Can Vagus Nerve Stimulation Help People Get More Exercise?

While we all intuitively know that health metrics are not the same as health, we do, nevertheless, watch them, unpack them, and try to improve them.

One such metric, heart rate variability (HRV), has become one of the most-tracked biomarkers among athletes, longevity researchers, and wellness enthusiasts alike. If you wear a tracker, you’ll recognize these three letters: HRV. You may even have heard about its links to vagus nerve health.

But what is HRV exactly, and what does it have to do with the vagus nerve?

What is heart rate variability (HRV)?

HRV might sound complex, but it isn’t. Instead of beating like a metronome, your heart naturally varies the time between each beat. There are tiny fluctuations in the "lub-dub" of your heart. These variations, measured in milliseconds and recorded with wearables like WHOOP, Oura Ring, Apple Watch, or clinical-grade ECGs, constitute heart rate variability (HRV) readings.

Heart rate counts beats per minute; HRV measures the variations in time between beats.

Why does HRV matter?

A healthy heart isn't perfectly regular; it's adaptable. HRV tells you just how adaptable your heart is, how resilient it is. And, by extension, HRV also shows how well your nervous system is functioning, opening a window into your body’s ability to handle and bounce back from stress.

A higher HRV generally signals that your nervous system is flexible and adaptive, able to switch smoothly between stress and relaxation. A lower HRV, by contrast, often indicates stress, poor recovery, illness, or an overworked nervous system.

Research has linked HRV to:

• Cardiovascular health: low HRV can indicate cardiac events
• Mental health: reduced HRV is associated with anxiety, depression, and PTSD
• Athletic performance and recovery: elite athletes use HRV to time their training loads
• Longevity: higher HRV correlates with lower all-cause mortality
• Cognitive function: better HRV is associated with improved focus and decision-making

What is a good HRV?

HRV is highly individual. It varies by age, fitness level, genetics, sex, and measurement method. That said, despite the lack of universal ranges, some trends have emerged:

More important than your absolute number is your personal baseline trend. Are you improving over weeks and months? That's what matters.

How the vagus nerve controls HRV

To understand HRV, you need to understand the vagus nerve — the longest cranial nerve in the human body, running from the brainstem all the way down to your gut, heart, and lungs.

The vagus nerve is the primary highway of the parasympathetic nervous system (your rest-and-digest mode). It carries signals that slow the heart rate, lower blood pressure, reduce inflammation, and promote digestion and repair.

The vagus nerve controls your heart rate through a precise, rapid-fire chemical process. When activated, it releases a neurotransmitter called acetylcholine. This binds to receptors and triggers changes in cells, slowing your heartbeat.

What makes this remarkable is how fast it happens.

Unlike the sympathetic nervous system, which takes several seconds to influence heart rate, vagal signals act in under one second.

This near-instantaneous response is what allows the vagus nerve to make precise, beat-to-beat adjustments.

It is those vagal adjustments that are measured as HRV.

When the vagus nerve is active and healthy, it continuously modulates your heart rate in response to your breath, thoughts, movement, and environment. This modulation is HRV.

What is vagal tone?

Vagal tone refers to the baseline level of activity in your vagus nerve.

High vagal tone = efficient parasympathetic regulation = higher HRV.

Low vagal tone = reduced parasympathetic control, with greater sympathetic (fight-or-flight) influence = suppressed HRV.

Poor vagal tone has been linked to:

• Chronic inflammation
• Digestive issues (IBS, functional dyspepsia)
• Depression and anxiety
• Fatigue and poor sleep quality
• Slower recovery from illness or exercise

Vagal tone is not fixed. You can improve your vagus nerve's responsiveness — and your HRV along with it — through deliberate, evidence-based practices.

How to improve heart rate variability: evidence-based strategies

Here are the most evidence-supported methods to improve HRV by strengthening vagus nerve tone.

Practice slow breathing

Slow breathing activates the vagus nerve and produces large HRV improvements. You can follow breathwork activities on the yōjō app to complement your daily vagus nerve stimulation.

Try this: Inhale for 4 seconds, hold for 4, exhale for 4, and hold for 4. Do this for 5 minutes daily. This technique is often called "box breathing."

Cold exposure

Splashing cold water on your face, taking a cold shower, or submerging in cold water triggers the diving reflex, which activates the vagus nerve and increases parasympathetic tone. Even 30 seconds of exposure to cold water has been shown to affect HRV.

Regular aerobic exercise

Consistent cardio — running, cycling, swimming — is the single most powerful long-term intervention for improving HRV.

Exercise trains the heart and autonomic nervous system to handle stress more efficiently, building baseline vagal tone over months and years.

Tip: Track your HRV after hard training sessions. A significant HRV drop signals you need more recovery time — use it as your body's readiness signal.

Meditation and mindfulness

Studies show that regular meditators have higher resting HRV compared to non-meditators. Even an 8-week mindfulness program has been shown to shift autonomic balance toward greater parasympathetic dominance.

Transauricular vagus nerve stimulation (taVNS)

Several studies show that transcutaneous auricular vagus nerve stimulation (taVNS) can improve heart rate variability (HRV), a key marker of the nervous system's ability to regulate stress.

Research consistently finds that taVNS increases high-frequency (HF) power and RMSSD, two HRV measures strongly linked to vagus nerve activity and parasympathetic control of the heart.

These changes indicate a shift in the nervous system from sympathetic fight-or-flight dominance and toward parasympathetic recovery mode.

The effects are often most pronounced in people with higher baseline nervous system stress, such as older adults or individuals with cardiovascular conditions.

Sleep quality and consistency

Your HRV recovers during sleep, specifically during slow-wave and REM stages. Poor sleep hygiene chronically suppresses vagal tone and HRV. Prioritizing 7–9 hours of quality sleep, consistent sleep timing, and a cool, dark room are basic but powerful HRV levers.

Excessive alcohol consumption

Alcohol acutely suppresses HRV within hours of consumption.

Even moderate alcohol the night before can reduce next-morning HRV by 28-33% in some individuals.

The gut-vagus connection is bidirectional: what damages or disrupts your gut microbiome alters your vagal signaling.

Humming, singing, and gargling

These might sound unusual, but they work.

The vagus nerve innervates the muscles of the larynx and pharynx. Humming, chanting, singing, or gargling activates these muscles and sends afferent (upward) signals along the vagus nerve, increasing parasympathetic tone.

HRV as a window into your nervous system

HRV is more than a fitness metric. It's a real-time readout of how well your nervous system is regulating itself, how resilient your body is to physical and psychological stress.

The vagus nerve is the biological infrastructure behind that resilience.

By deliberately training vagal tone through breathing, movement, cold exposure, and mindfulness, you're not just chasing a number on a dashboard — you're rewiring your autonomic nervous system toward greater health and adaptability.

In a world that chronically pushes us toward sympathetic overdrive (stress, screens, poor sleep, inflammation), improving your HRV through vagal stimulation is one of the most powerful evidence-backed things you can do for long-term health.

Vagus nerve stimulation (VNS) is a medical treatment that uses mild electrical pulses to stimulate the vagus nerve — one of the most important communication pathways in the body.

The vagus nerve begins in the brainstem (the medulla oblongata) and travels down through the neck into the chest and abdomen. Along the way, it connects to the heart, lungs, digestive organs, and immune system.

It is the body’s main “homeostasis nerve.”

Roughly 80% of its fibers are afferent, meaning they carry sensory information from the body up to the brain. The remaining fibers are efferent, sending regulatory signals from the brain back down into the organs.

It is a two-way highway between your brain and body.

By stimulating that vagus nerve, you can influence brain activity, calm the nervous system, and regulate inflammation.

The two types of vagus nerve stimulation

There are two types of vagus nerve stimulation, invasive and non-invasive.

Invasive VNS (iVNS)

This is the original surgical approach approved by the FDA for the treatment of drug-resistant epilepsy in 1988.

• A pulse generator is implanted under the skin in the chest.
• A wire is wrapped around the left vagus nerve in the neck.
• The device sends automatic electrical pulses throughout the day.
• Doctors program it externally.
• Patients can trigger extra stimulation with a magnet.

While effective, it requires surgery and carries surgical risks.

Non-invasive VNS (nVNS)

Newer devices stimulate the vagus nerve through the skin, without surgery.

There are two main forms:

• Cervical VNS (tcVNS) is usually a handheld device placed on the side of the neck. It delivers short bursts of stimulation and is often used for migraine and cluster headaches.
• Auricular VNS (taVNS) stimulates the vagus nerve through its branches in the ear. A small earpiece or clip is placed on the tragus, cymba concha, and cavum concha, producing a mild tingling sensation. This form of nVNS is highly effective because the vagus nerve’s branches are close to the surface of the skin.

Non-invasive devices are typically used at home and do not require anesthesia.

Studies suggest nVNS can be as effective as implanted VNS for many conditions — without surgery.

It is:

• Safe
• Well tolerated
• Drug-free
• Flexible
• Affordable
• Free of known drug interactions

There are no strict limits on daily stimulation sessions.

How vagus nerve stimulation works

VNS works by delivering mild electrical impulses to the vagus nerve. These signals travel up to the brainstem and then spread to other important brain regions involved in mood, stress, pain, and healing.

When stimulated, the vagus nerve can trigger several important changes:

Chemical shifts in the brain

VNS increases the release of key neurotransmitters such as:

• Serotonin, which supports mood stability
• Norepinephrine, which helps with focus and alertness
• GABA, which calms overactive brain activity

These changes help regulate mood, reduce anxiety, and stabilize abnormal brain signaling.

Brain rewiring (neuroplasticity)

VNS promotes neuroplasticity, the brain’s ability to reorganize and form new connections. This is especially helpful in conditions like stroke rehabilitation and depression.

It can also quiet overactive “fear centers” in the brain, such as the amygdala.

Autonomic nervous system balance

The vagus nerve is a key part of the parasympathetic nervous system, often called the rest-and-digest system.

Stimulating it helps engage what researchers call the vagal brake, which:

• Slows heart rate
• Reduces fight-or-flight responses
• Promotes calm and recovery

Inflammation control

VNS activates the cholinergic anti-inflammatory pathway, a built-in reflex that signals the immune system to reduce the production of inflammatory chemicals.

This is one reason why researchers are studying VNS for autoimmune and inflammatory conditions.

What does vagus nerve stimulation feel like?

For non-invasive ear-based devices, most people feel a mild tingling or gentle buzzing. Cervical stimulation is similar but can also cause facial muscle twitching.

nVNS should not be painful at all.

Implanted devices may cause temporary hoarseness during stimulation.

The future of vagus nerve stimulation

VNS is already approved for:

• Drug-resistant epilepsy
• Treatment-resistant depression
• Migraines and cluster headaches
• Stroke rehabilitation
• Rheumatoid arthritis

It is being actively studied for:

• Anxiety
• Chronic pain
• Insomnia
• Parkinson’s disease
• Alzheimer’s disease
• Autoimmune disorders
• Post-viral syndromes

Research is still evolving, but one thing is clear:

Vagus nerve stimulation represents a shift in medicine, away from symptom suppression and toward neuromodulation and homeostasis, modern tech working with the body’s ancient wiring.

Chronic inflammation is linked to many modern diseases, from rheumatoid arthritis and inflammatory bowel disease (IBD) to respiratory diseases and heart problems, even complications after surgery or infection.

Most treatments focus on suppressing the immune system with medication.

But vagus nerve stimulation (nVNS) works differently.

Instead of blocking inflammation chemically with drugs, nVNS activates the body’s built-in anti-inflammatory system.

When we stimulate the vagus nerve, we activate natural pathways that:

• Lower harmful inflammatory chemicals
• Support anti-inflammatory signals
• Help rebalance the stress response

There are four main ways this happens.

1. The cholinergic anti-inflammatory pathway (CAP)

This is the most studied mechanism.

When the vagus nerve is stimulated, it releases a chemical messenger called acetylcholine.

Acetylcholine binds to a specific receptor on immune cells, the α7 nicotinic receptor, which is found on cells like macrophages — your body’s primary cleanup crew.

When this happens, the immune cells reduce their production of pro-inflammatory chemical messengers like:

• TNF-α
• IL-1β
• IL-6
• IL-18

These chemical messengers normally help fight infection — but when levels stay high, they can damage healthy tissue.

Importantly, vagus nerve stimulation does not shut down helpful anti-inflammatory chemical messengers. In some cases, IL-10, for example, may even increase.

Rather than turn off the inflammatory response entirely, nVNS helps to keep it from overreacting.

2. The spleen pathway

A lot of inflammation in the body is driven by the spleen. The spleen is like a pantry of immune cells, its doors flinging open in response to injury or infection.

Vagus nerve stimulation affects the spleen through a relay system:

1. The vagus nerve activates the splenic sympathetic nerve, a nearby nerve connected to the spleen.
2. That nerve releases norepinephrine, the neurotransmitter and hormone that triggers your fight-or-flight response.
3. Norepinephrine activates special cells in the spleen.
4. These cells release acetylcholine.
5. Acetylcholine stops spleen macrophages from producing more pro-inflammatory agents.

This chain reaction lowers inflammation throughout the body.

Even though it sounds complex, the outcome is simple:

Less inflammatory signaling.

3. Activation of the hypothalamic-pituitary-adrenocortical (HPA) axis

Vagus nerve stimulation also works through stress-regulating centers in the brain.

When vagal sensory fibers detect inflammation, they send signals to the brainstem. This activates the hypothalamus and starts a hormone flow:

• The brain releases CRF
• Then the pituitary releases ACTH
• And finally, the adrenal glands release cortisol

Known as the stress hormone, because it's associated with the stress response, cortisol is actually one of the body’s strongest natural anti-inflammatory hormones.

Part of the damage caused by chronic stress is cortisol resistance, which leads to less and less short-term inflammation management.

Through this hypothalamic-pituitary-adrenal pathway, VNS helps reduce systemic inflammation, or whole-body inflammation.

4. The splanchnic anti-inflammatory pathway

Newer research shows that stimulating certain abdominal vagal fibers can activate another nerve network called the splanchnic sympathetic system.

This pathway also lowers levels of pro-inflammatory agents in the bloodstream, likely by influencing the spleen.

So, as you can see, VNS stimulates multiple anti-inflammatory circuits at once.

Why this matters

Chronic inflammation often develops when the body’s regulation systems stop working properly — especially under long-term stress.

Vagus nerve stimulation helps restore that regulation.

Instead of blocking the immune system directly, it activates the body’s natural “brake” on inflammation.

It lowers harmful cytokines.

It supports anti-inflammatory signals.

And, it improves communication between the brain and the immune system.

In short, VNS reduces inflammation by helping your body rebalance itself.