30-second passive rest interval, performed on a mechanically braked cycle ergometer (Monark 894E, Vansbro, Sweden). Resistance was calibrated at 10% of the participant's individual body mass. The inertial momentum of the flywheel was excluded from power output calculations following the approach described by Bogdanis et al. (2008). Each session was preceded by a structured warm-up consisting of five 30-second bouts at 100 W, followed by a 5-minute seated rest before test commencement. Each participant initiated the protocol with their dominant leg to ensure procedural consistency across all sessions.
OTHERBreath-by-Breath VO₂ Monitoring - COSMED K5
Continuous breath-by-breath oxygen uptake (VO₂) data were collected throughout each testing session using the COSMED K5 portable metabolic system (Rome, Italy). Data were used to estimate the relative and absolute contributions of the three metabolic energy pathways. The fast component of excess post-exercise oxygen consumption (EPOC) was extracted and modeled using a mono-exponential function (OriginPro 8.0, OriginLab Corp.) to estimate phosphocreatine (PCr) resynthesis during recovery intervals and following the final sprint. Oxidative metabolism contribution was derived by subtracting resting VO₂ from exercise VO₂. Total energy demand was expressed in both liters of O₂ and kilojoules (caloric equivalent: 20.92 kJ·L-¹ O₂).
OTHERCapillary Blood Lactate Sampling (non-invasive)
Capillary blood samples were obtained at two time points per session: (1) resting lactate (LA\_rest) - collected following a 20-minute passive rest period immediately before the sprint test, in accordance with published lactate clearance protocols; and (2) maximal post-exercise lactate (LA\_max) - collected immediately upon completion of the final sprint repetition. Delta lactate (ΔLA) was calculated as the arithmetic difference between LA\_max and LA\_rest and expressed in mmol·L-¹. Delta lactate values were additionally used to estimate the glycolytic energy system contribution, applying a conversion factor of 3 mL O₂·kg-¹ body mass per 1 mmol·L-¹ increase in blood lactate concentration (Di Prampero \& Ferretti, 1999).
Continuous heart rate was recorded throughout each testing session via chest type radiotelemetry sensor integrated with COSMED K5. Peak heart rate (HR\_peak, bpm) was defined as the highest value observed across the entire repeated sprint protocol and reported as a secondary physiological outcome.
Sponsors
Trabzon University
Study design
Allocation
RANDOMIZED
Intervention model
CROSSOVER
Primary purpose
BASIC_SCIENCE
Masking
DOUBLE (Subject, Investigator)
Eligibility
Sex/Gender
MALE
Age
18 Years to 25 Years
Healthy volunteers
Yes
Inclusion criteria
* Male combat sports athletes aged 18 to 25 years * Minimum of five years of continuous structured training * Competitive experience at both regional (state) and national levels * Willingness to abstain from all caffeinated products for two weeks prior to and throughout the study period * Ability to follow a standardized dietary protocol prescribed by an Olympic Preparation Center dietitian * Provision of written informed consent
Exclusion criteria
* Age below 18 years * Self-reported use of anabolic agents, hormonal modulators, or performance-influencing dietary supplements within the three months preceding enrollment * Current use of narcotic, psychotropic, stimulant medications, or tobacco products during the assessment period * Presence of any diagnosed medical condition (including cardiovascular, metabolic, neurological, respiratory, or musculoskeletal disorders) that may compromise safe participation * Withdrawal from the study at the participant's own request
Design outcomes
Primary
| Measure | Time frame | Description |
|---|---|---|
| Peak Power Output | On 3 testing days with 48-hour interval | Highest instantaneous power output (Watts) recorded across all six 10-second sprint bouts on the cycle ergometer (Monark 894E), with resistance set at 10% of body mass. |
| Mean Power Output | On 3 testing days with 48-hour interval | Average power output (Watts) calculated across all six sprint efforts, reflecting the athlete's overall capacity to sustain high-intensity output across the full protocol. |
| Fatigue Index | On 3 testing days with 48-hour interval | Quantified as: FI = 100 × (1 - total peak power / ideal peak power), where ideal peak power is the product of the highest single-sprint peak power and the total number of repetitions. Expressed as a percentage (%). |
Secondary
| Measure | Time frame | Description |
|---|---|---|
| Total Energy Expenditure | On 3 testing days with 48-hour interval | Computed as the cumulative sum of ATP-PCr, glycolytic, and oxidative pathway contributions, expressed in kilojoules (kJ), using a caloric equivalent of 20.92 kJ per liter of O₂ consumed. |
| Energy System - Oxidative Contribution | On 3 testing days with 48-hour interval | Estimated absolute contributions (kJ) of each metabolic pathway. Oxidative contribution calculated as net VO₂ elevation above resting baseline. Breath-by-breath VO₂ data collected continuously via COSMED K5 portable metabolic system. |
| Energy System - ATP Contribution | On 3 testing days with 48-hour interval | ATP-PCr contribution derived from the fast component of EPOC kinetics modeled via mono-exponential curve fitting (OriginPro 8.0). |
| Energy System - Glycolytic Contribution | On 3 testing days with 48-hour interval | Glycolytic contribution estimated from net blood lactate rise (3 mL O₂·kg-¹ per 1 mmol·L-¹ increase). |
| Peak Heart Rate | On 3 testing days with 48-hour interval | Highest recorded heart rate (bpm) during the repeated sprint test. |
| Delta Blood Lactate Concentration | On 3 testing days with 48-hour interval | Difference between resting capillary blood lactate (measured after 20-minute passive rest prior to testing) and maximum post-exercise lactate (measured immediately following the final sprint). Expressed in mmol·L-¹. |
| Rating of Perceived Exertion | On 3 testing days with 48-hour interval | Subjective effort rating collected using the Borg scale (6-20) following the completion of the repeated sprint protocol. |
Countries
Turkey (Türkiye)
Outcome results
None listed