Symptoms can include fatigue and pain in muscles and joints.
In the more severe type, symptoms may be similar to those of stroke or can include numbness, tingling, arm or leg weakness, unsteadiness, vertigo (spinning), difficulty breathing, and chest pain.
People are treated with oxygen and recompression Recompression Therapy Recompression therapy involves giving 100% oxygen for several hours in a sealed chamber at high pressures (at least 1.9 atmospheres). (See also Overview of Diving Injuries.) Recompression therapy... read more (high-pressure, or hyperbaric, oxygen) therapy.
Limiting the depth and duration of dives and the speed of ascent can help with prevention.
(See also Overview of Diving Injuries Overview of Diving Injuries People who engage in deep-sea or scuba diving are at risk of a number of injuries, most of which are caused by changes in pressure. These disorders also can affect people who work in underwater... read more .)
Air is composed mainly of nitrogen and oxygen. Because air under high pressure is compressed, each breath taken at depth contains many more molecules than a breath taken at the surface. Because oxygen is used continuously by the body, the extra oxygen molecules breathed under high pressure usually do not accumulate. However, the extra nitrogen molecules do accumulate in the blood and tissues.
As outside pressure decreases during ascent from a dive or when leaving a compressed air environment, the accumulated nitrogen that cannot be exhaled immediately forms bubbles in the blood and tissues. These bubbles may expand and injure tissue, or they may block blood vessels in many organs—either directly or by triggering small blood clots. This blood vessel blockage causes pain and various other symptoms, for example, sometimes similar to those of a stroke (such as sudden weakness on one side of the body, difficulty speaking, or dizziness), or even flu-like symptoms. Nitrogen bubbles also cause inflammation, causing swelling and pain in muscles, joints, and tendons.
The risk of developing decompression sickness increases with many of the following factors:
Certain heart defects, such as patent foramen ovale or atrial septal defect Atrial and Ventricular Septal Defects Atrial and ventricular septal defects are holes in the walls (septa) that separate the heart into the left and right sides. Holes can be present in the walls of the heart between the upper heart... read more
Flying after diving
Increasing pressure (that is, the depth of the dive)
Length of time spent in a pressurized environment
Failure to follow appropriate decompression procedures
Because excess nitrogen remains dissolved in the body tissues for at least 12 hours after each dive, repeated dives within 1 day are more likely to cause decompression sickness than a single dive. Flying within 12 to 24 hours after diving (such as at the end of a vacation) exposes people to an even lower atmospheric pressure, making decompression sickness slightly more likely.
Nitrogen bubbles may form in small blood vessels or in the tissues themselves. Tissues with a high fat content, such as those in the brain and spinal cord, are particularly likely to be affected, because nitrogen dissolves very readily in fats.
Type I decompression sickness tends to be mild and affects primarily the joints, skin, and lymphatic vessels.
Type II decompression sickness, which may be life threatening, often affects vital organ systems, including the brain and spinal cord, the respiratory system, and the circulatory system.
Symptoms of Decompression Sickness
Symptoms of decompression sickness usually develop more slowly than do those of air embolism Arterial Gas Embolism Arterial gas embolism is blockage of blood supply to organs caused by bubbles in an artery. It is a leading cause of death among underwater divers, such as scuba divers, who breathe compressed... read more and pulmonary barotrauma Pulmonary barotrauma Barotrauma is tissue injury caused by a change in pressure, which compresses or expands gas contained in various body structures. The lungs, gastrointestinal tract, part of the face covered... read more . Only half of the people with decompression sickness have symptoms within 1 hour of surfacing, but 90% have symptoms by 6 hours. Symptoms commonly begin gradually and take some time to reach their maximum effect. The first symptoms may be
Loss of appetite
Vague feeling of illness
Type I decompression sickness (less severe)
The less severe type (or musculoskeletal form) of decompression sickness, often called the bends, typically causes pain. The pain usually occurs in the joints of the arms or legs, back, or muscles. Sometimes the location is hard to pinpoint. The pain may be mild or intermittent at first but may steadily grow stronger and become severe. The pain may be sharp or may be described as “deep” or “like something boring into bone.” It is worse when moving.
Less common symptoms include itching, skin mottling, rash, swelling of the arm, chest, or abdomen, and extreme fatigue. These symptoms do not threaten life but may precede more dangerous problems.
Type II decompression sickness (more severe)
The more severe type of decompression sickness most commonly results in neurologic symptoms, which range from mild numbness to paralysis and death. The spinal cord is especially vulnerable.
Symptoms of spinal cord involvement can include numbness, tingling, weakness, or a combination in the arms, legs, or both. Mild weakness or tingling may progress over hours to irreversible paralysis. Inability to urinate or inability to control urination or defecation may also occur. Pain in the abdomen and back also is common.
Symptoms of brain involvement, most of which are similar to those of air embolism, include
Loss of consciousness is rare.
Symptoms of inner ear involvement, such as severe vertigo, ringing in the ears, and hearing loss, occur when the nerves of the inner ear are affected.
Symptoms of lung involvement caused by gas bubbles that travel through the veins to the lungs, produce cough, chest pain, and progressively worsening difficulty breathing (the chokes). Severe cases, which are rare, may result in shock and death.
Late effects of decompression sickness
Dysbaric osteonecrosis (sometimes called avascular bone necrosis) can be a late effect of decompression sickness, or can occur in the absence of decompression sickness. It involves the destruction of bone tissue, especially in the shoulder and hip. Dysbaric osteonecrosis Osteonecrosis can produce persistent pain and disability due to osteoarthritis resulting from the injury. These injuries rarely occur among recreational divers but are more common among people who work in a compressed-air environment and divers who work in deep underwater habitats. There is often no specific initiating event the person can identify as the source of symptoms once they do appear.
These workers are exposed to high pressure for prolonged periods and may have an undetected case of the bends. Technical divers, who dive to greater depths than recreational divers, may be at higher risk than recreational divers. Dysbaric osteonecrosis usually produces no symptoms but if it occurs close to a joint it may gradually progress over months or years to severe, disabling arthritis. By the time severe joint damage has occurred, the only treatment may be joint replacement.
Permanent neurologic problems, such as partial paralysis, often result from delayed or inadequate treatment of spinal cord symptoms. However, sometimes the damage is too severe to correct, even with appropriate and timely treatment. Repeated treatments with oxygen in a high-pressure chamber seem to help some people recover from spinal cord damage.
Diagnosis of Decompression Sickness
A doctor's evaluation
Doctors recognize decompression sickness by the nature of the symptoms and their onset in relation to diving. Tests such as computed tomography (CT) or magnetic resonance imaging (MRI) sometimes show brain or spinal cord abnormalities but are not reliable. However, recompression therapy is begun before the results of a CT or MRI scan are available, except in cases in which the diagnosis is uncertain or the diver’s condition is stable. MRI is usually diagnostic of dysbaric osteonecrosis.
Treatment of Decompression Sickness
The majority of people recover completely.
Divers having only itching, skin mottling, and fatigue usually do not need to undergo recompression, but they should be kept under observation, because more serious problems may develop. Breathing 100% oxygen from a close-fitting face mask is recommended and may provide relief.
Any other symptoms of decompression sickness indicate the need for treatment in a high-pressure (recompression, or hyperbaric oxygen) chamber, because recompression therapy Recompression Therapy Recompression therapy involves giving 100% oxygen for several hours in a sealed chamber at high pressures (at least 1.9 atmospheres). (See also Overview of Diving Injuries.) Recompression therapy... read more restores normal blood flow and oxygen to affected tissues. After recompression, pressure is reduced gradually, with designated pauses, allowing time for excess gases to leave the body harmlessly. Because symptoms may reappear or worsen over the first 24 hours, even people with only mild or transient pain or neurologic symptoms are treated.
Recompression therapy is more beneficial when started quickly. When flying in a plane, the air pressure in the passenger compartment is lower than on the ground, and this pressure difference can sometimes worsen decompression sickness. However, in people with severe symptoms, the benefit of being treated sooner in a hyperbaric chamber is much greater than the risk of not being treated. Experts usually recommend flying in a commercial aircraft, which can be pressurized, or flying at low altitude if the aircraft is unpressurized.
Recompression therapy may be beneficial for up to 48 hours or longer after diving and should be given even if reaching the nearest chamber requires significant travel. While awaiting transport and during transport, oxygen is administered with a close-fitting face mask, and fluids are given by mouth or intravenously. Long delays in treatment increase the risk of permanent injury.
Prevention of Decompression Sickness
Divers try to prevent decompression sickness by avoiding gas bubble formation. They do this by limiting the depth and duration of dives to a range that does not need decompression stops during ascent (called no-stop limits by divers) or by ascending with decompression stops as specified in authoritative guidelines, such as the decompression table in Air Decompression, a chapter in the U. S. Navy Diving Manual.
The table provides a schedule for ascent that usually allows excess nitrogen to escape without causing harm. Many divers wear a portable dive computer that continually tracks the diver’s depth and time at depth. The computer calculates the decompression schedule for a safe return to the surface and indicates when decompression stops are needed.
In addition to following a table or computer guidelines for ascent, many divers make a safety stop of a few minutes at about 15 feet (4.5 meters) below the surface.
Following these procedures, however, does not eliminate the risk of decompression sickness. A small number of cases of decompression sickness develop after no-stop dives. The persistence of decompression sickness may be because the published tables and computer programs do not completely account for the variation in risk factors among different divers or because some people fail to obey the recommendations of the tables or computer.
Did You Know...
Other precautions also are necessary:
After several days of diving, a period of 12 to 24 hours (for example, 15 hours) at the surface is commonly recommended before flying or going to a higher altitude.
People who have completely recovered from mild decompression sickness should refrain from diving for at least 2 weeks. After serious decompression sickness, it is best to wait longer (at least a month) and be evaluated by a physician before diving again.
People who have developed decompression sickness despite following dive table or computer recommendations should return to diving only after a thorough medical evaluation for underlying risk factors, such as a heart defect.
The following English-language resources may be useful. Please note that THE MANUAL is not responsible for the content of these resources.