Linda Geddes
I’ve made a cup of coffee, written my to-do list and now I’m wiring up my ear to a device that will send an electrical message to my brainstem. If the testimonials are to believed, incorporating this stimulating habit into my daily routine could help to reduce stress and anxiety, curb inflammation and digestive issues, and perhaps improve my sleep and concentration by tapping into the “electrical superhighway” that is the vagus nerve.
From plunging your face into icy water, to piercing the small flap of cartilage in front of your ear, the internet is awash with tips for hacking this system that carries signals between the brain and chest and abdominal organs.
Manufacturers and retailers are also increasingly cashing in on this trend, with Amazon alone offering hundreds of vagus nerve products, ranging from books and vibrating pendants to electrical stimulators similar to the one I’ve been testing.
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Meanwhile, scientific interest in vagus nerve stimulation is exploding, with studies investigating it as a potential treatment for everything from obesity to depression, arthritis and Covid-related fatigue. So, what exactly is the vagus nerve, and is all this hype warranted?
The vagus nerve is, in fact, a pair of nerves that serve as a two-way communication channel between the brain and the heart, lungs and abdominal organs, plus structures such as the oesophagus and voice box, helping to control involuntary processes, including breathing, heart rate, digestion and immune responses. They are also an important part of the parasympathetic nervous system, which governs the “rest and digest” processes, and relaxes the body after periods of stress or danger that activate our sympathetic “fight or flight” responses.
In the late 19th century, scientists observed that compressing the main artery in the neck – alongside which the vagus nerves run – could help to prevent or treat epilepsy. This idea was resurrected in the 1980s, when the first electrical stimulators were implanted into the necks of epilepsy patients, helping to calm down the irregular electrical brain activity that triggers seizures.
As more people were fitted with these devices, doctors began to spot an interesting pattern. “They noticed that even if the device didn’t help their epilepsy, some of these patients started to have a better outlook on life,” says Kevin Tracey, a professor of molecular medicine and neurosurgery at the Feinstein Institutes for Medical Research in Manhasset, New York.
A medical illustration from Atlas and Text-book of Human Anatomy by Dr Johannes Sobotta, published in 1911. Photograph: VintageMedStock/Getty Images
Today, vagus nerve stimulators are increasingly being investigated as an alternative to antidepressants in patients with treatment-resistant depression. Surgically implanted stimulators are also an approved treatment for epilepsy – although they only seem to work in a subset of patients.
Using electrical stimulation to treat brain disorders such as epilepsy and depression makes intuitive sense – nerves and brain cells communicate using electricity, after all.
However, in the late 1990s, Tracey and his colleagues made a surprising discovery. They were testing an experimental drug that they expected to dampen inflammation in rats’ brains, but when they injected it, it dampened inflammation throughout the body.
This was puzzling, because the brain is physically separated from the rest of the body by the blood-brain barrier – a tightly packed layer of cells that regulates the passage of large and small molecules into the brain, to help keep it safe. Tracey and his colleagues tried severing the vagus nerve and repeated the experiment. This time, the drug’s anti-inflammatory effects were confined to the brain.
It was an extraordinary discovery: conventional wisdom held that there was no connection between the nervous and immune systems – but the vagus nerve appeared to provide that link. Further research revealed that the brain communicates with the spleen – an organ that plays a critical role in the immune system – by sending electrical signals down the vagus nerve. These trigger the release of a chemical called acetylcholine that tells immune cells to switch off inflammation. Electrically stimulating the vagus nerve with an implanted device achieved the same feat.
Tracey immediately recognised the therapeutic implications, having spent years trying to develop better treatments for inflammatory conditions such as sepsis, arthritis and Crohn’s disease. Existing drugs dampen inflammation, but carry a risk of serious side effects. Here was a technique with the potential to switch off inflammation without the need for drugs.
Tracey’s discovery also caught the attention of mind-body practitioners, including the Dutch motivational speaker and “Iceman” Wim Hof, who claimed that he could control inflammation in his body through a combination of breath work, meditation and cold water immersion. “He wanted me to study him,” Tracey says.
They devised an experiment that involved drawing blood from Hof before and after practising his techniques, and analysing them for markers of inflammation. To their surprise, it seemed Hof really could reduce inflammation in his body, although they required more evidence to be convinced his techniques would work in others.
Picking up the baton, Matthijs Kox at Radboud University Medical Center in the Netherlands recruited 12 volunteers to attend Hof’s training camp in Poland, where they spent 10 days swimming in icy water, rolling around in snow, meditating and learning his breathing exercises – which are characterised by a period of forced hyperventilation followed by a period of holding your breath.
Afterwards, the researchers tested the volunteers’ ability to suppress their immune responses by injecting them with a component of bacteria that triggers inflammation and flu-like symptoms. Compared with volunteers who had not undergone Hof’s training, their levels of inflammation were lower and they experienced fewer flu-like symptoms.
But were they really hacking their immune systems by tapping into the power of their vagus nerve? Yes and no. Although the volunteers were able to dampen inflammation, they released large amounts of adrenaline in the process – a key component of the fight or flight response. “This is pretty much the opposite of what you’d expect if Hof’s techniques were working through the vagus nerve,” says Kox.
Adrenaline also suppresses the immune system, but through a different mechanism. And Kox warns that repeatedly triggering these fight or flight responses could be dangerous for people with cardiovascular conditions.
Hof’s aren’t the only techniques being espoused as ways to regulate anxiety, depression and improve general health by tapping into the vagus nerve.
Search “vagus nerve hacks” on TikTok, and you’ll be bombarded with tips ranging from humming in a low voice to twisting your neck and rolling your eyes, to practising yoga or meditation exercises.
Researchers who study the vagus nerve are broadly sceptical of such claims. Though such techniques may help you to feel calmer and happier by activating the autonomic nervous system, the vagus nerve is only one component of that. “If your heart rate slows, then your vagus nerve is being stimulated,” says Tracey. “However, the nerve fibres that slow your heart rate may not be the same fibres that control your inflammation. It may also depend on whether your vagus nerves are healthy.”
Similarly, immersing your face in cold water may also slow down your heart rate by triggering something called the mammalian dive reflex, which also triggers breath-holding and diverts blood from the limbs to the core. This may serve to protect us from drowning by conserving oxygen, but it involves sympathetic and parasympathetic responses.
Electrical stimulation may hold greater promise though. One thing that makes the vagus nerves so attractive is surgical accessibility in the neck. “It is quite easy to implant some device that will try to stimulate them,” says Dr Benjamin Metcalfe at the University of Bath, who is studying how the body responds to electrical vagus nerve stimulation. “The other reason they’re attractive is because they connect to so many different organ systems. There is a growing body of evidence to suggest that vagus nerve stimulation will treat a wide range of diseases and disorders – everything from rheumatoid arthritis through to depression and alcoholism.”
In 2016, Tracey and his colleagues published the results of a study of 18 patients with rheumatoid arthritis – an autoimmune condition that causes pain, swelling and stiffness in joints – who were still experiencing symptoms despite taking immunosuppressive drugs. The patients were fitted with a vagus nerve stimulator that was used to target the fibres in their necks that are thought to control immune activity in the spleen. This led to an improvement in their symptoms and was associated with reduced levels of tumor necrosis factor, an inflammatory protein that is a leading target of drugs for rheumatoid arthritis.
Preliminary data also suggests that the technology might be effective in patients with Crohn’s disease, another inflammatory condition, which affects the digestive system.
In all of the medical conditions discussed so far, the device is implanted into the patient’s neck, where it provides regular bursts of stimulation, with different frequencies blocking or activating different nerve fibres. Although this is relatively safe, some patients do experience side effects such as fatigue or headaches.
But there may be alternative ways of stimulating the vagus nerve. Prof Chris Toumazou at Imperial College London and his colleagues are investigating whether a microstimulator could be attached to a specific branch of the vagus nerve that tells the brain when the stomach is full or empty. This idea stems from the discovery that the hormones controlling appetite communicate with the brain via the vagus nerve. Cut the nerve, and these hunger signals no longer get through.
The team has been working on a device that could eavesdrop on this chemical chatter, and send an electrical signal to the brain in response to the release of hunger hormones by an empty stomach. “The device will be able to send an opposite signal to the brain to say: ‘No, you’re full,’” Toumazou says. “We’re not completely cutting those signals off, but controlling them, which could be a much better means of obesity control than a stomach bypass.”
The device that I’ve been clipping to my ear, called a Nurosym, could provide an alternative means of stimulating the vagus nerve, and, unlike implanted stimulators, does not require surgery.
As well as organs and structures in the chest and abdomen, there’s a branch of the vagus nerve that terminates at the outer ear, known as the auricular branch.
“It projects to the brainstem and then to different regions of the brain, and that leads to vagal signalling that projects down to the heart and other organs,” says Nathan Dundovic, co-founder of London-based neurotechnology company Parasym, which develops and manufactures the Nurosym device.
Although this is primarily a medical device designed for patients with chronic health conditions that affect involuntary processes such as heart rate or digestion, Dundovic believes that healthy individuals like me may also benefit from auricular stimulation – albeit to a lesser extent.
Many of the company’s employees use the device to promote relaxation and sleep, and to potentially reap some of the cognitive enhancing effects that early clinical studies have hinted at – such as improvements in short-term memory.
Clipping the device to my tragus, the fleshy chunk of cartilage in front of my ear, I feel a gentle pulsating prickle when it is switched on. I can’t claim to have been transformed into a hyper-efficient, calmer version of myself – yet – but I’m willing to persist and see.
Not everyone is convinced that this kind of auricular vagus nerve stimulation will be clinically effective. “Because the vagus connects to so many different organ systems, it can still be a challenge sometimes to make sure that we are only stimulating the right part of the nerve,” says Metcalfe. “The idea that you can place electrodes completely outside the body and still selectively stimulate nerve fibres, I find that very hard to believe.”
However, Parasym’s device is currently being tested in trials for various heart and brain-related disorders, including postural orthostatic tachycardia syndrome (Pots) – a condition characterised by an abnormal increase in heart rate upon standing – and long Covid, by reputable research institutions across North America and Europe.
The idea that auricular stimulation could benefit long Covid patients is being investigated by other teams as well. Already, there is some evidence to suggest that it may help to alleviate the fatigue associated with an autoimmune disease called Sjögren’s Syndrome.
Encouraged by such findings, Dr Mark Baker at Newcastle University is now exploring whether it could also benefit patients with post-Covid fatigue.
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