(See also Overview of Diving Injuries Overview of Diving Injuries More than 1000 diving-related injuries occur annually in the US; > 10% are fatal. Similar injuries can befall workers in tunnels or caissons (watertight retaining structures used for construction)... read more .)
Henry’s law states that the quantity of gas dissolved in a liquid is directly proportional to the partial pressure of the gas in equilibrium with the liquid. Thus, the amount of inert gases (eg, nitrogen, helium) dissolved in the blood and tissues increases at higher pressure.
During ascent, when the surrounding pressure decreases, bubbles (mainly nitrogen) may form. The liberated gas bubbles can arise in any tissue and cause local symptoms, or they can travel via the blood to distant organs (arterial gas embolism Arterial Gas Embolism Arterial gas embolism is a potentially catastrophic event that occurs when gas bubbles enter or form in the arterial vasculature and occlude blood flow, causing organ ischemia. Arterial gas... read more ). Bubbles cause symptoms by
Blocking blood vessels
Rupturing or compressing tissue
Inducing endothelial damage and extravasation of plasma
Activating clotting and inflammatory cascades
Because nitrogen dissolves readily in fat, tissues with a high lipid content (eg, in the central nervous system) are particularly susceptible.
Risk factors for decompression sickness
Decompression sickness occurs in about 2 to 4/10,000 dives among recreational divers. The incidence is higher among commercial divers who are exposed to deeper depths and longer dive times. Risk factors include all of the following:
Exercise after diving
Flying after diving
Prolonged or deep dives
Right-to-left cardiac shunts
Because excess nitrogen remains dissolved in body tissues for at least 12 hours after each dive, repeated dives within 1 day are more likely to cause decompression sickness. Decompression sickness can also develop if pressure decreases below atmospheric pressure (eg, by exposure to altitude).
Classification of decompression sickness
Generally, there are 2 types of decompression sickness:
Type I: Involves joints, skin, and lymphatics and is milder and not typically life threatening
Type 11: Includes neurologic or cardiorespiratory involvement, which is serious, is sometimes life threatening, and affects various organ systems
The spinal cord is especially vulnerable; other vulnerable areas include the brain, respiratory system (eg, pulmonary emboli), and circulatory system (eg, heart failure, cardiogenic shock).
The bends refers to local joint or muscle pain due to decompression sickness but is often used as a synonym for any component of the disorder.
Symptoms and Signs
Severe symptoms may manifest within minutes of surfacing, but in most patients, symptoms begin gradually, sometimes with a prodrome of malaise, fatigue, anorexia, and headache. Symptoms occur within 1 hour of surfacing in about 50% of patients and by 6 hours in 90%. Rarely, symptoms can manifest 24 to 48 hours after surfacing, particularly by exposure to altitude after diving (such as air travel).
Type I decompression sickness typically causes progressively worsening pain in the joints (typically elbows and shoulders) and muscles; the pain typically does not intensify during movement and is described as “deep” and “boring.” Other manifestations include lymphedema, skin mottling, itching, and rash.
Type II decompression sickness consists of neurologic and sometimes respiratory symptoms. It typically manifests with paresis, numbness and tingling, difficulty urinating, and loss of bowel or bladder control. Headache and fatigue may be present but are nonspecific. Dizziness, tinnitus, and hearing loss may result if the inner ear is affected. Severe symptoms include seizures, slurred speech, vision loss, confusion, and coma. Death can occur.
The chokes (respiratory decompression sickness) is a rare but grave manifestation; symptoms include shortness of breath, chest pain, cough, resulting from pulmonary edema. Massive bubble embolization of the pulmonary vascular tree can result in rapid circulatory collapse and death.
Dysbaric osteonecrosis is a late manifestation of decompression sickness and often occurs without any previous symptoms. It is an insidious form of osteonecrosis Osteonecrosis (ON) Osteonecrosis is a focal infarct of bone that may be caused by specific etiologic factors or may be idiopathic. It can cause pain, limitation of motion, joint collapse, and secondary osteoarthritis... read more caused by prolonged or closely repeated exposures to increased pressure (typically in people working in compressed air and in deep commercial rather than recreational divers). Deterioration of shoulder and hip articular surfaces can cause chronic pain and disability due to secondary osteoarthritis.
Diagnosis is clinical. CT and MRI may be helpful to rule out other disorders that cause similar symptoms (eg, herniated intervertebral disk, ischemic stroke, central nervous system hemorrhage). Although these studies sometimes show brain or spinal cord abnormalities due to decompression sickness, their sensitivity for decompression sickness is low, and treatment should usually begin based on clinical suspicion.
Arterial gas embolism Arterial Gas Embolism Arterial gas embolism is a potentially catastrophic event that occurs when gas bubbles enter or form in the arterial vasculature and occlude blood flow, causing organ ischemia. Arterial gas... read more can have similar manifestations (for a comparison of features, see table Comparison of Gas Embolism and Decompression Sickness Comparison of Gas Embolism and Decompression Sickness Decompression sickness occurs when rapid pressure reduction (eg, during ascent from a dive, exit from a caisson or hyperbaric chamber, or ascent to altitude) causes gas previously dissolved... read more ). However, immediate treatment for both is similar.
For dysbaric osteonecrosis, skeletal x-rays may show joint degeneration, which cannot be distinguished from that caused by other joint disorders; MRI is usually diagnostic.
Pearls & Pitfalls
Fluid therapy to maintain intravascular volume
The majority of patients recover completely.
Initially, high-flow 100% oxygen enhances nitrogen washout by widening the nitrogen pressure gradient between the lungs and the circulation, thus accelerating reabsorption of nitrogen-containing embolic bubbles.
To restore lost intravascular volume, oral resuscitation fluid (or plain water) is indicated for alert patients with mild manifestations. Isotonic, glucose-free IV fluids are indicated for those with serious manifestations.
Recompression therapy Recompression Therapy Recompression therapy is administration of 100% oxygen for several hours in a sealed chamber pressurized to > 1 atmosphere, gradually lowered to atmospheric pressure. In divers, this therapy... read more is indicated for all patients except perhaps those whose symptoms are limited to itching, skin mottling, and fatigue, which may be treatable with oxygen alone; patients should be observed for deterioration (1 Treatment reference Decompression sickness occurs when rapid pressure reduction (eg, during ascent from a dive, exit from a caisson or hyperbaric chamber, or ascent to altitude) causes gas previously dissolved... read more ). Patients with more severe symptoms are transported to a suitable recompression facility. Because time to treatment and severity of the injury are important determinants of outcome, transport should not be delayed for performance of nonessential procedures.
If air evacuation is required, an aircraft capable of 1 atmosphere internal pressure is preferred. In unpressurized aircraft, low altitude (< 609 m [< 2000 ft]) should ideally be maintained and oxygen given continuously. Commercial aircraft, although pressurized, typically have a cabin pressure up to an equivalent of 2438 m (8000 ft) at normal cruise altitude, which may exacerbate symptoms. Flying in commercial aircraft shortly after a dive can precipitate symptoms.
Significant bubble formation can usually be avoided by limiting the depth and duration of dives to a range that does not need decompression stops during ascent (called no-stop limits) or by ascending with decompression stops as specified in published guidelines (eg, the decompression table in the chapter Diagnosis and Treatment of Decompression Sickness in the US Navy Diving Manual). Many divers wear a portable dive computer that continually tracks depth and time at depth and calculates a decompression schedule.
In addition to following published and computer-generated guidelines, many divers make a safety stop for a few minutes at about 4.6 m (15 ft) below the surface. However, cases can occur after appropriately identified no-stop dives, and the incidence of decompression sickness has not decreased despite widespread use of dive computers (although fewer serious cases occur).
Dives < 24 hours apart (repetitive dives) require special techniques to determine proper decompression procedures.
Symptoms of decompression sickness develop within 1 hour of surfacing in 50% of affected patients and within 6 hours in 90%.
If the disorder is suspected, start high-flow 100% oxygen and arrange the most expeditious transport to a recompression facility possible, using ground transportation or an aircraft capable of 1 atmosphere of internal pressure.
Counsel divers to follow established recommendations (eg, diving depth and duration, use of decompression stops during ascent) that decrease the risk of decompression sickness.
The following English-language resources may be useful. Please note that THE MANUAL is not responsible for the content of these resources.
Divers Alert Network: 24-hour emergency hotline, 919-684-9111
Duke Dive Medicine: Physician-to-physician consultation, 919-684-8111
Undersea and Hyperbaric Medical Society: Scientific and medical information pertaining to undersea and hyperbaric medicine through its bimonthly, peer-reviewed journal, Undersea and Hyperbaric Medicine, and other resources
US Navy Diving Manual: Detailed reference guide published by the US Navy detailing diver training and diving operations