HBOT cancer treatment

What is a hyperbaric chamber? It is a device that a person enters in order to have oxygen under pressure given to them.

There is definite research showing the benefits of hyperbaric for a variety of complaints from decubitus ulcers (bedsores) and diabetic non-healing wounds to cancer treatment [1, 2] For cancer treatment, oxygen makes cancer cells weaker and less resistant to treatment. [3, 4]

Dominic D’Agostino of the University of South Florida has done research for the Department of Defense for work with Navy SEALS. His work shows that a ketogenic diet and hyperbaric oxygen therapy prolong survival in mice with systemic metastatic cancer. [5] In fact, this work shows a ketogenic diet with hyperbaric oxygen stops the tumor growth progression.

But a good hard shell hyperbaric chamber will cost around $75,000. (That’s the price of a very nice new BMW!) Taking time out of the day to drive to a clinic and paying for the use of a hard shell? Who has that much time? So what are the alternatives?

Manfred von Ardenne, a student of Otto Warburg, investigated the delivery of oxygen to the patient in what he called the “Oxygen Multistep Therapy” or O2MT which evolved into at home therapy called “Exercise With Oxygen Therapy” or EWOT. Dr. Ardenne found that this therapy stimulated the immune system, impacts microcirculation, increases oxygen status and improves the overall energetic status. [6]

This work is so impressive that Warburg wrote a letter to von Ardenne stating: “In these last few years you have certainly reached the peak of cancer research; I certainly know of no single book in the whole of cancer research in which anyone else has tackled the therapy problem with the same energy and breadth. My instinct tells me that, in the long run, your victory is certain.” [6]



. 1998 Oct 24; 317(7166): 1140–1143.
PMCID: PMC1114115
PMID: 9784458
ABC of oxygen

Hyperbaric oxygen therapy

Over the past 40 years hyperbaric oxygen therapy has been recommended and used in a wide variety of medical conditions, often without adequate scientific validation of efficacy or safety. Consequently a high degree of medical scepticism has developed regarding its use. The Undersea and Hyperbaric Medical Society approves use of hyperbaric oxygen for a few conditions for which there is thought to be reasonable scientific evidence or well validated clinical experience. In these conditions early referral is essential.

Therapeutic uses of hyperbaric oxygen

Strong scientific evidence

Main treatment

  • Decompression sickness
  • Arterial gas embolism
  • Severe carbon monoxide poisoning and smoke inhalation

Adjunctive treatment

  • Prevention and treatment of osteoradionecrosis
  • Improved skin graft and flap healing
  • Clostridial myonecrosis

Suggestive scientific evidence

Adjunctive treatment

  • Refractory osteomyelitis
  • Radiation induced injury
  • Acute traumatic ischaemic injury
  • Prolonged failure of wound healing
  • Exceptional anaemia from blood loss

Hyperbaric oxygen has been shown ineffective in diseases such as multiple sclerosis and dementia, but it continues to be used despite the risks of the treatment. For conditions where its use remains unproved—for example, rheumatoid arthritis, cirrhosis, and gastroduodenal ulcer—hyperbaric oxygen should be used only in the context of well controlled clinical trials.

Biochemical and physiological effects

At sea level the plasma oxygen concentration is 3 ml/l. Tissues at rest require about 60 ml of oxygen per litre of blood flow (assuming normal perfusion) to maintain normal cellular metabolism, although requirements vary between tissues. At a pressure of 3 atmospheres (304 kPa) dissolved oxygen approaches 60 ml/l of plasma, which is almost sufficient to supply the resting total oxygen requirement of many tissues without a contribution from oxygen bound to haemoglobin. This has advantages in situations such as carbon monoxide poisoning or in severe anaemia where difficult crossmatching or religious belief prevents blood transfusion.

Cellular and biochemical benefits of hyperbaric oxygen

  • Promotes angiogenesis and wound healing
  • Kills certain anaerobes
  • Prevents growth of species such as Pseudomonas
  • Prevents production of clostridial alpha toxin
  • Restores neutrophil mediated bacterial killing in previously hypoxic tissues
  • Reduces leucocyte adhesion in reperfusion injury, preventing release of proteases and free radicals which cause vasoconstriction and cellular damage

Oxygen at 300 kPa increases oxygen tension in arterial blood to nearly 270 kPa and in tissue to about 53 kPa. This improves the cellular oxygen supply by raising the tissue-cellular diffusion gradient. The hyperoxia has potential benefits including improved angiogenesis. The formation of collagen matrix is essential for angiogenesis and is inhibited by hypoxia. In irradiated tissue hyperbaric oxygen is more effective than normobaric oxygen at raising tissue partial pressure of oxygen and promoting angiogenesis and wound healing. The healing process may also be helped in non-irradiated tissues with compromised perfusion, but this requires further validation.

Advice on the nearest suitable UK unit and help to coordinate the management can be obtained from the Institute of Naval Medicine, Gosport (24 hour emergency number 0831 151523, daytime inquiries 01705 768026)

The value of hyperbaric oxygen therapy in decompression illness and arterial gas embolism depends on the physical properties of gases. The volume of a gas in an enclosed space is inversely proportional to the pressure exerted on it (Boyle’s law). At 300 kPa bubble volume is reduced by about two thirds. Any intravascular bubbles causing obstruction move to smaller vessels, which reduces extravascular tissue damage. Dissolution of the gas bubble is enhanced by replacing the inert gas in the bubble with oxygen, which is then rapidly metabolised by the tissues.

Availability and administration

Multiplace chambers are available in a few NHS hospitals (Aberdeen, Craigavon, Newcastle upon Tyne), Royal Navy centres, private units, police diving units, professional diver training schools, and sites associated with the North Sea oil industry. The United States has over 250 facilities.

Comparison of monoplace and multiplace hyperbaric oxygen chambers


  • Claustrophobic environment;limited access to patient
  • Whole chamber containshyperbaric oxygen,increasing fire risk
  • Lower cost
  • Portable


  • More room; assistant canenter to deal with acuteproblems such aspneumothorax
  • Hyperbaric oxygen via tightfitting mask—chamber gascan be air (reduced fire risk)
  • Risk of cross infection whenused for ulcers etc

Often early treatment is essential for maximum benefit. This poses appreciable practical problems as severely ill patients may have to be transported long distances and may require intensive medical support, including mechanical ventilation, between treatment sessions. It is important to discuss the potential benefits and risks for each patient with the regional hyperbaric oxygen facilities.

Multioccupancy chambers are required for critically ill patients who require an attendant within the chamber and are usually used for acute problems. Monoplace chambers can be used to treat patients with chronic medical conditions. Hyperbaric oxygen is inhaled through masks, tight fitting hoods, or endotracheal tubes.

Inside the chambers pressure is usually increased to about 250-280 kPa, equivalent to a depth of 15-18 m of water. The duration of treatment varies from 45 to 300 min and patients may receive up to 40 sessions. Appropriate monitoring is essential during treatment, and facilities for resuscitation and immediate mechanical ventilation should be available.

Dangers of hyperbaric oxygen

The potential risks and risk-benefit ratio of hyperbaric oxygen have often been underemphasised in therapeutic trials. The side effects are often mild and reversible but can be severe and life threatening. In general, if pressures do not exceed 300 kPa and the length of treatment is less than 120 minutes, hyperbaric oxygen therapy is safe. Overall, severe central nervous system symptoms occur in 1-2% of treated patients, symptomatic reversible barotrauma in 15-20%, pulmonary symptoms in 15-20%, and reversible optic symptoms in up to 20% of patients.

Reversible myopia, due to oxygen toxicity on the lens, is the commonest side effect and can last for weeks or months. Epileptic fits are rare and usually cause no permanent damage. A suggested carcinogenic effect of hyperbaric oxygen has not been substantiated in extensive studies.

Risks of hyperbaric oxygen

Fire hazard

Most common fatal complication

General features

  • Claustrophobia
  • Reversible myopia
  • Fatigue
  • Headache
  • Vomiting


  • Ear damage
  • Sinus damage
  • Ruptured middle ear
  • Lung damage

Oxygen toxicity

  • Brain
    •  Convulsions
    •  Psychological
    • •  Lung
    •  Pulmonary oedema,haemorrhage
    •  Pulmonary toxicity
    •  Respiratory failure (may beirreversible when due topulmonary fibrosis)

Decompression illness

  • Decompression sickness
  • Pneumothorax
  • Gas emboli

Pneumothoraces must be adequately drained before treatment with hyperbaric oxygen. Pulmonary oxygen toxicity with chest tightness, cough, and reversible falls in pulmonary function may occur with repeated treatment, particularly in patients exposed to high oxygen levels before treatment. Oxygen toxicity can be prevented in most tissues by using air in the chamber for 5 minutes every 30 minutes. This allows antioxidants to deal with free oxygen radicals formed during the hyperoxic period.

Therapeutic uses

Decompression sickness and arterial gas embolism

When divers surface too rapidly the partial pressure of nitrogen dissolved in the tissues may exceed the ambient atmospheric pressure sufficiently to form gas bubbles in the blood and the tissues. Although less common, rapid ascent to over 5500 m can result in high altitude decompression sickness.

Decompression sickness may produce mild problems such as rash or joint pain or be more serious with paralysis, confusion, convulsions, and ultimately death secondary to blockage of vital blood vessels. Hyperbaric oxygen is the main treatment, and its efficacy has been validated by extensive clinical experience and scientific studies. Recompression rapidly alleviates the symptoms, and tables are available to determine safe periods for subsequent decompression. Treatment should be started as soon as possible and given in sessions of 2-5 hours until the symptoms have resolved.

Air may also enter the circulation during placement of arterial and venous catheters, cardiothoracic surgery, haemodialysis, or mechanical ventilation. Although no formal trials support the use of hyperbaric oxygen in air embolism, the well established physical properties of gases and extensive clinical experience justify its use as the primary treatment. Treatment should begin immediately at pressures of 250-300 kPa for 2-5 hours. Benefit is reported when hyperbaric oxygen therapy begins several hours after the onset of air embolism but further trials are required to establish the delay after which hyperbaric oxygen is no longer of value.

Carbon monoxide poisoning

Carbon monoxide poisoning is an important cause of death from poisoning, particularly in the United States. Carbon monoxide binds to haemoglobin with an affinity 240 times that of oxygen. This reduces the oxygen carrying capacity of the blood. Unoccupied haemoglobin binding sites have an increased affinity for oxygen, further reducing the availability of oxygen to the tissues. In addition, carbon monoxide binds to the large pool of myoglobin increasing tissue hypoxia. Hyperbaric oxygen provides an alternative source of tissue oxygenation through oxygen dissolved in the plasma. It also facilitates dissociation of carbon monoxide from the haemoglobin and myoglobin; the carboxyhaemoglobin half life is 240-320 min breathing air, 80-100 min breathing 100% oxygen, and about 20 min with hyperbaric oxygen. In addition, hyperbaric oxygen dissociates carbon monoxide from cytochrome c oxidase, improving electron transport and cellular energy state.

Symptoms of carbon monoxide poisoning

  • Loss of consciousness
  • Neurological abnormalities
  • Myocardial ischaemia
  • Pulmonary oedema
  • Metabolic acidosis
  • Headache
  • Nausea
  • Delayed neuropsychological features (often permanent)

Controlled studies comparing hyperbaric oxygen and normobaric 100% oxygen in the acute and delayed effects of carbon monoxide poisoning have produced conflicting results, although some benefit was seen in patients who experienced loss of consciousness or neurological abnormality.

The clinical severity of carbon monoxide poisoning does not correlate well with carboxyhaemoglobin concentrations

If carbon monoxide poisoning results in unconsciousness, convulsions, neurological impairment (including abnormal gait or mental state test results) or severe metabolic acidosis the case should be discussed with the nearest regional centre. A single session of hyperbaric oxygen therapy will usually reverse the acute, potentially life threatening effects of carbon monoxide poisoning, but additional treatments may be needed to reduce the delayed neuropsychological sequelae. Patients with less severe poisoning should be treated with 100% oxygen.

Necrotising infections and osteomyelitis

The primary treatment of myonecrosis and gas gangrene of soft tissues resulting from clostridial infection and alpha toxin production is surgical debridement and antibiotics. However, experimental evidence and clinical experience suggest that adjunctive treatment with hyperbaric oxygen improves systemic illness and decreases tissue loss by demarcating the border between devitalised and healthy tissue. This reduces the extent of surgical amputation or debridement. Controlled trials of hyperbaric oxygen and normobaric 100% oxygen are not available. In necrotising fasciitis (rapidly progressive skin infection without muscle disease) retrospective studies suggest that hyperbaric oxygen is beneficial in combination with surgical debridement but prospective controlled trials are lacking.

Hyperbaric oxygen is also claimed to be helpful in refractory osteomyelitis. Animal experiments show improved healing of osteomyelitis compared with no treatment, but the effect is no better than that with antibiotics alone and the two treatments have no synergistic effect. Uncontrolled trials of surgery and antibiotics combined with hyperbaric oxygen in refractory osteomyelitis have reported success rates of as high as 85%, but controlled trials are needed.

Post radiation damage

Soft tissue radionecrosis and osteonecrosis after surgery on irradiated mandibles are reduced by hyperbaric oxygen. In a controlled study comparing osteoradionecrosis at six months postoperatively, the incidence was 5% in patients receiving 30 preoperative hyperbaric oxygen treatments compared with 30% in patients who received only preoperative antibiotics. A similar improvement in wound healing after surgery has been shown in patients with irradiated tissue who receive preoperative hyperbaric oxygen therapy. Normobaric 100% oxygen does not seem to confer the same benefits. The higher partial pressures achieved with hyperbaric oxygen may stimulate new vessel growth and healing in damaged irradiated tissue which has lost the capacity for restorative cellular proliferation.

To prevent mandibular osteonecrosis after surgery on irradiated facial and neck tissue 30 preoperative 90 minute sessions and 10 postoperative sessions are recommended

Skin grafts, flaps, and wound healing

In poorly vascularised tissue hyperbaric oxygen improves both graft and flap survival compared with routine postoperative surgical care alone. The effect of normobaric 100% oxygen was not examined in these studies. In the United States problem wounds are the commonest indication for a trial of adjunctive hyperbaric oxygen therapy and include diabetic and other small vessel ischaemic foot ulcers. Several studies have shown improved healing and a lower incidence of amputation with 4-30 sessions.

Hyperbaric oxygen should be considered for problem wounds if the facility is readily available

Other indications

Hyperbaric oxygen has been used successfully to treat haemorrhagic shock in patients who refuse blood on religious grounds or for whom suitable blood was not available. Similarly, there is evidence for benefit in acute traumatic ischaemic injuries including compartmental syndromes and crush injuries.

Conditions which do not benefit

Hyperbaric oxygen has been tried in numerous conditions and is often reported to be beneficial. However, in many of these situations the scientific evidence is flimsy and use should be restricted to randomised controlled trials. Hyperbaric oxygen has been clearly shown not to be beneficial in several diseases including multiple sclerosis and senility.


  • Lack of randomised controlled trials makes it difficult to assess the efficacy of hyperbaric oxygen in many diseases
  • Side effects are usually mild but can be life threatening
  • Clear evidence of benefit has been found in decompression sickness and a few other conditions
  • Much work remains to be done to establish the timing, indications, and therapeutic regimens required to obtain the best clinical and cost effective results
  • The cellular, biochemical, and physiological mechanisms by which hyperbaric oxygen achieves beneficial results are not fully established

The suggestion that hyperbaric oxygen may be beneficial in multiple sclerosis arose from animal work suggesting that it improved experimental allergic encephalomyelitis and several uncontrolled studies suggesting disease remission in humans with multiple sclerosis. In 1983, a small controlled trial reported significant benefit, and large numbers of patients with multiple sclerosis were treated with hyperbaric oxygen. Since this initial trial at least 14 trials, of which eight are high quality randomised controlled studies, have been published. In the eight high quality studies the patients had chronic stable or chronic progressive multiple sclerosis, had at least 20 sessions of therapy for 90 minutes over four weeks, and were adequately assessed with evoked potentials and for functional and disability state. Only one study showed a benefit from hyperbaric oxygen.

No convincing evidence exists for using hyperbaric oxygen in thermal burns. In the only randomised controlled trial of hyperbaric oxygen and usual burn care the length of hospital stay, need for autografting, and mortality were virtually identical with both treatments.


P Wilmshurst is consultant cardiologist at Royal Shrewsbury Hospital, Shrewsbury.

The ABC of Oxygen is edited by Richard M Leach, consultant physician, department of intensive care, and P John Rees, consultant physician, department of respiratory medicine, Guy’s and St Thomas’s Hospitals Trust, London.

The pictures of the hyperbaric chamber and necrotic heel of diabetic patient were downloaded from the internet with permission from Proteus Hyperbaric Systems. The picture of gas gangrene was downloaded with permission from St Joseph Medical Center, Fort Wayne, Indiana, USA

Articles from The BMJ are provided here courtesy of BMJ Publishing Group


    • Article





Exciting News

Exciting New Benefits of Hyperbaric Oxygen Therapy

At Whitaker Wellness, we’ve been using and extolling the benefits of hyperbaric oxygen therapy for decades. But the earliest documented use of hyperbaric therapy dates back to 1662, when a British physician treated patients with respiratory conditions in a chamber filled with compressed air. America’s first hyperbaric chamber was built in 1861, and in 1928 Dr. Orval Cunningham constructed a five-story, 900-ton pressurized spherical chamber, where scores of patients could stay for long periods. Criticism by the American Medical Association, however, undermined enthusiasm for hyperbarics, and the “steel ball hospital” was eventually dismantled for scrap metal.Conventional medicine’s interest faded, but research continued. In 1939, the US Navy began administering 100 percent oxygen under pressure—true hyperbaric oxygen therapy (HBOT)—to treat decompression illness from diving accidents. During the next three decades, European doctors discovered that the benefits of hyperbaric oxygen therapy extended to carbon monoxide poisoning, stroke, radiation injury, multiple sclerosis, wound healing, bone infections, and more.

Although bias among US physicians endures, thousands of scientific papers have been published on hyperbaric oxygen therapy’s benefits for dozens of serious conditions.

Wound- and Injury-Healing Wonder

Cecil came to us in a last-ditch effort to save his leg. Antibiotics, intensive wound care, and amputation of several toes failed to stem a festering diabetic ulcer, and he was told the leg had to go. Within days, the benefits of hyperbaric oxygen therapy were evident. HBOT coupled with sugar dressings worked quickly and the infected ulcer began to close. His wound eventually healed, and amputation was avoided.

This is not an isolated case. Hyperbaric oxygen therapy benefits wounds of all kinds. When 100 percent oxygen is breathed under pressure, it dissolves in all the body’s fluids and saturates tissues with oxygen. This massive influx reduces inflammation, curbs infection, signals the release of reparative stem cells and growth factors, and boosts production of collagen and new blood vessels (angiogenesis).

More benefits of hyperbaric oxygen therapy include faster recovery from muscle, ligament, and bone injuries and reduced post-exercise muscle fatigue and soreness—which explains HBOT’s popularity with Michael Phelps, Novak Djokovic, Tiger Woods, Terrell Owens, Darren Sharper, and other elite athletes.

Diabetic ulcers lead to 73,000 amputations annually, and who knows how many serious injuries are sustained every day. Just imagine how many limbs could be saved and how much pain and suffering eliminated with routine use of HBOT.

Another Benefit of Hyperbaric Oxygen Therapy: Stroke Recovery

Gary made some progress during his stint in a rehab facility following a serious stroke, but he was unable to drive, walk, or even stand without assistance. So he came to Whitaker Wellness for HBOT. By the time he returned home, hyperbaric oxygen therapy’s benefits were clear: His balance, strength, speech, and swallowing dramatically improved, and he no longer required a wheelchair.

Strokes cut off blood flow in the brain. Deprived of oxygen and glucose, brain cells in the immediate area die and those nearby go into “hibernation”—they’re still alive but nonfunctioning. No therapy can raise the dead, but by flooding the brain with oxygen, HBOT provides the energy needed to revive stunned neurons. It also reduces swelling and activates cell regeneration and angiogenesis, which promote the brain’s ability to develop new connections and compensate for injury.

The ideal time to reap the benefits of hyperbaric oxygen therapy is immediately after a stroke, but that option is rarely offered. Fortunately, HBOT is valuable at any time. Israeli researchers conducted a trial of patients who had enduring deficits from strokes suffered six months to three years earlier. Forty treatments resulted in remarkable improvements in function and quality of life.

Strokes are a leading cause of long-term disability. Don’t all patients deserve a shot at this potentially life-altering treatment?

Hyperbaric Oxygen Therapy Benefits TBIs

Hyperbaric oxygen therapy is, hands down, the best available treatment for another common cause of brain damage: traumatic brain injury (TBI). One of our patients Curtis had lingering problems stemming from a TBI sustained in a childhood bicycle accident. At age 22, his parents brought him to the clinic for HBOT and neurofeedback. After treatment he wrote, “Taking on challenges became easy for me. My coordination was immensely better, and I started using my left hand more. This was an amazing opportunity for me.”

Hall of Fame quarterback Joe Namath is also a proponent of HBOT, based on his own personal experience and his concern about the TBI-related degenerative brain diseases in more and more retired pro football players. Military veterans suffering with TBI or post-traumatic stress disorder (PTSD) rave about HBOT as well.

You’d think neurologists, the Veteran’s Administration, and the National Football League would be on the frontlines promoting the benefits of hyperbaric oxygen therapy, but that isn’t case—for all the wrong reasons. As Kenneth Stoller, MD, explained in a 2015 article, “HBOT is an efficacious, benign and humanitarian way to affect brain repair but it has not been adopted because it lacks patent protection and has no large corporate sponsors. It has also met interference because other agendas are present be they the protection of the status quo, myopic budgetary constraints, or perceived liability issues.”

Hyperbaric Oxygen Therapy Benefits Nearly Everyone

HBOT relieved N.L.’s post-herpetic neuralgia pain and William’s excruciating diabetic neuropathy. It rapidly healed Stephanie’s facial burns and E.B.’s facelift incisions. Cynthia’s Lyme disease-related problems improved dramatically after 40 treatments, and G.G.’s rosacea cleared up with just one. Liam, a six-year-old with autism, became more social and verbal following HBOT and neurofeedback. Ashley had notable improvements in her balance, sensation, vision, and other symptoms of multiple sclerosis.

This therapy has also been demonstrated to improve quality of life in patients with fibromyalgia, terminate acute migraines and cluster headaches, reverse sudden sensorineural hearing loss, and reduce symptoms of ulcerative colitis. HBOT even has an adjunct role in cancer treatment: It sensitizes tumors to radiation and reduces adverse effects of chemo/radiation.

Whitaker Wellness’s hyperbaric department has treated thousands of patients with this safe, versatile therapy. It can cause uncomfortable pressure in the ears and claustrophobia (other safety issues are rare and overblown), but most patients tolerate it well and enjoy their one-hour sessions watching videos, reading, or simply relaxing.

Don’t expect to hear about the benefits of hyperbaric oxygen therapy from your doctor; old biases die hard. But for stubborn conditions that don’t respond to conventional treatments, HBOT is a game changer.

Where to Get Hyperbaric Oxygen Therapy

HBOT is a safe, effective treatment for wounds, strokes, head injuries, and many other conditions.


Nobody enjoys the little signs of aging we see when looking in the mirror each morning. We spend billions of dollars a year on products and surgeries to help us look and feel younger: hair re-growth products, dyes to hide the grey, anti-wrinkle face and eye creams, cosmetic injections, surgeries and more.

Yet none of these products or procedures actually stop the biological clock, or regrow that within us which has diminished with age. Wouldn’t it be wonderful if after generations of searching, we actually did discover a true fountain of youth? As noted in Desert Health’s lead story, Dr. Andrews’ work certainly looks promising and may lead to that discovery in our lifetime.

In today’s modern medicine, there is a therapy that is proven to offer anti-aging benefits through healing or regrowth of damaged cells: hyperbaric oxygen therapy (HBOT). In HBOT, patients breathe 100% pure oxygen while the pressure of the treatment chamber is slowly increased. Pressurized oxygen is delivered into the chamber, which increases the pressure of oxygen within a person’s body as much as 15 times normal tissue saturation. Each cell is literally saturated with 100% pure oxygen, accelerating the body’s natural healing processes.

Oxygen therapy can help to jump start the body’s antioxidant defenses, boost metabolism, and counteract low oxygen levels that lead to sluggish cell activity and oxidative stress. Research has shown that it can also help to improve the efficiency of hemoglobin in transporting oxygen around the body; improve blood flow by helping to keep cell membranes flexible; suppress inflammation; and detoxify and fight infection by destroying bacteria, viruses, parasites and fungi that thrive in low-oxygen environments.

HBOT is also commonly used in treating many age-related diseases and conditions such as stroke, rheumatoid Arthritis and cancer treatment recovery.

In addition to its often lifesaving work in the medical industry, HBOT is gaining widespread recognition for its success in treating a breadth of cosmetic concerns.  Regular treatment is widely thought to increase aging skin elasticity and to stimulate collagen production which, over time, can improve skin texture and reduce the appearance of fine lines, wrinkles, and scars. Plastic surgeons often prescribe the therapy to enhance recovery from reconstructive surgery.

But true aging goes beyond those fine lines and wrinkles.

Scientists have found that the chromosomes in our cells progressively shorten each time the cell divides. Eventually, the chromosomes can shorten no further and stop dividing. When this happens, the cells become senescent (sleepy) and die. In premature aging, the lifespan is shortened due to the effects of various stressors to the human body. The most obvious, and often the most common, are alcohol, tobacco, and drugs. These substances have a tremendous aging effect on the human body and can cause progressive ‘wounding.’

In his book, The Oxygen Revolution, Dr. Paul G. Harch expresses that hyperbaric oxygen therapy will “likely become most appreciated by those Baby Boomers whose life spans have been compromised by years of drug experimentation in the 1960s and 1970s.”  Wounds in the brain register as areas of low blood flow and low oxygenation, which cause decreased neurological function. Most commonly, this decreased neurological function leads to the premature aging diagnosis we call dementia.

Dr. Harch calls HBOT a “generic drug for repair of brain wounds.” The stereotypic chronic brain wound typically responds well to low pressures of hyperbaric oxygen treatments. What Drs. Neubauer, Harch, and others have shown in the past 30 years is that these premature aging wounds can be repaired for improvement neurologically, cognitively, behaviorally, and emotionally.

Repairing these chronic wounds is considered by many to be a reversal of premature aging by use of HBOT, aiding in prolonging longevity and an enhanced quality of life.

Considering that it delivers a natural substance which helps our body repair itself and has many significant medical benefits, including mending our DNA, it is easy to see why a growing population is utilizing hyperbaric oxygen as an anti-aging therapy.

For more information on hyperbaric oxygen therapy for anti-aging and other conditions, visit or call 973-620-8100

Sources: 1) The Oxygen Revolution. Hyperbaric Oxygen Therapy: The Groundbreaking New Treatment. Paul G. Harch, MD. 2007. 2); 3)