Health
The ‘runner’s high’ may result from molecules called cannabinoids – the body’s own version of THC and CBD
Many people have experienced reductions in stress, pain and anxiety and sometimes even euphoria after exercise. What’s behind this so-called “runner’s high”? New research on the neuroscience of exercise may surprise you.
The “runner’s high” has long been attributed to endorphins. These are chemicals produced naturally in the body of humans and other animals after exercise and in response to pain or stress.
However, new research from my lab summarizes nearly two decades of work on this topic. We found that exercise reliably increases levels of the body’s endocannabinoids – which are molecules that work to maintain balance in the brain and body – a process called “homeostasis.” This natural chemical boost may better explain some of the beneficial effects of exercise on brain and body.
I am a neuroscientist at the Wayne State University School of Medicine. My lab studies brain development and mental health, as well as the role of the endocannabinoid system in stress regulation and anxiety disorders in children and adolescents.
This research has implications for everyone who exercises with the aim of reducing stress and should serve as a motivator for those who don’t regularly exercise.
Health benefits of exercise
Several decades of research has shown that exercise is beneficial for physical health. These studies find a consistent link between varying amounts of physical activity and reduced risk of premature death and dozens of chronic health conditions, including diabetes, hypertension, cancer and heart disease.
More recently – over about the past two decades – mounting research shows that exercise is also highly beneficial for mental health. In fact, regular exercise is associated with lower symptoms of anxiety, depression, Parkinson’s disease and other common mental health or neurological problems. Consistent exercise is also linked to better cognitive performance, improved mood, lower stress and higher self-esteem.
It is not yet clear what is behind these mental health boosts. We do know that exercise has a variety of effects on the brain, including raising metabolism and blood flow, promoting the formation of new brain cells – a process called neurogenesis – and increasing the release of several chemicals in the brain.
Some of these chemicals are called neurotrophic factors, such as brain-derived neurotrophic factor. BDNF is intricately involved in brain “plasticity,” or changes in activity of brain cells, including those related to learning and memory.
Scientists have also shown that exercise increases blood levels of endorphins, one of the body’s natural opioids. Opioids are chemicals that work in the brain and have a variety of effects, including helping to relieve pain. Some early research in the 1980s contributed to the long-standing popular belief that this endorphin release is related to the euphoric feeling known as the runner’s high.
However, scientists have long questioned the role of endorphins in the runner’s high sensation, in part because endorphins cannot cross into the brain through the blood-brain barrier, which protects the brain from toxins and pathogens. So endorphins are not likely to be the main driver for the beneficial effects of exercise on mood and mental state.
This is where our research and that of others points to the role of our body’s natural versions of cannabinoids, called endocannabinoids.
The surprising role of endocannabinoids
You may be familiar with cannabinoids such as tetrahydrocannabinol – better known as THC – the psychoactive compound in cannabis (from the Cannabis sativa L. plant) that causes people to feel high. Or you may have heard of cannabidiol, commonly known as CBD, an extract of cannabis that is infused in some foods, medicines, oils and many other products.
But many people do not realize that humans also create their own versions of these chemicals, called endocannabinoids. These are tiny molecules made of lipids – or fats – that circulate in the brain and body; “endo” refers to those produced in the body rather than from a plant or in a lab.
Endocannabinoids work on cannabinoid receptors throughout the brain and body. They cause a variety of effects, including pain relief, reduction of anxiety and stress and enhanced learning and memory. They also affect hunger, inflammation and immune functioning. Endocannabinoid levels can be influenced by food, time of day, exercise, obesity, injury, inflammation and stress.
It’s worth noting that one should not be tempted to forgo a run or bike ride and resort to smoking or ingesting cannabis instead. Endocannabinoids lack the unwanted effects that come with getting high, such as mental impairment.
Understanding the runner’s high
Studies in humans and in animal models are pointing to endocannabinoids – not endorphins – as the star players in the runner’s high.
These elegant studies demonstrate that when opioid receptors are blocked – in one example by a drug called naltrexone – people still experienced euphoria and reduced pain and anxiety after exercise. On the flip side, the studies showed that blocking the effects of cannabinoid receptors reduced the beneficial effects of exercise on euphoria, pain and anxiety.
While several studies have shown that exercise increases the levels of endocannabinoids circulating in the blood, some have reported inconsistent findings, or that different endocannabinoids produce varying effects. We also don’t know yet if all types of exercise, such as cycling, running or resistance exercise like weightlifting, produce similar results. And it is an open question whether people with and without preexisting health conditions like depression, PTSD or fibromyalgia experience the same endocannabinoid boosts.
To address these questions, an undergraduate student in my lab, Shreya Desai, led a systematic review and meta-analysis of 33 published studies on the impact of exercise on endocannabinoid levels. We compared the effects of an “acute” exercise session – like going for a 30-minute run or cycle – with the effects of “chronic” programs, such as a 10-week running or weightlifting program. We separated them out because different levels and patterns of exertion could have very distinct effects on endocannabinoid responses.
We found that acute exercise consistently boosted endocannabinoid levels across studies. The effects were most consistent for a chemical messenger known as anandamide – the so-called “bliss” molecule, which was named, in part, for its positive effects on mood.
Interestingly, we observed this exercise-related boost in endocannabinoids across different types of exercise, including running, swimming and weightlifting, and across individuals with and without preexisting health conditions. Although only a few studies looked at intensity and duration of exercise, it appears that moderate levels of exercise intensity – such as cycling or running – are more effective than lower-intensity exercise – like walking at slow speeds or low incline – when it comes to raising endocannabinoid levels. This suggests that it is important to keep your heart rate elevated – that is, between about 70% and 80% of age-adjusted maximum heart rate – for at least 30 minutes to reap the full benefits.
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There are still a lot of questions about the links between endocannabinoids and beneficial effects from exercise. For example, we didn’t see consistent effects for how a chronic exercise regimen, such as a six-week cycling program, might affect resting endocannabinoid levels. Likewise, it isn’t yet clear what the minimum amount of exercise is to get a boost in endocannabinoids, and how long these compounds remain elevated after acute exercise.
Despite these open questions, these findings bring researchers one step closer to understanding how exercise benefits brain and body. And they offer an important motivator for making time for exercise during the rush of the holidays.
Hilary A. Marusak, Assistant Professor of Psychiatry and Behavioral Neurosciences, Wayne State University
This article is republished from The Conversation under a Creative Commons license. Read the original article.
Hilary A. Marusak, Wayne State University
