Your 24-hour circadian rhythm is the primary factor that determines your sleep and wake cycle. Alongside your circadian rhythm is a complementary sleep pressure system in your brain. This system is especially susceptible to being disrupted by caffeine.
If you want to keep your sleep cycles on track, it’s a good idea to understand how your genes, gender, diet, and dosage all impact how your body processes caffeine.
Caffeine Delays Sleep
Caffeine tricks your brain into thinking it’s not tired by blocking your sleepiness signal, adenosine. Adenosine is a brain molecule (neurotransmitter) that helps register elapsed time.
The longer you are awake, the more adenosine will accumulate in your brain, creating pressure to sleep. Sleep wipes the slate, resetting your adenosine levels.
Caffeine has a unique ability to disrupt this signal by transitioning from your blood into your brain—crossing a difficult border known as the blood-brain barrier.
Without caffeine, adenosine binds to receptors that send sleepiness signals throughout your body. However, if caffeine enters the brain, it fits in the same receptors and blocks adenosine from binding.
When adenosine receptors can’t fire, your brain falsely registers that it has been awake for a shorter period of time, making you feel more alert.
When caffeine leaves your system you experience a crash because all your adenosine has been building up and binds all at once. This experience can vary by person, as caffeine is cleared from your system at different rates.
Caffeine Has Lasting Effects
Caffeine doesn’t last forever—it has a half life of 5 to 7 hours, which means it takes that many hours to break down half of the caffeine in your system.
For example, if you have a cup of coffee at 3 p.m., by 8 p.m. you have only metabolized half of that caffeine—the other half is still in your system.
However, half the population may have a gene that leads to slower processing of caffeine, meaning the half life is even longer. Caffeine is metabolized by a particular enzyme in your liver, determined by your genes. Fifty percent of the population may have a variant in this gene—CYP1A2—that makes them a slow vs. fast metabolizer. You can often find this data through one of the many direct-to-consumer genetic testing companies (e.g, 23andMe).
Other factors, such as hormones, may also impact how you break down caffeine. Women using hormonal birth control, for example, have an extended half life for caffeine, meaning it stays in their system for much longer.
Things to Keep in Mind
When caffeine is in your system, it activates your nervous system and increases your resting heart rate (RHR). This can interfere with your ability to wind down before bed and may be evident in your RHR pattern as you sleep.
You might also see these patterns on days when caffeine is still in your system at bedtime:
- higher average RHR throughout
- delay in RHR reaching its lowest point
- higher restlessness
- increased time spent awake
Try observing how caffeine impacts you and keep in mind that soda, tea, medication, and even chocolate can contain enough caffeine to disrupt your sleep.
- Patwardhan, Rashmi V., Paul V. Desmond, Raymond F. Johnson, and Steven Schenker. “Impaired elimination of caffeine by oral contraceptive steroids.” The Journal of laboratory and clinical medicine 95, no. 4 (1980): 603-608. (link)
- Ribeiro-Alves, M. A., Trugo, L. C., & Donangelo, C. M. (2003). Use of oral contraceptives blunts the calciuric effect of caffeine in young adult women. The Journal of nutrition, 133(2), 393-398.
- Walker, M. (2017). Why we sleep: Unlocking the power of sleep and dreams. Simon and Schuster.
- Yang, A., Palmer, A. A., & de Wit, H. (2010). Genetics of caffeine consumption and responses to caffeine. Psychopharmacology, 211(3), 245-257.
Cornelis, M. C., El-Sohemy, A., Kabagambe, E. K., & Campos, H. (2006). Coffee, CYP1A2 genotype, and risk of myocardial infarction. Jama, 295(10), 1135-1141.