The human body is a sophisticated system that functions much like a machine. Like most machinery, our bodies need some periodic maintenance. Since pure oxygen and the human body go hand in hand, many individuals, including A-listers, celebrities, divers, athletes, astronauts, and pilots, are turning to Hyperbaric Oxygen Therapy (HBOT) — for all the right reasons.
Do you often zone out in front of the television while watching some of your all-time favorite shows? Try replacing your couch with a Hyperbaric Oxygen Chamber! Hyperbaric Oxygen Therapy has been shown to have curative and restorative effects. Though HBOT has recently been technologically revolutionized for the ever-evolving market, the use of oxygen therapy in medicine actually has ancient roots.
Leading scientists and medical professionals consider Hyperbaric Oxygen Therapy is a game-changer, and we couldn't agree more. There's a reason why Cristiano Ronaldo, Madonna, Justin Bieber, Usher, LeBron James, Michael Phelps, and Mohamed Salah have made hyperbaric oxygen therapy an essential part of their daily routines.
Eager to experience the wonders of hyperbaric oxygen chambers, but don't know where to start? Don't worry; you're in safe hands. Below, we'll reduce Hyperbaric Oxygen Therapy (HBOT) to its bare bones so you can carefully understand what it's all about. Once you have all the relevant information about hyperbaric treatment at your disposal, you can choose a suitable chamber and begin taking advantage of this pure oxygen therapy to the fullest!
Considering that the Internet is flooded with how-to-guides, tips and tricks, and unwanted suggestions, you may wonder what makes this blog any different. Readers, the following guide will not only teach you how oxygen chambers work but will also help you find the one that suits your budget!
The Science Behind Hyperbaric Oxygen Therapy (HBOT)
Since oxygen is essential for maintaining, repairing, and improving cellular function in every cell in the body, hyperbaric oxygen therapy uses pressurized oxygen to a very high level. The inhalation of oxygen at more elevated pressures than sea level helps flood the body with enriched oxygen, creating a cascade of favorable advantages. The Undersea Hyperbaric Medical Society (UHMS), the Centers for Medicare and Medicaid Services (CMS), and other providers like Airpuria agree that via hyperbaric oxygen therapy, the patient breathes up to 100% pure oxygen while inside pressurized hyperbaric chambers with a pressure of 1.4 atmospheres absolute (ATA) or higher.
Surprisingly, several gas laws and physiological and biochemical consequences form the basis for the mechanisms of action that work in hyperbaric oxygen therapy. According to Boyle's law, the pressure of a gas and its volume are inversely related, while the temperature of the gas remains the same. This is a foundational idea for a great deal of the hyperbaric treatment that is available today.
According to Henry's law, the quantity of gas embolism that may be dissolved in a liquid or irradiated tissue depends directly on the partial pressure of that air or gas embolism when it is in contact with the fluid or body tissues. Increased oxygen tension results from hyperbaric oxygen medical treatments based on this principle. According to Dalton's law, each component of a mixed inert gas exerts air pressure proportionate to the amount of the gas it contributes to (partial air pressure).
Most of the oxygen transported by the blood vessels is coupled to hemoglobin, which under increased atmospheric pressure is around 97%. As stated in Henry's rule, oxygen may be transported in the blood plasma at greater pressure; this makes it possible for pure oxygen to reach the spaces it would not normally go, promoting the wound healing process. This is likely to be the problem for people with preexisting disorders that reduce the amount of oxygen their blood vessels can transport.
What Conditions Can HBOT Treat?
The use of hyperbaric oxygen therapy is effective for the primary treatment of a broad range of injuries, diseases, and other ailments. However, the FDA has only authorized hyperbaric oxygen therapy for 14 different indications. A significant body of data indicates the efficacy of hyperbaric oxygen therapy in healing additional conditions, even though the others have not yet been licensed.
Approved Conditions by the FDA
The conditions below are all FDA approved to be treated using HBOT.
Air or Gas Embolism
Diabetic Foot Ulcers
Thermal Burns (Severe)
Carbon Monoxide Poisoning
Radiation Body Tissue Damage
Acute Traumatic Ischemia
Failed Skin Grafts & Flaps
Central Retinal Artery Occlusion
Necrotizing Soft Tissue Infections
Chronic Refractory Osteomyelitis
Diabetic Lower Extremity Wounds
Sudden Sensorineural Hearing Loss
Conditions that Lack FDA Approval
The conditions below have undergone studies that suggest they can be treated by HBOT, but are not yet FDA approved.
Acute Severe Blood Loss
Spinal Cord Injuries
Anoxic Brain Injury
Soft Tissue Infection
Arterial Gas Embolism
Alpha Toxin Production
Tissue Death (Irradiated Tissue)
Glycemic Condition (Blood Glucose)
Chronic Fatigue Syndrome
Cancer (Treatment Synergy)
Pulmonary Oxygen Toxicity
Inflammatory Bowel Disease
Surgery Preparation & Recovery
Complex Regional Pain Syndrome
Concussion and Traumatic Brain Injury
Risks and Side Effects from Too Much Oxygen Therapy and Recovery
Hyperbaric oxygen therapy is a natural treatment with no significant number of dangers or adverse effects linked with it — quite a low risk compared to other available medical therapies for critically ill patients. Only in unusual circumstances do patients encounter adverse effects, such as pressure injuries to the ear, low blood sugar, or transient eye-light alterations. Middle Ear Barotrauma (MEB) is a frequent side effect caused by Eustachian Tube Dysfunction. Since HBOT is not a surgical procedure, no downtime or wound healing process is required after individual treatment sessions!
Types of Hyperbaric Chambers
Patients in hyperbaric oxygen therapy get 100% pure oxygen in a pressurized vessel, known as a chamber. A chamber designed for a single person is known as a monoplace, while a chamber intended to treat many individuals simultaneously is known as a multiplace chamber. A device known as a "mild" or "soft" chamber is an alternative to the conventional monoplane chamber. Nevertheless, it is not the same regarding its scope of service, applications, or efficiency.
Both monoplace and multiplace hyperbaric chambers are FDA approved to treat 14 conditions; however, many other indications have been or are now being researched with these chambers (more on this later). On the other hand, mild or soft hyperbaric chambers have only been authorized by the FDA to treat acute mountain sickness. Speak to an expert to learn more about these wonderful devices.
Key Takeaways So Far
Hyperbaric Oxygen Therapy (HBOT)
Involves breathing 100% pure oxygen in a pressurized chamber at 1.4 atmospheres absolute (ATA) or higher
Based on principles of Boyle's Law, Henry's Law, and Dalton's Law
Increases oxygen transportation in blood plasma, promoting wound healing
Conditions Treated by HBOT
FDA-approved for 14 conditions, including crush injury, diabetic foot ulcers, and carbon monoxide poisoning
Many other conditions show promise but lack FDA approval, such as stroke, arthritis, and Lyme disease
Is Hyperbaric Oxygen Therapy Right For You?
Almost every individual can potentially benefit from hyperbaric oxygen therapy. As a first step in determining whether or not this ground-breaking treatment is appropriate for achieving your health objectives, schedule a consultation with a medical expert to get a comprehensive assessment. Make the most of this opportunity by asking a wide range of in-depth questions.
Suppose it is confirmed that hyperbaric oxygen therapy is a suitable treatment. We're excited for you! In that case, we recommend buying the right chamber from Airpuria's diverse collection of Oxyhealth chambers: Vitaeris 320 ®, Solace 210 ®, Respiro 270 ®, Quamvis 320 ®, and Fortius 420 ®. Below you will find a breakdown of costs associated with each Oxyhealth chamber. For detailed information about different types of hyperbaric oxygen chambers. Feel free to visit the link available for each product.
One of our most portable designs is one of our biggest chambers and is particularly well-liked by parents, doctors, celebrities, and professional athletes including LeBron James! The large chamber, which measures 32 inches in diameter, provides patients with total freedom of movement while adhering to our stringent and flawless safety criteria.
It also includes enough space for two people to self-treat simultaneously. During treatments, the chamber has a tamper-proof air-in inlet strategically positioned to ensure a steady circulatory airflow. It also has redundant pressure regulators that are tamper-proof.
The Vitaeris 320® is a functional piece of equipment that is perfect for use in clinics and patients' homes since the spacious interior gives patients the confidence they need while undergoing treatments. The inside of the chamber is illuminated by room light thanks to the presence of three patient viewing windows. The combination of a roomy layout and the medical-grade technology guarantees that the device's durability and usefulness will remain intact for many years.
Sale Price: $23,000.00
You Save: $3,000.00 (12%)
This moderate chamber is the lightest and most affordably priced option that meets our stringent safety requirements despite its very portable design, made possible by its double-sided 44-ounce urethane bladder and 21-inch-diameter construction.
Patients can self-treat and stay comfortable during the treatment process thanks to dual control valve technology and three extra-large patient viewing windows located around the room.
Room light also illuminates the inside of the chamber. It has a tamper-proof, strategically slanted air-in inlet and redundant pressure regulators to ensure a constant circulatory airflow throughout the space. This classic style, combined with cutting-edge medical technology, promises years of reliable service in terms of its longevity and functionality.
Sale Price: $9,000.00
You Save: $3,000.00 (25%)
This chamber provides enhanced mobility flexibility while compacting to fit into any area, thanks to its innovative design that combines use and comfort with a 27-inch diameter; in addition to the dual power valve technology for physician/self-treatment, the 44 oz. Double-sided urethane-coated polyester delivers an ergonomic design and meets our outstanding safety criteria.
The inside of the room is illuminated by room light thanks to the presence of three huge patient viewing windows. During treatments, the chamber has a tamper-proof air-in inlet strategically positioned to ensure a steady circulatory airflow. It also has redundant pressure regulators that are tamper-proof. Durability and functionality will be maintained over many years because of its a practical design concept and medical-grade components.
Sale Price: $15,000.00
You Save: $3,000.00 (17%)
The Quamvis320® is our newest and most revolutionary design. It is the most portable soft-walled chamber currently available on the market. A big, non-obstructive interior and a one-of-a-kind support system allow patients to quickly enter and depart the chamber, thanks to the chamber's vast interior and external frame, which measures 32 inches in diameter.
This chamber has space for two people and is furnished with dual pressure control valves, making it suitable for self-therapy and treatment by a medical professional. The chamber has a tamper-proof, strategically slanted air-in inlet and redundant pressure regulators to ensure a constant circulatory airflow throughout the space.
This chamber surpasses our most stringent safety criteria because of its reinforced ballistic nylon jacket and external "SafeSet" buckling mechanism. Despite these features, the chamber is suitable for clinical and personal usage. This cutting-edge design combined with medical-grade components assures users that the functionality will be safe and long-lasting for years.
Sale Price: $27,000.00
You Save: $3,000.00 (10%)
This chamber is both the second biggest and the most adaptable and is a customer favorite. Patients may be treated in an operating pressure range of up to 3.0 ATA (29 psi), which is standard with this device. This room is 62 inches long and has an impressive inside diameter of 42 inches.
Despite its sizable dimensions, the Fortius420 - EXP can be accommodated in most workplaces and medical facilities. The inside and outside of the hybrid alloy hyperbaric chamber have mirrored control panels. This specific chamber can emit 100 percent oxygen at up to 3.0 ATA using a hood assembly system, making the therapy risk-free for the patient and cost-effective for the clinicians.
Oxyhealth prioritizes timely delivery and can ship and install the chamber in as little as ten business days. EXP was created with safety measures and high industry standards in mind throughout the design process so that it would continue to operate normally for many years to come.
Sale Price: $120,000.00
You Save: $30,000.00 (20%)
Operating pressures of up to 3.0 ATA (29 psi) may be accommodated in this spacious and adaptable chamber, which can treat patients and medical professionals. Despite having an impressive inside diameter of 42 inches, this chamber is intended to be compact enough to fit in most offices and clinics.
The Fortius 420® provides amazingly secure functioning across various protocols, thanks to its mirrored controls both within and outside the device. In addition, this chamber can deliver oxygen at a concentration of one hundred percent at a pressure of up to three and a half atmospheres absolute (ATA), making it both economical for those administering the treatments, and risk-free for the patients.
This ground-breaking design and medical-grade technology promise durability and usefulness that will endure for years, and it can be supplied and installed in less than ten business days.
Sale Price: $117,000.00
You Save: $3,000.00 (3%)
The Fascinating History of Hyperbaric Oxygen Therapy (HBOT)
Due to the tight relationship between the beginnings of hyperbaric treatment and the development of diving medicine, the use of compressed gas in medical practice has truly ancient roots. The origins of diving are murky, according to our best knowledge. However, free diving (dives during which the diver does not breathe) for mother-of-pearl was a unique form of employment that dates back to as far as 4,500 B.C.
It is reported that in 320 B.C., Alexander the Great was placed in a glass barrel and plunged into the Bosphorus Straits. Around 1500 A.D., Leonardo da Vinci drew many different types of diving equipment.
Fun fact: Despite all his dive equipment artwork, it remains as one of his fantasies since none have been created or put into service.
Cornelius Drebbel, a Dutch inventor, is credited with creating the first genuine diving bell around 1620. It did not have a closed base and instead depended on the weight of the water above it to prevent air from escaping from the bell. The bell would be lowered into the water by a crane to ensure that it remained in the correct orientation after submerging.
A hose was used to pump air into the bell so that only fresh air would be contained inside it. This allowed surplus gases to escape from beneath the lip of the bell. As the bell descended, the air was pushed to maintain the passengers' comfort level. The bell was intended to serve as a foundation for free divers.
Even though oxygen wasn't discovered for another hundred years, hyperbaric treatment was already being utilized. In 1662, a British priest named Henshaw employed a system of organ bellows to vary the air pressure inside a sealed room called a domicilium. This domicilium had the capability of producing hyperbaric as well as hypobaric settings.
Henshaw felt that acute ailments would benefit from increased air pressure, while chronic problems would react better to lower air pressure. Although he did not have any scientific foundation for his views, he persisted in this belief. According to Henshaw, "In times of good health, this domicilium is advised as a good expedient to aid digestion, promote insensible respiration, improve breathing and expectoration, and therefore, is of great service for the avoidance of most maladies of the lungs."
Henshaw was decreasing the air pressure and not increasing the oxygen concentration. You will be surprised to learn that Sweden's pharmacist Carl Wilhelm Scheele discovered Oxygen in 1773, while the French scientist Antoine Lavoisier coined the term "oxygen" in 1777.
Hyperbaric medicine teams saw a rise in France after nearly two centuries (the 1830s). Increased circulation to the internal organs, improved cerebral blood flow, and feelings of well-being were among the benefits described by French physician Junod, who constructed a chamber in 1834 to treat pulmonary diseases with pressures of 2-4 ATA.
Patients with lung diseases including TB, tracheitis, laryngitis, and pertussis were treated in Pravaz's 1837 chamber, the biggest of its day. On top of that, patients with conjunctivitis, cholera, menorrhagia, deafness, and rickets were also treated. Later in 1860, the pioneering hyperbaric chamber was built in Canada. However, the first American chamber was constructed by Corning a year later in New York. "Nervous and associated ailments" were treated in this chamber.
Using Henry's Law, a French surgeon named Fontaine created the first portable hyperbaric operating theatre in 1877. According to Henry's Law, the pressure exerted by a gas above a liquid solution affects the degree to which the gas dissolves in the liquid. Hernia reduction, emphysema, chronic bronchitis, asthma, and anemia were all cited as the "ailments to cure" while using this chamber.
Twenty-seven surgeries were conducted in this portable chamber in only three months. After its first success, architects began designing a 300-seat hyperbaric surgical amphitheater to accommodate the growing demand for the procedure. Fontaine was the first medical martyr for hyperbaric medicine, having died in a tragic accident at the Pneumatic Institute; therefore, there was never any practical implementation of the proposals
After almost a decade, in 1885, the British Medical Journal published C. Theodore Williams's Lectures on the Compressed Air Bath and Uses in the Treatment of Disease, where he lauded the use of atmospheric air subjected to varying degrees of atmospheric pressure to heal ailments. He stated that this kind of treatment was one of the most significant breakthroughs in contemporary medicine and expressed his shock at the fact that it was disregarded in England.
Orval J. Cunningham, a Kansas-born physician, constructed the first chamber in the United States in 1921 in Lawrence, Kansas, during the latter days of World War I. He used the facility to provide medical care to those affected by the Spanish influenza outbreak sweeping over North America, affecting thousands of individuals in the region.
Cunningham postulated that the higher death rates found in individuals who lived at higher altitudes were due to atmospheric pressure or barometric influences and that these factors were to blame for the higher mortality rates. After noting that those who lived in the valley coped better than those in the mountains, he pursued this line of reasoning.
He saw dramatic changes in patients treated with HBO, particularly in individuals who were cyanotic and unconscious before receiving the treatment. The heat from open gas burners used to warm the chambers during the winter of 1923 caused the insulation to catch fire and melt, but before the blaze spread, all patients were safely evacuated. In a separate instance, a mechanical malfunction led to a total drop in blood pressure within the chamber, resulting in all patients' deaths.
However, this setback did not stop Cunningham's mission. He went on to treat ailments such as syphilis, diabetes mellitus, hypertension, and cancer while believing that anaerobic infections contributed to the development of each of these conditions. Cunningham constructed a massive chamber in 1928 in Cleveland, Ohio, along the shores of Lake Erie for one million dollars with the financial backing of a roller bearing manufacturer and capitalist, Henry H. Timken.
This Cunningham's Sanitarium or Steel Ball Hospital was a steel sphere that stood five stories tall, had a diameter of 64 feet, weighed 900 tons, and included 60 rooms.
Due to the increasing demand for Dr. Cunningham's treatments, the Bureau of Investigation of the American Medical Association (AMA) sent a request asking him to confirm his statements about the efficacy of hyperbaric therapy. However, Cunningham did not disclose the information or collaborate with the AMA, contributing to his reputation as a quack and a scam among the medical community. In 1937, the chamber was destroyed and sold for use as scrap during World War II.
Drager was the first person to investigate the use of compressed oxygen to treat decompression sickness. Behnke and Shaw were the ones who ultimately put his procedures into action in the late 1930s. The United States Navy first used hyperbaric oxygen treatment in 1939 to treat divers suffering from decompression illness, distinct from all other treatments discovered and performed in the past.
Following the end of World War II, the United States military carried out studies that increased their understanding of the survivable stresses. As a direct consequence of this, the use of HBOT (or simply HBO) rose during the latter half of the 1950s and the early 1960s. Drager was the first person to investigate the use of compressed oxygen to treat decompression sickness. Behnke and Shaw were the ones who ultimately put his procedures into action in the late 1930s.
The United States Navy first used hyperbaric oxygen treatment in 1939 to treat divers who were suffering from decompression sickness. This was distinct from all other applications of hyperbaric therapy done in the past. Following the end of World War II, the United States military carried out studies that increased their understanding of the survivable stresses. As a direct consequence of this, the use of HBOT (or simply HBO) rose during the latter half of the 1950s and the early 1960s.
Ite Boerema, a Dutch physician, came up with the concept of "flooding" the body's tissues with more oxygen in the 1950s. The cardiac surgeon Boerema collaborated with the Royal Dutch Navy on various surgical procedures using animals inside a hyperbaric oxygen chamber.
Because of the positive outcomes of his research, the University of Amsterdam decided to construct a big, spacious room equipped with a massive chamber so that he could carry out a variety of complex procedures on patients with lung collapse, chest pain, and heart disease.
Boerema and his colleagues were the pioneers who successfully used Hyperbaric Oxygen Therapy to treat clostridial myonecrosis (also known as gas gangrene or necrotizing soft tissue infection) in an experimental pig. Boerema published a report of terminally anemic pigs successfully treated with HBOT under the title "Life without blood." These pigs flourished inside the chamber even though there were no circulating red blood cells in their systems at any point throughout the experiment.
In 1967, the United States of America saw the birth of an organization known as the Undersea Hyperbaric Medical Society (UHMS), which mainly comprised current and former medical personnel from the United States Navy. Since the UHMS was concerned about the lack of scientific development and regulation, they established a Committee in the late 1970s tasked with conducting a comprehensive evaluation of all the current scientific information about HBOT.
They compiled a list of diseases for which high-volume oxygen therapy that recognized by insurance companies, including Medicare. Later, Dr. Richard A. Neubauer established Ocean Hyperbaric Neurologic Center in 1972 to treat patients and report on the efficacy of hyperbaric oxygen treatment, despite critics' criticism. He did this to manage various conditions affecting the central nervous system. Today, Neubauer is widely regarded as the founder of HBOT in neurology.
Dr. Paul Harch started an in-depth investigation of brain decompression sickness (also known as DCI) and investigated divers who suffered from this condition. The fact that it was not excess gas but rather ischemic brain damage that was being treated was proven by two diving instances; Harch realized this was the situation. Igor Gamow, who had previously worked as a professor of microbiology, came up with and received a patent for the Gamow Bag in 1990.
Climbers experiencing acute mountain sickness (AMS) were given access to successful treatment in the form of a low-pressure hyperbaric bag. This portable chamber was inflated to around 2 pounds of pressure per square inch using a foot pump, designed to accommodate a single individual by simulating a vertical drop of up to 7,000 feet.
Today, individuals are becoming more and more aware of the many advantages of hyperbaric oxygen therapy, as well as its effectiveness in treating disorders such as autism, traumatic brain injury (TBI), stroke, and others that are mentioned under "Internationally Treated Conditions". The Food & Drug Administration (FDA) has approved 14 conditions to be treated with HBOT, allowing companies like Airpuria to give individuals a chance to benefit from oxygen therapy.
This is not the end of the story. The most fundamental scientific principles, such as gas laws, are still used today as the foundation for hyperbaric oxygen therapy; however, as the hyperbaric medicine team makes technological advances, the field of hyperbaric medicine will continue to develop and advance in the years to come. But for now, the oxygen genius of the future is already here!
Frequently Asked Questions
Whether you're looking for a hyperbaric oxygen chamber for commercial or residential space, finding a reputable supplier is the first step. Regardless of whether you decide to purchase a product from the list above or not, read on to find all the answers to your questions!
How Does Hyperbaric Therapy Treat Carbon Monoxide Poisoning?
When treating carbon monoxide poisoning using extra oxygen therapy, the goal is to get the patient's oxygen level back up to normal as rapidly as possible while lowering the quantity of carbon monoxide poisoning in blood vessels. Inhaling 100 percent more oxygen inside a chamber where the air pressure is about 2-3 times greater than average is the treatment for carbon monoxide poisoning. This expedites the process of the blood replacing the carbon monoxide poisoning it contains with oxygen dissolved.
What is the Definitive Treatment for Decompression Sickness?
Hyperbaric oxygen therapy, also known as the administration of pure oxygen at an increased pressure much greater than atmospheric pressure, is the gold standard for treating decompression sickness (DCS). It lowers the bubbles in the circulation, saturates the body tissue with extra oxygen, and brings down the potentially life-threatening swelling. As a general rule, you must seek treatment as quickly as possible since the symptoms of DCS may pose a serious risk to one's life.
Is Mechanical Ventilation a Safe Method during HBOT?
Mechanical ventilation is the safest method. The most common injuries that need breathing are arterial gas embolism, carbon monoxide poisoning, and soft tissue infections. The patient's lungs are supplied with more oxygen via the use of the ventilator, which forces a combination of air and oxygen into the airways. To prevent the air sacs in the lungs from collapsing, the ventilator can maintain a continuous quantity of positive end-expiratory pressure (PEEP), also known as low pressure.
Is HBOT an Effective Treatment for Oxygen Toxicity?
Excessive amounts of toxic oxygen may cause oxygen toxicity, also known as oxygen poisoning. It has the potential to make one cough and have breathing problems. In extreme circumstances, it is even capable of causing death. In HBOT, the patient breathes pure oxygen. The elevated air pressure inside the chamber facilitates enhanced oxygen absorption by the lungs, treating oxygen toxicity.
What is the Normal Air Pressure in HBOT?
Masks, close-fit hoods, or endotracheal tubes may be used for the inhalation of hyperbaric oxygen. The normal air pressure is often raised within the chambers to somewhere in the range of 250-280 kPa, comparable to a depth of 15-18 meters of water. The therapy length may range from 45 minutes to three hours, and patients might undergo as many as 40 sessions with increased normal air pressure.
What is Central Retinal Artery Occlusion?
Central retinal artery occlusion (CRAO) causes rapid and painless vision loss. This condition is caused by blockage of the central retinal artery and may result in irreversible loss of eyesight. The Undersea Hyperbaric Medicine Society (UHMS) recently approved the now world-famous hyperbaric oxygen therapy to treat CRAO. Patients may benefit from this technology to reverse the signs of this condition.
How Does It Feel After HBOT Session?
Your blood carries the additional oxygen throughout your body and provides it to the wounded tissues that need it to begin the healing process. Additionally, hyperbaric medicine has been shown to enhance the healing process and deliver greater success rates in compromised skin grafts and flaps. You may feel dizzy after the session is over. Some minor side effects are claustrophobia, tiredness, high blood pressure, and headaches. If not performing at home in a monoplace chamber, you should always have someone drive you home.
Is Scuba Diving the Same As Hyperbaric Chamber?
In general, hyperbaric chambers are an essential part of the sport of scuba diving. Since they both have to breathe gases while being subjected to pressures higher than atmospheric, patients treated in hyperbaric chambers are physiologically comparable to scuba divers. Patients undergoing HBO 2 treatment, on the other hand, stay dry during the procedure and breathe oxygen at a concentration of one hundred percent, in contrast to divers who are completely submerged in water.
How HBOT Treats Radiation Injury?
Hyperbaric oxygen treatment, often known as HBOT, is useful for these individuals. HBOT works by assisting the blood in carrying more oxygen to the damaged regions. Most cancer patients who endure unpleasant side effects from radiotherapy do so for a very short period and often feel better within six months following their last radiation treatment. On the other hand, receiving radiation while inhaling hyperbaric oxygen may lead to a decrease in mortality.
Does Daily HBO Treatment Enhance the Growth of Fibroblasts?
Many studies examine the effects of high-pressure oxygen on the development and autocrine synthesis of growth factors by fibroblasts cultured in an in vitro serum-free environment. Additionally, it seems that first exposure to HBO directly influences the generation of autocrine growth factors. Researchers hypothesized that fibroblasts could directly react to hyperopia, resulting in modifications to the cell signaling pathways involved in synthesizing growth factors and cellular proliferation.
How Could Hyperbaric Oxygen Therapy Help Reduce Tissue Damage?
Many medical professionals trust hyperbaric oxygen therapy for promoting wound healing by delivering plasma rich in oxygen to tissue deficient in oxygen. Injuries that produce wounds cause damage to the blood vessels of the body, which then release fluid and seep into the tissues and cause swelling. As a result of the swelling, the injured cells are deprived of oxygen, resulting in tissue death.
Can Hyperbaric Therapy Damage Ears?
The most typical adverse effect of hyperbaric oxygen treatment is a condition known as middle ear barotrauma. Between the ear's inner and external portions is a gap filled with air called the middle ear. Pressure imbalances between the ear canal and the atmosphere outside are the root cause of this condition. It can cause discomfort as well as hearing loss.
Our Final Thoughts
So there you have it: a complete guide on hyperbaric oxygen therapy. Hyperbaric oxygen has been utilized in medicine for centuries, and it is now generally accepted as the treatment of choice for various potentially fatal disorders, including carbon monoxide poisoning, decompression syndrome, and gas embolism. With A-listers, celebrities, divers, athletes, astronauts, and pilots adopting this therapy into their health-obsessed lifestyles, HBOT is definitely here to stay.
Hyperbaric Oxygen Chambers @ Airpuria
Whether you're looking for a hyperbaric oxygen chamber for commercial or residential space, finding a reputable supplier is the first step—that's where we come in. Shop from our diverse collection of Oxyhealth chambers: Vitaeris 320 ®, Solace 210 ®, Respiro 270 ®, Quamvis 320 ®, and Fortius 420 ®.
At Airpuria, our goal is to match the best health products on the market with the people who are the most health-conscious. We'd love to hear about your challenges, your goals, and what health benefits you're looking for, so feel free to give us a call at 773.337.8822!
Financing Options and Combining Information
If you're considering investing in a hyperbaric chamber like the Vitaeris 320 from OxyHealth, it's important to explore financing options to make your purchase more affordable. Airpuria offers financing for all customers with rates as low as 0% for up to 18 months, as well as business financing with flexible terms and competitive rates.
Remember to combine your Hyperbaric Oxygen Therapy with other healthy habits, such as a balanced diet, regular exercise, and proper skincare. Consult with a healthcare professional before starting any new treatment, and always do thorough research on potential risks and safety records of oxygen chamber providers.