- ICH GCP
- US Clinical Trials Registry
- Clinical Trial NCT05764018
Caffeine and Hypoxia During Exercise in Males and Females (HypoCaff)
Sex Differences in the Acute Effects of Caffeine Supplementation on Exercise in Normobaric Hypoxia
Several high-altitude destinations recommend their visitors to avoid caffeine, theoretically due to the associated diuresis which could contribute to acute mountain sickness. There is however no direct evidence for this association. In fact, caffeine ingestion is known to improve exercise performance at sea level, and may therefore help mountaineers during expeditions.
Sport science research is largely conducted in male participants, and the findings from these studies are assumed to apply to the female population. Given the known sex differences in body composition, hormones, and other physiological factors, this may not be appropriate. It is therefore important to conduct research in women, to allow for female-specific recommendations.
Study Overview
Status
Intervention / Treatment
Detailed Description
As a result of transportation modernisation and tourism development, an increasing number of individuals are visiting high-altitude destinations for work and leisure purposes. The resulting exposure to (hypobaric) hypoxia is known to reduce exercise capacity due to a reduction in maximal oxygen uptake induced by lower oxygen pressure throughout the oxygen cascade. Several high-altitude destinations recommend their visitors to reduce or completely avoid caffeine intake during their stay. This recommendation is often based on the diuretic effects of caffeine, as the increased fluid loss through urine could accentuate dehydration, potentially contributing to feelings of acute mountain sickness. However, there is currently no scientific evidence to substantiate this recommendation. In fact, caffeine is known to be a particularly effective stimulant to improve exercise performance at sea level. Caffeine could therefore help mountaineers who engage in relatively intense physical activity during expeditions at altitude. The mechanisms underlying the ergogenic effects of caffeine are believed to originate centrally and peripherally. Of particular interest is the potential for caffeine to increase ventilation at submaximal and maximal exercise intensities. In a high-altitude environment, this could help to offset exercise- and hypoxia-induced hypoxemia, thereby enhancing exercise capacity.
Some studies have indeed provided evidence for the notion that caffeine could enhance exercise capabilities in hypoxia. Caffeine doses of 4.0 - 6.0 mg/kg body mass have been assessed, in (simulated and terrestrial) altitude environments equating to 2000 - 4300 m. In each case, it appeared that exercise performance and/or capacity at altitude could indeed be enhanced by caffeine ingestion. However, further mechanistic work is required, particularly in the assessment of the physiological effects of caffeine beyond typical exercise performance (time trial) and exercise capacity (peak power output, maximal oxygen uptake) outcomes. An enhanced holistic understanding of respiratory, cardiovascular, muscular and metabolic responses to exercise, caffeine and hypoxia is necessary to understand if caffeine ingestion at altitude is advisable.
Sport science research is largely conducted in male participants, and the findings from these studies are assumed to also apply to the female population. However, given the known sex differences in body composition, hormones, and other physiological factors, these assumptions may not be appropriate. It is therefore important to conduct research in women, to allow female-specific recommendations to be applied to athletes and to the general population.
As these are important considerations, the aim of this project is to investigate the effects of caffeine supplementation on exercise in hypoxia, and to determine whether these effects are influenced by sex differences.
24 healthy adult participants (12 male, 12 female) will be recruited to take part in the project. A preliminary testing session will be used to determine the maximal oxygen uptake of the participants in normoxia, and to familiarise them with the main trial protocol. A second preliminary laboratory visit will be used to measure the resting metabolic rate of the participants.
The main phase of the experiment will be a four-trial randomised crossover study; normoxia (ambient) vs. hypoxia (fraction of inspired oxygen = 0.13) and placebo (20 g maltodextrin) vs. caffeine (20 g maltodextrin + 6 mg/kg body mass caffeine). Participants will avoid caffeine, alcohol and intense exercise for 24 h prior to each laboratory visit. They will also replicate their diet for 24 h before each main trial. Each main trial will involve a 20-minute moderate-intensity cycling period, immediately followed by an incremental exercise test to exhaustion. Participants will be blinded to the environmental condition and the contents of the test drink. Outcome measures will include gas exchange variables, blood glucose/lactate concentration, muscle and brain oxygenation, blood oxygen saturation, heart rate and rating of perceived exertion. These measurements will provide a holistic overview of the broad physiological response to exercise, hypoxia and caffeine.
Study Type
Enrollment (Anticipated)
Phase
- Not Applicable
Contacts and Locations
Study Contact
- Name: Tadej Debevec, PhD
- Phone Number: +386 15207726
- Email: Tadej.Debevec@fsp.uni-lj.si
Study Locations
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-
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Ljubljana, Slovenia, 1000
- Recruiting
- University of Ljubljana
-
Contact:
- Tadej Debevec, PhD
- Phone Number: +38615207726
- Email: Tadej.Debevec@fsp.uni-lj.si
-
-
Participation Criteria
Eligibility Criteria
Ages Eligible for Study
Accepts Healthy Volunteers
Genders Eligible for Study
Description
Inclusion Criteria:
- Regularly physically active (at least 30 mins of structured exercise 5 times per week).
- Sea-level natives.
Exclusion Criteria:
- presence of any medical risk factors to exercise and/or exposure to altitude
- presence of any medical condition that would make the protocol unreasonably hazardous for the participant
- smokers
- exposure to altitude above 2000 m in the last 2 months
Study Plan
How is the study designed?
Design Details
- Primary Purpose: Other
- Allocation: Randomized
- Interventional Model: Crossover Assignment
- Masking: Triple
Arms and Interventions
Participant Group / Arm |
Intervention / Treatment |
---|---|
Placebo Comparator: Normoxia-Placebo
Participants will be breathing room air, and ingest a flavoured drink containing only a trivial amount of maltodextrin.
|
Negligible amount of maltodextrin in flavoured drink solution provided 45 minutes before exercise.
Other Names:
Participants will be breathing from ambient air (~21% O2) for the duration of the exercise bout.
This will provide no hypoxic stimulus as the laboratory is located relatively near sea level (295 m)
Other Names:
|
Experimental: Normoxia-Caffeine
Participants will be breathing room air, and ingest a flavoured drink containing a trivial amount of maltodextrin and 6 mg/kg body mass caffeine.
|
Participants will be breathing from ambient air (~21% O2) for the duration of the exercise bout.
This will provide no hypoxic stimulus as the laboratory is located relatively near sea level (295 m)
Other Names:
Negligible amount of maltodextrin in flavoured drink solution containing 6 mg/kg body mass caffeine provided 45 minutes before exercise
|
Placebo Comparator: Hypoxia-Placebo
Participants will be breathing a 13% oxygen gas mixture, and ingest a flavoured drink containing only a trivial amount of maltodextrin.
|
Negligible amount of maltodextrin in flavoured drink solution provided 45 minutes before exercise.
Other Names:
Participants will be breathing from a hypoxic gas mixture (13% O2) for the duration of the exercise bout.
This will simulate an altitude of approximately 3500 m.
Other Names:
|
Experimental: Hypoxia-Caffeine
Participants will be breathing a 13% oxygen gas mixture, and ingest a flavoured drink containing a trivial amount of maltodextrin and 6 mg/kg body mass caffeine.
|
Negligible amount of maltodextrin in flavoured drink solution containing 6 mg/kg body mass caffeine provided 45 minutes before exercise
Participants will be breathing from a hypoxic gas mixture (13% O2) for the duration of the exercise bout.
This will simulate an altitude of approximately 3500 m.
Other Names:
|
What is the study measuring?
Primary Outcome Measures
Outcome Measure |
Measure Description |
Time Frame |
---|---|---|
Peak oxygen uptake
Time Frame: Immediately prior to volitional exhaustion during the incremental exercise test
|
Peak oxygen consumption (VO2peak, ml/kg/min) will be quantified from the end of each maximal exercise test and compared between groups and conditions.
|
Immediately prior to volitional exhaustion during the incremental exercise test
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Maximal aerobic power
Time Frame: At the instant of volitional exhaustion during the incremental exercise test
|
Maximal aerobic power (MAP, W) will be quantified based on the time at which participants reach volitional exhaustion during the incremental exercise tests.
This value will then be compared between groups and conditions.
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At the instant of volitional exhaustion during the incremental exercise test
|
Peak minute ventilation
Time Frame: Immediately prior to volitional exhaustion during the incremental exercise test
|
Peak minute ventilation (VEpeak, L/min) will be quantified from the end of each maximal exercise test and compared between groups and conditions.
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Immediately prior to volitional exhaustion during the incremental exercise test
|
Peak heart rate
Time Frame: Immediately prior to volitional exhaustion during the incremental exercise test
|
Peak heart rate (HRpeak, bpm) will be quantified from the end of each maximal exercise test and compared between groups and conditions.
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Immediately prior to volitional exhaustion during the incremental exercise test
|
Muscle oxygenation nadir
Time Frame: Immediately prior to volitional exhaustion during the incremental exercise test
|
The nadir in muscle oxygenation (TSIMmin, %) will be quantified from the end of each maximal exercise test and compared between groups and conditions.
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Immediately prior to volitional exhaustion during the incremental exercise test
|
Peak blood lactate concentration
Time Frame: Immediately after volitional exhaustion during the incremental exercise test
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Blood lactate concentration will be measured immediately after the incremental exercise test to exhaustion ([BLapeak], mmol/L).
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Immediately after volitional exhaustion during the incremental exercise test
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Secondary Outcome Measures
Outcome Measure |
Measure Description |
Time Frame |
---|---|---|
Submaximal oxygen uptake
Time Frame: From the onset of exercise to the end of the submaximal exercise period at 20 mins.
|
Oxygen consumption (VO2, L/min) will be continuously monitored during the exercise bouts under each condition.
Absolute oxygen uptake during the submaximal exercise phases will be compared between groups and conditions.
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From the onset of exercise to the end of the submaximal exercise period at 20 mins.
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Submaximal minute ventilation
Time Frame: From the onset of exercise to the end of the submaximal exercise period at 20 mins.
|
Minute ventilation (VE, L/min) will be continuously monitored during the exercise bouts under each condition, and values during the submaximal exercise phases will be compared between groups and conditions.
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From the onset of exercise to the end of the submaximal exercise period at 20 mins.
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Submaximal substrate oxidation
Time Frame: From the onset of exercise to the end of the submaximal exercise period at 20 mins.
|
Substrate oxidation, as respiratory exchange ratio (RER, arbitrary units) will be continuously monitored during the exercise bouts under each condition.
The relative contributions of fat and carbohydrate will be estimated using this variable and compared between groups and conditions.
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From the onset of exercise to the end of the submaximal exercise period at 20 mins.
|
Submaximal muscle oxygenation
Time Frame: From the onset of exercise to the end of the submaximal exercise period at 20 mins.
|
Muscle oxygenation, as tissue saturation index (TSIM, %), will be continuously monitored during the exercise bouts under each condition using near-infrared spectroscopy.
Absolute muscle oxygenation during the submaximal exercise phases, will be compared between groups and conditions.
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From the onset of exercise to the end of the submaximal exercise period at 20 mins.
|
Submaximal brain oxygenation
Time Frame: From the onset of exercise to the end of the submaximal exercise period at 20 mins.
|
Brain oxygenation, as tissue saturation index (TSIB, %), will be continuously monitored during the exercise bouts under each condition using near-infrared spectroscopy.
Absolute brain oxygenation during the submaximal exercise phases, will be compared between groups and conditions.
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From the onset of exercise to the end of the submaximal exercise period at 20 mins.
|
Submaximal heart rate
Time Frame: From the onset of exercise to the end of the submaximal exercise period at 20 mins.
|
Heart rate (HR, bpm), will be continuously monitored during the exercise bouts under each condition.
Absolute heart rate during the submaximal exercise phases, will be compared between groups and conditions.
|
From the onset of exercise to the end of the submaximal exercise period at 20 mins.
|
Blood glucose concentration
Time Frame: At rest prior to exercise, and at the end of the submaximal exercise period at 20 mins.
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Blood glucose concentration ([BG] mmol/L) will be measured at baseline and at the end of the submaximal exercise phase, to provide an indication of relative carbohydrate flux within each group and condition.
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At rest prior to exercise, and at the end of the submaximal exercise period at 20 mins.
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Blood lactate concentration
Time Frame: At rest prior to exercise, and at the end of the submaximal exercise period at 20 mins.
|
Blood lactate concentration ([BLa] mmol/L) will be measured at baseline and at the end of the submaximal exercise phase, to provide an indication of anaerobic metabolism within each group and condition.
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At rest prior to exercise, and at the end of the submaximal exercise period at 20 mins.
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Rating of perceived exertion
Time Frame: Every 5 minutes throughout the 20 minute submaximal exercise period.
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Ratings of perceived exertion (RPE, 6-20) will be measured throughout the submaximal exercise phases to establish the perception of workload.
This will be compared between groups and conditions.
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Every 5 minutes throughout the 20 minute submaximal exercise period.
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Collaborators and Investigators
Sponsor
Investigators
- Principal Investigator: Tadej Debevec, PhD, University of Ljubljana
Study record dates
Study Major Dates
Study Start (Anticipated)
Primary Completion (Anticipated)
Study Completion (Anticipated)
Study Registration Dates
First Submitted
First Submitted That Met QC Criteria
First Posted (Estimate)
Study Record Updates
Last Update Posted (Estimate)
Last Update Submitted That Met QC Criteria
Last Verified
More Information
Terms related to this study
Keywords
Additional Relevant MeSH Terms
- Signs and Symptoms, Respiratory
- Hypoxia
- Physiological Effects of Drugs
- Neurotransmitter Agents
- Molecular Mechanisms of Pharmacological Action
- Enzyme Inhibitors
- Purinergic Antagonists
- Purinergic Agents
- Phosphodiesterase Inhibitors
- Purinergic P1 Receptor Antagonists
- Central Nervous System Stimulants
- Caffeine
Other Study ID Numbers
- HypoCaff
Plan for Individual participant data (IPD)
Plan to Share Individual Participant Data (IPD)?
Drug and device information, study documents
Studies a U.S. FDA-regulated drug product
Studies a U.S. FDA-regulated device product
product manufactured in and exported from the U.S.
This information was retrieved directly from the website clinicaltrials.gov without any changes. If you have any requests to change, remove or update your study details, please contact register@clinicaltrials.gov. As soon as a change is implemented on clinicaltrials.gov, this will be updated automatically on our website as well.
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