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The Chemistry of Ozonated Olive Oil

by | Mar 10, 2026

Understanding How Ozone Reacts with Unsaturated Oils

A simple travel experience helped spark our curiosity about ozonated oils.

During a long international flight, my business partner felt the early signs of a cold coming on. With very little available, he used a small amount of ozonated olive oil.

By the end of the trip, the symptoms had disappeared instead of progressing further.

This is only an anecdote, not a study — but it raises an interesting question:

What actually happens chemically when ozone reacts with olive oil?

To answer that question, we must first examine the molecular chemistry involved.

The Reactive Site in Olive Oil

Olive oil is composed primarily of fatty acids. The most important for ozone chemistry is oleic acid, a monounsaturated fatty acid.

Simplified molecular structure:

CH3–(CH2)7–CH=CH–(CH2)7–COOH

double bond

The carbon-carbon double bond (C=C) is the key reactive site.

Double bonds contain a region of high electron density, which makes them chemically attractive to reactive molecules such as ozone.

Because olive oil contains a large proportion of oleic acid, it provides many of these reaction sites.

The Ozone Molecule

Ozone is a molecule composed of three oxygen atoms.

Chemical formula:

O3

However, ozone is not arranged in a simple straight chain. Instead it exists as a resonance structure, meaning the electrons are shared between two possible bonding arrangements.

Two simplified representations are often used:

O=O–O

or

O–O=O

The molecule continually shifts between these structures.

Because of this unstable electron distribution, ozone is highly reactive and readily reacts with molecules containing double bonds.

The Ozonolysis Reaction

When ozone encounters the double bond in oleic acid, a reaction called ozonolysis occurs.

This reaction proceeds through several distinct steps.

Double Bond Before Reaction

The starting structure contains the carbon-carbon double bond.

R–CH = CH–R

The R groups represent the remainder of the fatty acid chain.

Formation of the Primary Ozonide (Molozonide)

Ozone adds across the double bond to form an unstable ring structure called the primary ozonide, also known as a molozonide.

Diagram — Primary Ozonide

O
/ \\\\
R–CH CH–R
\\\\ /
O
|
O

Key features:

  • five-member ring
  • three oxygen atoms connected in sequence (O–O–O)
  • extremely unstable

This structure exists only briefly.

Criegee Intermediate Formation

The primary ozonide rapidly breaks apart into fragments.

Two major fragments are produced:

R–CHO + R–CHOO
aldehyde carbonyl oxide
(Criegee intermediate)

The Criegee intermediate is a highly reactive carbonyl oxide.

Simplified structure:

O
||
R–CH–O–O

These fragments exist only briefly before recombining.

Formation of the Secondary Ozonide

The fragments recombine to form a more stable ring structure known as the secondary ozonide.

Diagram — Secondary Ozonide

O
/ \\\\
R–CH CH–R
\\\\ /
O–O

Key chemical feature:

O–O

This is a peroxide bond.

Secondary ozonides are the molecules that remain stored in ozonated oils after the ozone gas has disappeared.

Compounds Found in Ozonated Olive Oil

After prolonged ozonation, olive oil becomes a mixture of oxygen-containing lipid molecules.

These may include:

  • secondary ozonides
  • peroxides
  • hydroperoxides
  • aldehydes
  • ketones
  • other oxidized lipid compounds

These molecules contain additional oxygen atoms incorporated into the lipid structure.

Why Ozonated Oil Thickens

One of the most visible changes during ozonation is the gradual thickening of the oil.

Fresh olive oil is normally a free-flowing liquid. However, during ozonation it may become:

• more viscous
• cloudy
• eventually gel-like

This change reflects molecular changes occurring in the oil.

As ozone reacts with double bonds, the original lipid molecules are converted into oxygen-rich compounds. These modified molecules can interact with each other through hydrogen bonding and peroxide linkages.

As more of these interactions occur, the oil begins to behave like a loose molecular network.

Simplified visualization:

Fresh oil molecules

——— ——— ———
——— ———
——— ——— ———

After ozonation

—O—O— —O—
—O—O—
—O— —O—

The increased interaction between molecules causes the oil to thicken.

What Happens When Ozonated Oil Contacts Tissue

Once ozonation is complete, the ozone gas itself is gone. What remains are oxygen-rich lipid molecules.

These molecules can interact with biological tissue in several ways.

Peroxide Bond Reactivity

Peroxide bonds contain stored chemical energy.

R–O–O–R

When exposed to moisture, enzymes, or biological molecules, these bonds can slowly decompose.

This may generate small amounts of reactive oxygen-containing compounds.

Reactive Oxygen Molecules

Examples of molecules that may form include:

• hydrogen peroxide (H₂O₂)
• lipid hydroperoxides
• short-lived oxygen radicals

These molecules are chemically reactive but typically short-lived.

Oxidation of Microorganisms

Reactive oxygen compounds can interact with microbial structures.

Targets may include:

  • lipid membranes
  • viral envelopes
  • microbial enzymes

Oxidation of these structures can disrupt microbial survival.

For this reason, ozonated oils have historically been explored in:

  • dermatology
  • wound care
  • dental preparations
  • antimicrobial topical formulations

Cellular Signaling and Adaptive Responses

Small amounts of reactive oxygen molecules can also function as biological signals.

Cells use these signals to regulate protective systems.

One important pathway is the Nrf2 pathway, which activates production of antioxidant enzymes such as:

  • superoxide dismutase
  • catalase
  • glutathione peroxidase

These enzymes help regulate redox balance, the equilibrium between oxidative and antioxidant processes within cells.

Why Olive Oil Works Well for Ozonation

Several characteristics make olive oil suitable for ozonation.

High Oleic Acid Content

Oleic acid contains the double bond required for ozone reactions.

Molecular Stability

Compared with highly polyunsaturated oils, olive oil is relatively stable during oxidation.

Liquid Structure

Because olive oil is liquid, ozone can diffuse through the oil and react with the fatty acids.

Why Coconut Oil Reacts Differently

Coconut oil has a very different composition.

Most of its fatty acids are saturated, meaning they contain no carbon-carbon double bonds.

Example saturated fatty acid:

CH3–CH2–CH2–CH2–CH2–CH2–COOH

Because ozone reacts primarily with double bonds, coconut oil provides fewer reaction sites.

This means:

  • ozonation proceeds more slowly
  • fewer ozonide structures form

Why Glycerin Behaves Differently

Glycerin (glycerol) is not a fatty oil.

Its structure is:

HO–CH2–CH(OH)–CH2–OH

Because glycerin contains no carbon-carbon double bonds, it cannot undergo ozonolysis in the same way as unsaturated oils.

Instead, ozone reacts with glycerin through oxidation of alcohol groups, producing different oxygen-containing compounds.

Stability of Ozonated Oils

Unlike ozone gas, which decomposes quickly, ozonated oils can remain chemically active for extended periods.

This stability occurs because the reactive oxygen chemistry is stored within lipid molecules such as ozonides and peroxides.

Several factors affect stability:

Temperature — cooler storage improves stability
Light exposure — ultraviolet light can degrade peroxide bonds
Air exposure — oxygen can slowly oxidize the oil further

For this reason ozonated oils are often stored in dark glass containers in cool environments.

Producing Ozonated Oils

The ozonation process requires controlled ozone generation.

Step 1 — Ozone generation

Ozone is produced from oxygen using an electrical discharge.

3 O2 → 2 O3

Step 2 — Bubbling ozone through oil

Ozone gas is bubbled through the oil for many hours.

Step 3 — Progressive ozonation

During this process:

• double bonds react
• ozonide structures accumulate
• viscosity increases

Final Summary Diagram

Unsaturated fatty acid (C=C)
+
Ozone

Primary ozonide (unstable)

Criegee intermediate

Secondary ozonide

The result is a stored mixture of oxygen-rich lipid compounds that can remain chemically active long after the ozone gas itself has disappeared.

Recover U Technologies and Services Inc.

Maya Fabiszak, Director, Certified Oxidative Therapies Specialist, Certified Nutritionist & Environmental Lifestyle Counselor, phone 647.909.7419
Ewa Pringle, Cofounder, phone 289.217.5552

Websites:
Recover U Technologies and Services Inc.
Swiss Bionic Solutions

Related Articles

If you’re interested in how different oils behave during ozonation, you may also enjoy:

Why Coconut Oil Reacts Differently from Olive Oil During Ozonation

This article explains how saturated oils such as coconut oil respond differently to ozone and why olive oil remains the most common oil used in ozonation chemistry.

👉 Read the article here

FAQ – Ozonated Coconut Oil

1. Why does coconut oil react more slowly with ozone than olive oil?

Coconut oil is composed mainly of saturated fatty acids, which do not contain carbon–carbon double bonds.

Ozone reacts most readily with double bonds in unsaturated fatty acids. Because olive oil contains a high concentration of oleic acid with these double bonds, it reacts much more easily with ozone.

Coconut oil contains far fewer reactive sites, so ozonation occurs more slowly and produces fewer ozonide compounds.

2. What is the difference between ozonated coconut oil and ozonated olive oil?

The main difference lies in the chemical structures formed during ozonation.

Ozonated olive oil forms larger quantities of:

  • ozonides
  • peroxides
  • oxygen-rich lipid compounds

These structures allow olive oil to store reactive oxygen chemistry more effectively.

Ozonated coconut oil typically produces fewer of these compounds and therefore tends to be milder and more suitable for cosmetic formulations.

3. Why do some people choose ozonated coconut oil for skincare products?

Coconut oil has several properties that make it attractive for cosmetic use.

It naturally contains fatty acids such as lauric acid, which has antimicrobial characteristics.

When ozonated, coconut oil can produce a product that is:

  • moisturizing
  • easy to spread
  • gentle on skin
  • suitable for creams and balms

For these reasons, ozonated coconut oil is sometimes used in skincare formulations.

4. How long does it take to produce ozonated coconut oil?

Because coconut oil contains fewer reactive sites for ozone, the ozonation process typically takes longer than with olive oil.

Depending on the ozone concentration and the desired level of oxidation, ozonation may take:

  • 24 hours
  • 48 hours
  • sometimes longer

The oil is usually gently warmed during the process to keep it liquid so ozone bubbles can pass through it more easily.

5. Can ozonated coconut oil be inhaled?

No. Ozonated oils are chemically different from ozone gas.

During the ozonation process, the ozone molecule reacts with the oil and is no longer present as free gas. What remains are oxygen-containing lipid compounds.

These products are typically explored for topical applications, not inhalation.
Ozone inhalation requires specialized equipment and controlled environments.

Ozone & Pets

Ozone & Pets

by | Jan 2, 2026

Practical, Responsible Home Uses Inspired by Veterinary Ozone Practice

Ozone therapy has been used worldwide for decades in water sanitation, dentistry, medicine, and environmental disinfection. In recent years, it has also become part of integrative veterinary practice, where trained professionals use ozone in controlled ways to support wound care, oral health, infection management, and recovery.

This resource is not about clinical veterinary ozone therapy.

It is about sensible, non-invasive, at-home uses of ozonated water and topical ozone products, informed by professional ozone principles and adapted for everyday pet care.

For readers new to ozone, you can learn more about how ozone works here:https://resonateintowellness.com/ozone-therapy/

Why Ozone Makes Sense for Home Pet Care

Ozone (O₃) is oxygen with an extra oxygen atom. That extra atom makes ozone highly reactive, which is why it has long been used to:

  • Disinfect drinking water
  • Sanitize food and surfaces
  • Neutralize odours at their source
  • Reduce microbial load without leaving chemical residues

A key point many people miss:

Ozone is not stable.

  • In water, ozone gradually converts back into oxygen
  • Heat, air exposure, and time reduce its strength
  • Fresh ozonated water is the most effective

This short lifespan is actually a benefit for home use — it allows ozone to be effective without lingering toxicity.

Clear Safety Boundaries (Realistic & Accurate)

What not to do

  • ❌ Do not expose pets to ozone gas in the air
  • ❌ Do not attempt veterinary ozone procedures at home
    (injections, internal insufflation, IV ozone, etc.)
  • ❌ Do not use ozone as a replacement for veterinary diagnosis or treatment

What is appropriate at home

  • ✅ Fresh ozonated water for external cleaning and hygiene
  • Topical ozone oils for skin support (used appropriately)
  • ✅ Environmental cleaning and odour control
  • ✅ Supportive hygiene for skin, fur, paws, mouth, and surfaces

Ears: Responsible Use Without Overreach

In veterinary settings, ozone may be used for ear conditions by trained professionals.

At home:

  • Limit ozone use to external ear hygiene only
  • Apply fresh ozonated water to a cotton pad
  • Gently clean the visible outer ear
  • Never force liquid or gas deep into the ear canal

If there is pain, head shaking, discharge, or persistent odour, professional veterinary evaluation is essential.

Oral Hygiene & Gums (Supportive, Not Clinical)

Many pet owners already brush teeth or wipe gums. Fresh ozonated water can be used in the same supportive hygiene category:

  • Helps reduce surface microbial load
  • Leaves no chemical residue
  • Works best when used gently and fresh

This does not replace dental cleanings or treatment of infections — it supports routine care.

Skin, Fur & Environmental Hygiene

Ozonated water can be used for:

Minor superficial skin irritations
Paw rinsing after outdoor exposure
Fur wiping after messy adventures
Cleaning bedding, bowls, crates, carriers, and grooming tools

Because ozone breaks down into oxygen, it is often chosen by pet owners who want to reduce chemical load in the home.

Odour Events: Where Ozone Excels

Certain pet situations overwhelm normal washing:

  • Skunk encounters
  • Rolling in faeces
  • Contact with decomposing organic matter
  • Persistent “mystery smells”

Ozonated water:

  • Neutralizes odour-causing compounds
  • Does not rely on fragrance
  • Works as a powerful add-on to washing, not a mask

Ozone Equipment (For Home Hygiene Use)

Pet owners who regularly use ozonated water for hygiene, cleaning, or odour control often choose home ozone generator kits designed for water ozonation, not air treatment.

You can explore ozone generator kits suitable for water-based applications here:
https://resonateintowellness.com/product-category/ozone-generator-kits/

A Brief Note on PEMF

Some pet owners also explore PEMF (Pulsed Electromagnetic Field) systems as a non-invasive wellness tool. This topic will be covered in a separate dedicated article focused specifically on PEMF and pets.

Bottom Line

Ozone is powerful — but power works best with restraint.

When used as fresh ozonated water, ozone can be a valuable home tool for:

  • Hygiene
  • Odor control
  • Environmental cleanliness
  • Gentle skin and oral support

Used responsibly, it complements veterinary care rather than competing with it.

Frequently Asked Questions: Ozone & Pets

Contents

Disclaimer

This content is for educational purposes only and does not replace veterinary care or professional medical advice. Ozone use described here is limited to non-invasive, external hygiene and environmental applications using properly ozonated water. Veterinary ozone procedures should only be performed by trained professionals. If your pet has persistent symptoms, pain, infection, or injury, consult a licensed veterinarian.

The Lymphatic Drainage System: Superficial, Deep & Whole-Body Detox Pathways

by | Dec 21, 2025

The lymphatic system is central to detoxification, immune regulation, inflammation control, and metabolic balance. Yet it remains one of the least understood systems in modern health discussions.

When lymphatic transport slows, detoxification does not stop — it accumulates, placing increasing stress on immune, metabolic, and inflammatory systems over time.

Unlike the cardiovascular system, the lymphatic system has no central pump. Its efficiency depends entirely on mechanical movement, pressure gradients, breathing dynamics, circulation, and biochemical signaling. When these inputs are insufficient, lymph stagnates — and detoxification slows at a systemic level.

This resource explains how the lymphatic system functions, the difference between superficial and deep lymphatic drainage, and how therapies involving heat, ozone, oxygen utilization, and controlled stress can significantly influence lymphatic flow.

The Core Role of the Lymphatic System

The lymphatic system is a parallel circulatory network responsible for:

  • Transporting metabolic waste and cellular debris
  • Moving immune cells and inflammatory mediators
  • Regulating interstitial fluid balance
  • Supporting detoxification pathways
  • Maintaining tissue and organ health

Lymph fluid collects waste from tissues and transports it through lymph vessels and nodes, where immune processing occurs before elimination via the liver, kidneys, lungs, and digestive tract.

When lymph flow is impaired, waste clearance becomes inefficient — regardless of liver or kidney function.

Superficial Lymphatic Drainage

The superficial lymphatic network lies just beneath the skin and primarily drains:

  • Skin and subcutaneous tissue
  • Surface inflammation
  • Localized fluid retention
  • Cosmetic and soft-tissue congestion

Superficial lymph flow responds well to:

  • Gentle movement
  • Light pressure
  • Skin stimulation
  • Heat exposure

When superficial lymph stagnates, common signs include puffiness, swelling, dull skin tone, and localized fluid retention.

Superficial drainage is important — but it represents only the outer layer of lymphatic function.

Deep Lymphatic Drainage: Where Systemic Detox Occurs

The deep lymphatic system runs alongside major blood vessels and vital organs, including:

  • Liver
  • Intestines
  • Lungs
  • Kidneys
  • Muscles and joints

This network is responsible for transporting systemic waste, inflammatory byproducts, immune complexes, and metabolic debris generated deep within tissues.

Deep lymphatic flow depends heavily on:

  • Muscle contraction
  • Respiratory mechanics
  • Circulatory pressure changes
  • Heat-induced vasodilation
  • Carbon dioxide (CO₂) balance

When deep lymph stagnates, detoxification becomes incomplete. Waste accumulates not at the surface, but around organs and within tissues, contributing to fatigue, inflammation, and impaired recovery.

Detoxification Is a Transport Problem, Not a Breakdown Problem

Detoxification is often described as a liver-centric process. In reality, the liver and kidneys process waste, but the lymphatic system delivers it.

If lymphatic transport is slow:

  • Detox protocols may feel exhausting
  • Inflammatory load may increase
  • Energy may decline rather than improve

Effective detoxification requires efficient waste transport, not simply enhanced biochemical processing.

Heat, Circulation & Lymphatic Pressure Dynamics

Heat exposure has profound physiological effects relevant to lymphatic flow:

  • Blood and lymph vessels dilate
  • Circulatory volume increases
  • Tissue perfusion improves
  • Pressure gradients shift
  • Sweating increases

Steam and heat create rhythmic changes in vascular and interstitial pressure, which mechanically assist lymph movement — particularly in deep lymph vessels near organs.

This is why sauna therapy has long been associated with detoxification, immune support, and recovery.

What Ozone Contributes at a Physiological Level

Ozone is an activated form of oxygen that interacts with redox signaling, immune modulation, and oxygen utilization pathways.

When ozone is introduced in a controlled setting — particularly during heat exposure — it can influence:

  • Oxidative signaling cascades
  • Immune communication
  • Antimicrobial balance
  • Oxygen utilization efficiency

Importantly, ozone does not act as a simple oxygen donor. It functions as a biological signal, influencing how the body responds to oxidative stress and metabolic demand.

When circulation and lymph flow are already elevated (as during sauna use), these signaling effects are more likely to support efficient waste transport and immune regulation.

CO₂, Oxygen Utilization & Lymphatic Flow

A critical but often overlooked factor in lymphatic function is carbon dioxide (CO₂).

CO₂ plays a central role in:

  • Blood vessel dilation
  • Oxygen release into tissues (Bohr effect)
  • Breathing depth and rhythm
  • Pressure changes that drive lymph movement

Improved oxygen utilization is not solely about oxygen intake — it depends on appropriate CO₂ levels. When CO₂ balance improves, oxygen delivery and waste removal tend to improve together.

This is why breathing mechanics, heat exposure, and circulatory stimulation are so influential for lymphatic health.

EWOT, Oxygen Dynamics & Lymph Support

Exercise With Oxygen Therapy (EWOT) introduces oxygen under conditions of elevated metabolic demand. When used appropriately, EWOT may:

  • Increase circulatory pressure changes
  • Enhance oxygen utilization
  • Support lymphatic transport through muscular and respiratory activity

When combined with heat-based therapies, EWOT can complement lymphatic movement by reinforcing the mechanical drivers of lymph flow rather than relying on passive approaches alone.

Why Ozone Steam Saunas Offer a Multi-Layered Approach

Ozone steam saunas systems combine several lymph-supportive mechanisms in a single session:

  • Heat → circulation and lymph vessel dilation
  • Steam → hydration and skin-based elimination
  • Ozone → immune and oxidative signaling
  • Optional oxygen breathing / EWOT → oxygen utilization support

This creates a physiological environment in which deep lymphatic drainage is supported rather than forced, allowing detox processes to proceed more efficiently and sustainably.

Supporting Lymphatic Function Beyond the Sauna

Consistent lymphatic support also includes:

  • Regular movement
  • Conscious breathing
  • Adequate hydration
  • Stress regulation
  • Recovery-oriented routines

The goal is not aggressive detoxification, but optimized transport and clearance.

Frequently Asked Questions

Q: Why is deep lymphatic drainage more difficult to stimulate?
Deep lymph vessels rely on internal pressure changes, breathing mechanics, and circulation rather than surface stimulation alone.

Q: Can sauna therapy support lymphatic drainage?
Yes. Heat and steam increase circulation and pressure dynamics that mechanically assist lymph movement, including in deep vessels.

Q: How does ozone interact with detox pathways?
Ozone influences immune and oxidative signaling. When combined with heat and circulation, it may support efficient waste transport rather than forcing elimination.

Q: Why does detox sometimes feel draining instead of energizing?
Detox can feel difficult when lymphatic transport is insufficient. Supporting lymph flow often changes how detox is experienced.s

Summary

  • The lymphatic system is central to detoxification and immune regulation
  • Superficial and deep lymphatic drainage serve different roles
  • Heat, circulation, breathing, and pressure dynamics drive lymph movement
  • Ozone and oxygen-based therapies influence detox through signaling and utilization pathways
  • Ozone steam saunas integrate multiple supportive mechanisms in one system

Supporting lymphatic drainage means supporting the body’s capacity to clear, recover, and adapt.

Further Reading

Disclaimer

The information provided is for educational purposes only and is not intended as medical advice. Products and therapies referenced are not intended to diagnose, treat, cure, or prevent disease. Always consult a qualified healthcare practitioner before beginning any new wellness practice.

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Other ozone applications

by | Nov 21, 2025

There are several active oxygen (ozone) application methods that can be done in the clinic or after proper instruction safely and effectively applied at home.

“The concept of at home preventive therapy with ozone might just be one of the biggest breakthroughs of this decade”.

Dr. Frank Shallenberger

Assuming you have the proper equipment and know-how, there are simple and non-invasive do-it-yourself ozone therapy application methods that can be performed at home.

INGESTION

  • using low gamma ozonated water for drinking and purifying water
  • consuming ozonated olive oil

TOPICAL/TRANSDERMAL

  • ozone steam sauna
  • applying ozonated olive oil
  • limb bagging with ozone
  • cupping with ozone

INHALATION

IRRIGATION

  • using ozone water for colonic irrigation, retentive enema, vaginal douche
  • dental/oral applications

INSUFFLATION

  • rectal insufflation
  • vaginal insufflation
  • ear insufflation

CLEANING

  • disinfecting with ozonated water

It is essential to follow proper guidelines for safe and effective at-home ozone therapy. Consultation with a healthcare professional is advised.

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NASA studies

by | Nov 21, 2025

This four year study used volunteers “to define the most effective electromagnetic fields for enhancing growth and repair in mammalian tissues,” To utilize “nerve tissue which has been refractory to efforts to stimulate growth or enhance its repair regardless of the energy used”, to define a PEMF technology that would “duplicate mature, three dimensional morphology between neuronal cells and feeder (glial) cells, which has not been previously accomplished.”Concluding four-year-long research efforts NASA’s concluded: “The up-regulation of these genes is in no manner marginal (1.7-8.4 logs) with gene sites for collagen production and growth the most actively stimulated”, “We have clearly demonstrated the bioelectric/biochemical potentiation of nerve stimulation and restoration in humans as a documented reality”, “The most effective electromagnetic field for repair of trauma was square wave with a rapid rate of change (dB/dt) which saw cell growth increased up to 4.0 times.” They further noted that “slowly varying (millisecond pulse, sine wave) or non-varying DC (CW lasers, magnets) had little to no effect.” NASA’s suggested recommendations: “One may use square wave EM fields with a rapid rate of change for”: repairing traumatized tissues, moderating certain neurodegenerative diseases such as Alzheimer and Parkinson, treatment of some muscle disorders, in healing refractory broken bones, and developing tissues for transplantation.

We, humans, are electromagnetic beings and electromagnetism is a life force for us – as it is for the entire universe. All cells within our body are communicating via electrical impulses. Scientists and doctors have wondered for years if by upregulating and manipulating those impulses human health and well-being can be improved. According to the most cutting-edge modern science, PEMF technology can help prevent tissue decay for many hours and NASA research has proved that it definitively could. Overall, it enhances the way your body properly works in many cases controlling and treating inflammation a leading cause of countless chronic illnesses and relieving pain and halting all aging symptoms with no side effects.

We finally reach the time in our human history that not only astronauts travelling into the outer space of planet Earth are benefiting from PEMF technology. Swiss Bionic Solutions systems have been manufacturing PEMF home units that could benefit all of us. As PEMF technology has no risks and potentially huge benefits for all of us – why not to try it?

PHYSIOLOGICAL AND MOLECULAR GENETIC EFFECTS OF TIME-VARYING ELECTROMAGNETIC FIELDS ON HUMAN NEURONAL CELLS

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