Introduction
Caffeine is one of the most widely consumed psychoactive substances globally, with coffee alone accounting for approximately 2.25 billion cups consumed daily. Athletes and sports practitioners commonly use caffeine, not only for habitual or social reasons, but particularly for its effects in enhancing alertness and physical performance. The ergogenic benefits of caffeine—a methylxanthine alkaloid primarily acting as an adenosine receptor antagonist—are well-documented across various performance domains including endurance, strength, power, and cognitive functions.
At doses typically ranging from 3 to 6 mg/kg bodyweight ingested around one hour pre-exercise, caffeine enhances the volume of work, reduces glycogen utilization, delays fatigue, and improves muscle tension and power output. However, despite these benefits, caffeine has recognized side effects such as nervousness, gastrointestinal disturbances, and crucially, impaired sleep quality, particularly when consumed close to bedtime. This raises a clinical and practical conflict for athletes, especially those competing in the evening or at night: whether to ingest caffeine to gain acute performance benefits or to avoid caffeine to preserve optimal sleep, recovery, and subsequent athletic outcomes.
This article critically examines the interplay between caffeine’s ergogenic effects and its impact on sleep quality, evaluates the individual variability in response, and suggests practical strategies to balance these competing priorities in athletic populations.
Study Design and Methodology
A comprehensive review of the literature was conducted via systematic searches in PubMed, Web of Science, and SPORTDiscus, focusing on studies that examined caffeine intake’s effects on athletes’ sleep parameters and sports performance. The inclusion criteria encompassed studies analyzing acute caffeine ingestion, its impact on performance and sleep quality metrics, and excluded recreational athletes, pediatric populations, and animal models. Both original research articles and reviews were considered to provide a broad but focused synthesis.
Key Findings
Ergogenic Effects of Caffeine
Evidence robustly supports caffeine’s role in enhancing physical performance through central nervous system stimulation via adenosine receptor antagonism—primarily A1 and A2A receptors—leading to increased excitatory neurotransmitter release (dopamine, noradrenaline). This mechanism reduces perceived exertion and delay fatigue, as demonstrated by improved performance in endurance and high-intensity sports, including cycling, running, rugby, volleyball, and combat sports.
Caffeine improves several performance domains:
– Increased time-to-exhaustion in aerobic tasks
– Enhanced muscle strength and power output
– Improved anaerobic performance and sprinting ability
– Enhanced cognitive function including attention and reaction time
The ergogenic window is typically 3–6 mg/kg ingested 30–60 minutes pre-exercise. Various sources such as capsules, gums, coffee, and energy drinks are effective, though rate of absorption may vary (e.g., gum is absorbed faster).
Variability in Response
Interindividual differences in caffeine metabolism and sensitivity significantly affect both ergogenic effects and sleep disturbances. Genetic polymorphisms in CYP1A2 (key enzyme in caffeine metabolism) and ADORA2A (adenosine receptor gene) have been studied. For instance, CYP1A2 AA genotype individuals may metabolize caffeine faster than C-allele carriers; however, the link between genotype and performance response is inconsistent. ADORA2A polymorphisms may influence caffeine’s sleep-disruptive effects.
Habitual caffeine consumption presents further complexity. While tolerance to some effects of caffeine develops over time, studies suggest that acute performance benefits generally persist even in high habitual consumers, although attenuation may occur with chronic use.
Caffeine’s Impact on Sleep Quality
Caffeine’s stimulant properties, while beneficial during exercise, extend into the post-exercise period and may impair sleep quality by increasing sleep latency, reducing total sleep time, and decreasing sleep efficiency.
Research, including studies in professional athletes, demonstrates that caffeine ingestion within 5–6 hours of bedtime significantly disrupts sleep, leading to reduced recovery and potential decrements in subsequent performance and well-being.
Nighttime competitions and late training sessions compounded by exposure to bright light and post-competition arousal further impair sleep, exacerbated by caffeine’s half-life of 4–10 hours.
Balancing Caffeine Use and Sleep
A clear conflict exists between the recommended ergogenic caffeine use (typically within 1 hour pre-exercise) and sleep hygiene recommendations (avoid caffeine several hours before sleep). Individual factors such as genetic makeup, habitual intake, anxiety levels, and competition timing are critical determinants in managing this balance.
Some strategies include:
– Individualized assessment via simulated competitions measuring both performance and sleep outcomes
– Adjusted dosing: using the lowest effective dose to minimize side effects
– Timing: avoiding caffeine intake within 5–6 hours of bedtime
– Alternative caffeine sources with faster pharmacokinetics (e.g., gum) to narrow the window of exposure
– Implementation of comprehensive sleep hygiene practices such as regular sleep schedules, minimizing electronic device use before bedtime, and controlled light exposure.
Practical Recommendations
Sports practitioners should:
1. Recognize and evaluate individual variability in caffeine sensitivity and sleep response.
2. Avoid routine caffeine consumption to prevent tolerance which might reduce ergogenic benefits.
3. Perform athlete-specific testing to determine optimal caffeine dose and timing.
4. Prefer caffeine sources allowing controlled dosing and absorption rates.
5. Limit caffeine use to events scheduled well before usual bedtime.
6. Monitor sleep quality objectively (when feasible) or subjectively using validated questionnaires.
7. Employ sleep hygiene guidelines to enhance recovery and reduce dependency on stimulants.
Expert Commentary
The contrasting requirements of caffeine’s performance benefits and sleep preservation highlight the complexity of nutritional strategies in elite sports. Sleep quality is paramount not only for recovery but for cognitive and physical readiness in subsequent competitions. The evolving understanding of genetic influences on caffeine metabolism and sleep disruption underscores the importance of personalized nutrition. Current limitations include variable protocols in studies and limited controlled trials specifically targeting evening competitions.
Further research is needed to delineate precise genotype-phenotype interactions and to develop tailored protocols integrating caffeine use and sleep management.
Conclusion
Caffeine remains a potent ergogenic aid widely used among athletes but poses a significant risk for impaired sleep quality, particularly when consumed near bedtime or prior to evening competitions. Given the critical role of sleep in recovery and performance, individualized strategies incorporating genetic, habitual, and contextual factors are essential to balance caffeine’s benefits against its detriments. Practitioners should employ personalized assessment and monitoring, adopting the lowest effective caffeine doses, optimized timing, and comprehensive sleep hygiene to maximize athletic performance and well-being.
References
Silva H, Del Coso J, Pickering C. Caffeine and Sports Performance: The Conflict between Caffeine Intake to Enhance Performance and Avoiding Caffeine to Ensure Sleep Quality. Sports Med. 2025 Jul;55(7):1579-1592. doi: 10.1007/s40279-025-02245-y IF: 9.4 Q1 . Epub 2025 Jun 27. PMID: 40579619 IF: 9.4 Q1 ; PMCID: PMC12296924 IF: 9.4 Q1 .
