Acupuncture for Rheumatoid Arthritis and Inflammation

/ Reset Wellness Ltd/

The Evidence is Promising

Poking needles under your skin doesn’t exactly sound soothing, but some people swear by the use of acupuncture for their rheumatoid arthritis (RA). Such anecdotal evidence suggests this therapy might be effective in relieving RA discomfort. Yet with few good-quality studies available, proving acupuncture’s safety and benefit has been a challenge.

Many reviews of studies done so far have not found a statistically significant benefit on pain, swollen joints or other measures of disease when compared to a control treatment. Many of the studies that did find positive outcomes weren’t well conducted. Yet there has been enough potential noted for this therapy that researchers say it warrants further study.

Acupuncture’s Effect on Inflammatory Markers

Acupuncture involves inserting tiny needles into a person’s skin. A version known as electro-acupuncture adds a mild electric current. The needles are inserted at some of the 2,000 mapped points along what are called meridians or channels.In Chinese terms, acupuncture restores the optimal flow of energy – called Qi (pronounced chee) – in the body.

In a 2011 Chinese study looking at electro-acupuncture and traditional acupuncture, both significantly lowered tumor necrosis factor-α (TNF-α) and vascular endothelial growth factor (VEGF). “Both TNF-α and VEGF are associated with chronic inflammation,” explains Nathan Wei, MD, director of the arthritis treatment center in Frederick, Md. “In particular, TNF-α appears to play a pivotal role in the chronic inflammation and joint destruction that characterizes RA. That’s why so many of the biologic medications target TNF-α.”

In a 2008 Arthritis & Rheumatism review of eight acupuncture studies involving a total of 536 patients with RA, five studies reported a reduction in erythrocyte sedimentation rate (ESR), three saw a reduction in C-reactive protein (CRP), and one study described a significant drop in both. Both ESR and CRP are markers of inflammation in the body. Several of the studies also reported decreased pain and a reduction in morning stiffness.

How acupuncture affects inflammatory markers like TNF-α is unknown. “No one has figured out one single mechanism for acupuncture’s effects,” says Jeffrey I. Gold, PhD, director of the pediatric pain management clinic at Children’s Hospital in Los Angeles.

Gold explains that MRI studies show that acupuncture sites specifically induce responses in various portions of the brain. Acupuncture can possibly effect any organ or system: immunological, neurological, hormonal and psychological. “It doesn’t only block pain signals,” he says.

Experts do know that acupuncture relieves pain by stimulating the release of endorphins, the body’s own natural painkillers, says Jamie Starkey, lead acupuncturist for the Tanya I. Edwards, MD Center for Integrative and Lifestyle Medicine at Cleveland Clinic. “We’re activating the peripheral nervous system, which then activates the central nervous system, so that the brain begins to release endorphins.” Acupuncture may relieve pain locally, she says, by not only releasing neurotransmitters, but also by having an anti-inflammatory effect. “How exactly it happens, we are still researching.”

Taking the Acupuncture Route

“The more studies that come in showing the drop in inflammatory markers through acupuncture treatments, the more rheumatologists will take note,” says Starkey. In a 2010 Mayo Clinic survey, 54% of rheumatologists said they would recommend acupuncture as an adjunct treatment. 

Here are some things to consider if you’re thinking of jumping on the acupuncture bandwagon:

Choose Carefully

“Find an acupuncturist who comes highly recommended by your rheumatologist or physician, family friends, and colleagues so you know firsthand what their experience was like,” says Starkey. If you don’t know anyone to ask, search The National Certification Commission for Acupuncture website for a certified clinician in your area. 

Acupuncturists have to be licensed by their state medical board, so you can check there as well. “Ideally, try to find someone who has experience working with RA patients,” says Starkey.  

Know What’s Covered

Some insurance companies cover acupuncture for certain diagnoses, but others do not. Prices for acupuncture vary, depending on your area and can run $75 to $200 per treatment.

Expect Several Treatments

“We tend to see substantial results within three to six treatments,” says Dr. Gold. But each patient responds differently and treatments vary depending on the stage of the disease.

Understand the Limit

Acupuncture doesn’t work on everyone, says Starkey. “In my clinical work, we see a 20% non-response rate.” But,acupuncture has many styles and practitioners. “If it doesn’t work right away, don’t dismiss the whole field of acupuncture,” says Dr. Gold. “Try a different style.”

 

This article originally appeared on arthritis.org and was written by Dorothy Foltz-Gray


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What is Tendonitis?

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Tendonitis or its aliases: tendinitis, tendinopathy and tendinosis are all tendon injuries. 

Tendinopathy (tendon injuries) can develop in any tendon of the body.

Typically, tendon injuries occur in three areas:

  • musculotendinous junction (where the tendon joins the muscle)
  • mid-tendon (non-insertional tendinopathy)
  • tendon insertion (eg into bone)

Non-insertional tendinopathies tend to be caused by a cumulative microtrauma from repetitive overloading eg overtraining.

What is a Tendon Injury? 

Tendons are the tough fibres that connect muscle to bone. Most tendon injuries occur near joints, such as the shoulder, elbow, knee, and ankle. A tendon injury may seem to happen suddenly, but usually it is the result of repetitive tendon overloading. Health professionals may use different terms to describe a tendon injury. You may hear:

Tendinitis (or Tendonitis): This actually means "inflammation of the tendon," but inflammation is actually only a very rare cause of tendon pain. But many doctors may still use the term tendinitis out of habit.

The most common form of tendinopathy is tendinosis. Tendinosis is a noninflammatory degenerative condition that is characterised by collagen degeneration in the tendon due to repetitive overloading. These tendinopathies therefore do not respond well to anti-inflammatory treatments and are best treated with functional rehabilitation. The best results occur with early diagnosis and intervention.

What Causes a Tendon Injury?

Most tendon injuries are the result of gradual wear and tear to the tendon from overuse or ageing. Anyone can have a tendon injury, but people who make the same motions over and over in their jobs, sports, or daily activities are more likely to damage a tendon.

Your tendons are designed to withstand high, repetitive loading, however, on occasions, when the load being applied to the tendon is too great for the tendon to withstand, the tendon begins to become stressed.

When tendons become stressed, they sustain small micro tears, which encourage inflammatory chemicals and swelling, which can quickly heal if managed appropriately.

However, if the load is continually applied to the tendon, these lesions occurring in the tendon can exceed the rate of repair. The damage will progressively become worse, causing pain and dysfunction. The result is a tendinopathy or tendinosis.

Researchers current opinion implicates the cumulative microtrauma associated with high tensile and compressive forces generated during sport or an activity causes a tendinopathy.

For example, in explosive jumping movements, forces delivered to the patellar tendon can be eight times your body weight. Cumulative microtrauma appears to exceed the tendon’s capacity to heal and remodel.

What are the Symptoms of Tendinopathy?

Tendinopathy usually causes pain, stiffness, and loss of strength in the affected area.

  • The pain may get worse when you use the tendon.
  • You may have more pain and stiffness during the night or when you get up in the morning.
  • The area may be tender, red, warm, or swollen if there is inflammation.
  • You may notice a crunchy sound or feeling when you use the tendon.

The symptoms of a tendon injury can be a lot like those caused by bursitis.

Tendinopathy Phases

The inability of your tendon to adapt to the load quickly enough causes tendon to progress through four phases of tendon injury. While it is healthy for normal tissue adaptation during phase one, further progression can lead to tendon cell death and subsequent tendon rupture.

1. Reactive Tendinopathy

  • Normal tissue adaptation phase
  • Prognosis: Excellent. Normal Recovery!

2. Tendon Dysrepair

  • Injury rate > Repair rate
  • Prognosis: Good. Tissue is attempting to heal.
  • It is vital that you prevent deterioration and progression to permanent cell death (phase 3).

3. Degenerative Tendinopathy

  • Cell death occurs
  • Poor Prognosis - Tendon cells are giving up!

4. Tendon Tear or Rupture

  • Catastrophic tissue breakdown
  • Loss of function.
  • Prognosis: very poor.
  • Surgery is often the only option.

It is very important to have your tendinopathy professionally assessed to identify it’s injury phase. Identifying your tendinopathy phase is also vital to direct your most effective treatment, since certain modalities or exercises should only be applied or undertaken in specific tendon healing phases.

How is a Tendon Injury Diagnosed?

To diagnose a tendon injury, your physiotherapist will ask questions about your past health, your symptoms and exercise regime. They'll then do a physical examination to confirm the diagnosis. If your symptoms are severe or you do not improve with early treatment, specific diagnostic tests may be requested, such as an ultrasound scan or MRI.

How is Tendinopathy Treated?

In most cases, you can start treating a tendon injury at home. To get the best results, start these steps right away:

  • Rest the painful area, and avoid any activity that makes the pain worse.
  • Apply ice or cold packs for 20 minutes at a time, as often as 2 times an hour, for the first 72 hours. Keep using ice as long as it helps.
  • Do gentle range-of-motion exercises and stretching to prevent stiffness.
  • Have your biomechanics assessed by a sports physiotherapist.
  • Undertake an Eccentric Strengthen Program. This is vital!

How to Return to Sport

It may take weeks or months for a tendon injury to heal. Be patient, and stick with your treatment. If you start using the injured tendon too soon, it can lead to more damage.

To keep from hurting your tendon again, you may need to make some long-term changes to your activities. These should be discussed with your physiotherapist.

  • Try changing your activities or how you do them.
  • If exercise caused the problem, check your technique with a coach or sports physiotherapist.
  • Perform regular eccentric style exercises.
  • Closely monitor and record your exercise loads. Discuss your loading with your physiotherapist and coach.
  • Always take time to warm up before and cool down / stretch after you exercise.
     

This article originally appeared on physioworks.com.au and was written by Zoe Russell.

Depression is a physical illness which could be treated with anti-inflammatory drugs, scientists suggest

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Depression could be treated using anti-inflammatory drugs, scientists now believe, after determining that it is a physical illness caused by a faulty immune system.

Around one in 13 people in Britain suffers from anxiety or depression and last year the NHS issued 64.7 million prescriptions for antidepressants, double the amount given out a decade ago.

Current treatment is largely centred around restoring mood-boosting chemicals in the brain, such as serotonin, but experts now think an overactive immune system triggers inflammation throughout the entire body, sparking feelings of hopelessness, unhappiness and fatigue. 

It may be a symptom of the immune system failing to switch off after a trauma or illness, and is a similar to the low mood people often experience when they are fighting a virus, like flu.

A raft of recent papers, and unexpected results from clinical trials, have shown that treating inflammation seems to alleviate depression.

Likewise when doctors give drugs to boost the immune system to fight illness it is often accompanied by depressive mood - in the same way as how many people feel down after a vaccination.

Professor Ed Bullmore, Head of the Department of Psychiatry at the University of Cambridge, believes a new field of ‘immuno-neurology’ is on the horizon.

“It’s pretty clear that inflammation can cause depression,” he told a briefing in London to coincide with this week’s Academy of Medical Sciences FORUM annual lecture which has brought together government the NHS and academics to discuss the issue.

“In relation to mood, beyond reasonable doubt, there is a very robust association between inflammation and depressive symptoms.  We give people a vaccination and they will become depressed. Vaccine clinics could always predict it, but they could never explain it.

“The question is does the inflammation drive the depression or vice versa or is it just a coincidence?

“In experimental medicine studies if you treat a healthy individual with an inflammatory drug, like interferon, a substantial percentage of those people will become depressed. So we think there is good enough evidence for a causal effect.”

Scientists at Cambridge and the Wellcome Trust are hoping to begin trials next year to test whether anti-inflammatory drugs could switch off depression.

“There is evidence to suggest it should work,” added Prof Bullmore.

The immune system triggers an inflammatory response when it feels it is under threat, sparking wide-ranging changes in the body such as increasing red blood cells, in anticipation that it may need to heal a wound soon.

Scientists believe that associated depression may have brought an evolutionary benefit to our ancestors. If an ill or wounded tribal member became depressed and withdrawn it would prevent a disease being passed on.

However a link has taken so long to establish because until recently scientists believed the brain was entirely cut off from the immune system, trapped behind a ‘Berlin Wall’ known as the blood brain barrier.

But recent studies have shown that nerve cells in the brain are linked to immune function and one can have an impact on the other. Around 60 per cent of people referred to cardiologists with chest pain do not have a heart problem but are suffering from anxiety.

One in 13 people in Britain suffers from depression CREDIT: ANNA GOWTHORPE 

Figures also show that around 30 per cent of people suffering from inflammatory diseases such as rheumatoid arthritis are depressed - more than four times higher than the normal population.

Likewise people who are depressed after a heart attack are much more likely to suffer a second one, while the lifespan for people withcancer is hugely reduced for people with mental illness.

“You can’t separate the mind from the body,” said Prof Sir Robert Lechler, President of the Academy of Medical Sciences.

“The immune system does produce behaviour. You’re not just a little bit miserable if you’ve got a long term condition, there is a real mechanistic connection between the mind, the nervous system and the immune system.

“Our model of healthcare is outdated. We have a separation. Mental healthcare is delivered by mental health professionals, psychiatrists, mental health nurses and so on, often in separate premises from where physical health care is delivered and that is simply wrong and we need to find ways to ever more closely integrate and train amphibious healthcare professionals who can straddle this divide.”

Research has also shown that people who have suffered severe emotional trauma in their past have inflammatory markers in their body, suggesting their immune system is constantly firing, as if always on guard against abuse.

This article originally appeared on www.telegraph.co.uk and was written by Sarah Knapton.

Photo by: Photo by Nik Shuliahin on Unsplash

Hacking the Nervous System - Learning to Control One Nerve

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Shaping your health by learning to control the one nerve that connects your vital organs

When Maria Vrind, a former gymnast from Volendam in the Netherlands, found that the only way she could put her socks on in the morning was to lie on her back with her feet in the air, she had to accept that things had reached a crisis point. “I had become so stiff I couldn’t stand up,” she says. “It was a great shock because I’m such an active person.”

It was 1993. Vrind was in her late 40s and working two jobs, athletics coach and a carer for disabled people, but her condition now began taking over her life. “I had to stop my jobs and look for another one as I became increasingly disabled myself.” By the time she was diagnosed, seven years later, she was in severe pain and couldn’t walk any more. Her knees, ankles, wrists, elbows and shoulder joints were hot and inflamed. It was rheumatoid arthritis, a common but incurable autoimmune disorder in which the body attacks its own cells, in this case the lining of the joints, producing chronic inflammation and bone deformity.

Inflamed joints

Waiting rooms outside rheumatoid arthritis clinics used to be full of people in wheelchairs. That doesn’t happen as much now because of a new wave of drugs called biopharmaceuticals – such as highly targeted, genetically engineered proteins – which can really help. Not everyone feels better, however: even in countries with the best healthcare, at least 50 per cent of patients continue to suffer symptoms.

Like many patients, Vrind was given several different medications, including painkillers, a cancer drug called methotrexate to dampen her entire immune system, and biopharmaceuticals to block the production of specific inflammatory proteins. The drugs did their job well enough – at least, they did until one day in 2011, when they stopped working.

I was on holiday with my family and my arthritis suddenly became terrible and I couldn’t walk – my daughter-in-law had to wash me.

Vrind was rushed to hospital, where she was hooked up to an intravenous drip and given another cancer drug, one that targeted her white blood cells. “It helped,” she admits, but she was nervous about relying on such a drug long-term.

Luckily, she would not have to. As she was resigning herself to a life of disability and monthly chemotherapy, a new treatment was being developed that would profoundly challenge our understanding of how the brain and body interact to control the immune system. It would open up a whole new approach to treating rheumatoid arthritis and other autoimmune diseases, using the nervous system to modify inflammation. It would even lead to research into how we might use our minds to stave off disease.

And, like many good ideas, it came from an unexpected source.

The nerve hunter

Kevin Tracey, a neurosurgeon based in New York, is a man haunted by personal events – a man with a mission. “My mother died from a brain tumour when I was five years old. It was very sudden and unexpected,” he says. “And I learned from that experience that the brain – nerves – are responsible for health.” This drove his decision to become a brain surgeon. Then, during his hospital training, he was looking after a patient with serious burns who suddenly suffered severe inflammation. “She was an 11-month-old baby girl called Janice who died in my arms.”

Dr Kevin Tracey

These traumatic moments made him a neurosurgeon who thinks a lot about inflammation. He believes it was this perspective that enabled him to interpret the results of an accidental experiment in a new way.

In the late 1990s, Tracey was experimenting with a rat’s brain. “We’d injected an anti-inflammatory drug into the brain because we were studying the beneficial effect of blocking inflammation during a stroke,” he recalls. “We were surprised to find that when the drug was present in the brain, it also blocked inflammation in the spleen and in other organs in the rest of the body. Yet the amount of drug we’d injected was far too small to have got into the bloodstream and travelled to the rest of the body.”

After months puzzling over this, he finally hit upon the idea that the brain might be using the nervous system – specifically the vagus nerve – to tell the spleen to switch off inflammation everywhere.

It was an extraordinary idea – if Tracey was right, inflammation in body tissues was being directly regulated by the brain. Communication between the immune system’s specialist cells in our organs and bloodstream and the electrical connections of the nervous system had been considered impossible. Now Tracey was apparently discovering that the two systems were intricately linked.

The first critical test of this exciting hypothesis was to cut the vagus nerve. When Tracey and his team did, injecting the anti-inflammatory drug into the brain no longer had an effect on the rest of the body. The second test was to stimulate the nerve without any drug in the system. “Because the vagus nerve, like all nerves, communicates information through electrical signals, it meant that we should be able to replicate the experiment by putting a nerve stimulator on the vagus nerve in the brainstem to block inflammation in the spleen,” he explains. “That’s what we did and that was the breakthrough experiment.”

The vagus nerve

The wandering nerve

The vagus nerve starts in the brainstem, just behind the ears. It travels down each side of the neck, across the chest and down through the abdomen. ‘Vagus’ is Latin for ‘wandering’ and indeed this bundle of nerve fibres roves through the body, networking the brain with the stomach and digestive tract, the lungs, heart, spleen, intestines, liver and kidneys, not to mention a range of other nerves that are involved in speech, eye contact, facial expressions and even your ability to tune in to other people’s voices. It is made of thousands and thousands of fibres and 80 per cent of them are sensory, meaning that the vagus nerve reports back to your brain what is going on in your organs.

Operating far below the level of our conscious minds, the vagus nerve is vital for keeping our bodies healthy. It is an essential part of the parasympathetic nervous system, which is responsible for calming organs after the stressed ‘fight-or-flight’ adrenaline response to danger. Not all vagus nerves are the same, however: some people have stronger vagus activity, which means their bodies can relax faster after a stress.

The strength of your vagus response is known as your vagal tone and it can be determined by using an electrocardiogram to measure heart rate. Every time you breathe in, your heart beats faster in order to speed the flow of oxygenated blood around your body. Breathe out and your heart rate slows. This variability is one of many things regulated by the vagus nerve, which is active when you breathe out but suppressed when you breathe in, so the bigger your difference in heart rate when breathing in and out, the higher your vagal tone.

Breathing and the vagus nerve

Research shows that a high vagal tone makes your body better at regulating blood glucose levels, reducing the likelihood of diabetes, stroke and cardiovascular disease. Low vagal tone, however, has been associated with chronic inflammation. As part of the immune system, inflammation has a useful role helping the body to heal after an injury, for example, but it can damage organs and blood vessels if it persists when it is not needed. One of the vagus nerve’s jobs is to reset the immune system and switch off production of proteins that fuel inflammation. Low vagal tone means this regulation is less effective and inflammation can become excessive, such as in Maria Vrind’s rheumatoid arthritis or in toxic shock syndrome, which Kevin Tracey believes killed little Janice.

Having found evidence of a role for the vagus in a range of chronic inflammatory diseases, including rheumatoid arthritis, Tracey and his colleagues wanted to see if it could become a possible route for treatment. The vagus nerve works as a two-way messenger, passing electrochemical signals between the organs and the brain. In chronic inflammatory disease, Tracey figured, messages from the brain telling the spleen to switch off production of a particular inflammatory protein, tumour necrosis factor (TNF), weren’t being sent. Perhaps the signals could be boosted?

He spent the next decade meticulously mapping all the neural pathways involved in regulating TNF, from the brainstem to the mitochondria inside all our cells. Eventually, with a robust understanding of how the vagus nerve controlled inflammation, Tracey was ready to test whether it was possible to intervene in human disease.

Pacemaker implant

Stimulating trial

In the summer of 2011, Maria Vrind saw a newspaper advertisement calling for people with severe rheumatoid arthritis to volunteer for a clinical trial. Taking part would involve being fitted with an electrical implant directly connected to the vagus nerve. “I called them immediately,” she says.

I didn’t want to be on anticancer drugs my whole life; it’s bad for your organs and not good long-term.

Tracey had designed the trial with his collaborator, Paul-Peter Tak, professor of rheumatology at the University of Amsterdam. Tak had long been searching for an alternative to strong drugs that suppress the immune system to treat rheumatoid arthritis. “The body’s immune response only becomes a problem when it attacks your own body rather than alien cells, or when it is chronic,” he reasoned. “So the question becomes: how can we enhance the body’s switch-off mechanism? How can we drive resolution?”

When Tracey called him to suggest stimulating the vagus nerve might be the answer by switching off production of TNF, Tak quickly saw the potential and was enthusiastic to see if it would work. Vagal nerve stimulation had already been approved in humans for epilepsy, so getting approval for an arthritis trial would be relatively straightforward. A more serious potential hurdle was whether people used to taking drugs for their condition would be willing to undergo an operation to implant a device inside their body:

There was a big question mark about whether patients would accept a neuroelectric device like a pacemaker,” Tak says.

He needn’t have worried. More than a thousand people expressed interest in the procedure, far more than were needed for the trial. In November 2011, Vrind was the first of 20 Dutch patients to be operated on.

They put the pacemaker on the left-hand side of my chest, with wires that go up and attach to the vagus nerve in my throat,” she says. “I waited two weeks while the area healed, and then the doctors switched it on and adjusted the settings for me.”

Pacemaker x-ray

She was given a magnet to swipe across her throat six times a day, activating the implant and stimulating her vagus nerve for 30 seconds at a time. The hope was that this would reduce the inflammatory response in her spleen. As Vrind and the other trial participants were sent home, it became a waiting game for Tracey, Tak and the team to see if the theory, lab studies and animal trials would bear fruit in real patients. “We hoped that for some, there would be an easing of their symptoms – perhaps their joints would become a little less painful,” Tak says.

At first, Vrind was a bit too eager for a miracle cure. She immediately stopped taking her pills, but her symptoms came back so badly that she was bedridden and in terrible pain. She went back on the drugs and they were gradually reduced over a week instead.

And then the extraordinary happened: Vrind experienced a recovery more remarkable than she or the scientists had dared hope for.

“Within a few weeks, I was in a great condition,” she says. “I could walk again and cycle, I started ice-skating again and got back to my gymnastics. I feel so much better.” She is still taking methotrexate, which she will need at a low dose for the rest of her life, but at 68, semi-retired Vrind now plays and teaches seniors’ volleyball a couple of hours a week, cycles for at least an hour every day, does gymnastics, and plays with her eight grandchildren.

Other patients on the trial had similar transformative experiences. The results are still being prepared for publication but Tak says more than half of the patients showed significant improvement and around one-third are in remission – in effect cured of their rheumatoid arthritis. Sixteen of the 20 patients on the trial not only felt better, but measures of inflammation in their blood also went down. Some are now entirely drug-free. Even those who have not experienced clinically significant improvements with the implant insist it helps them; nobody wants it removed.

We have shown very clear trends with stimulation of three minutes a day,” Tak says. “When we discontinued stimulation, you could see disease came back again and levels of TNF in the blood went up. We restarted stimulation, and it normalised again.”

Nerve stimulation

Tak suspects that patients will continue to need vagal nerve stimulation for life. But unlike the drugs, which work by preventing production of immune cells and proteins such as TNF, vagal nerve stimulation seems to restore the body’s natural balance. It reduces the over-production of TNF that causes chronic inflammation but does not affect healthy immune function, so the body can respond normally to infection.

I’m really glad I got into the trial,” says Vrind. “It’s been more than three years now since the implant and my symptoms haven’t returned. At first I felt a pain in my head and throat when I used it, but within a couple of days, it stopped. Now I don’t feel anything except a tightness in my throat and my voice trembles while it’s working.

“I have occasional stiffness or a little pain in my knee sometimes but it’s gone in a couple of hours. I don’t have any side-effects from the implant, like I had with the drugs, and the effect is not wearing off, like it did with the drugs.”

Raising the tone

Having an electrical device surgically implanted into your neck for the rest of your life is a serious procedure. But the technique has proved so successful – and so appealing to patients – that other researchers are now looking into using vagal nerve stimulation for a range of other chronic debilitating conditions, including inflammatory bowel disease, asthma, diabetes, chronic fatigue syndrome and obesity.

But what about people who just have low vagal tone, whose physical and mental health could benefit from giving it a boost? Low vagal tone is associated with a range of health risks, whereas people with high vagal tone are not just healthier, they’re also socially and psychologically stronger – better able to concentrate and remember things, happier and less likely to be depressed, more empathetic and more likely to have close friendships.

Twin studies show that to a certain extent, vagal tone is genetically predetermined – some people are born luckier than others. But low vagal tone is more prevalent in those with certain lifestyles – people who do little exercise, for example. This led psychologists at the University of North Carolina at Chapel Hill to wonder if the relationship between vagal tone and wellbeing could be harnessed without the need for implants.

In 2010, Barbara Fredrickson and Bethany Kok recruited around 70 university staff members for an experiment. Each volunteer was asked to record the strength of emotions they felt every day. Vagal tone was measured at the beginning of the experiment and at the end, nine weeks later. As part of the experiment, half of the participants were taught a meditation technique to promote feelings of goodwill towards themselves and others.

Meditating to promote feelings of goodwill

Those who meditated showed a significant rise in vagal tone, which was associated with reported increases in positive emotions. “That was the first experimental evidence that if you increased positive emotions and that led to increased social closeness, then vagal tone changed,” Kok says.

Now at the Max Planck Institute in Germany, Kok is conducting a much larger trial to see if the results they found can be replicated. If so, vagal tone could one day be used as a diagnostic tool. In a way, it already is. “Hospitals already track heart-rate variability – vagal tone – in patients that have had a heart attack,” she says, “because it is known that having low variability is a risk factor.”

The implications of being able to simply and cheaply improve vagal tone, and so relieve major public health burdens such as cardiovascular conditions and diabetes, are enormous. It has the potential to completely change how we view disease. If visiting your GP involved a check on your vagal tone as easily as we test blood pressure, for example, you could be prescribed therapies to improve it. But this is still a long way off: “We don’t even know yet what a healthy vagal tone looks like,” cautions Kok. “We’re just looking at ranges, we don’t have precise measurements like we do for blood pressure.”

Meditation for health

What seems more likely in the shorter term is that devices will be implanted for many diseases that today are treated by drugs:

As the technology improves and these devices get smaller and more precise,” says Kevin Tracey, “I envisage a time where devices to control neural circuits for bioelectronic medicine will be injected – they will be placed either under local anaesthesia or under mild sedation.”

However the technology develops, our understanding of how the body manages disease has changed for ever. “It’s become increasingly clear that we can’t see organ systems in isolation, like we did in the past,” says Paul-Peter Tak. “We just looked at the immune system and therefore we have medicines that target the immune system.

“But it’s very clear that the human is one entity: mind and body are one. It sounds logical but it’s not how we looked at it before. We didn’t have the science to agree with what may seem intuitive. Now we have new data and new insights.”

And Maria Vrind, who despite severe rheumatoid arthritis can now cycle pain-free around Volendam, has a new lease of life: “It’s not a miracle – they told me how it works through electrical impulses – but it feels magical. I don’t want them to remove it ever. I have my life back!”