Diving With A PFO
Text by Douglas Ebersole, MD
If a diver suspects recurrent DCS might be due to a PFO, they will usually undergo a bubble study. A surgical solution is a PFO closure, as Dr. Doug Ebersole is performing here. It is an outpatient procedure that normally takes less than an hour.
To clear up any confusion divers may have about patent foramen ovale (PFO), I will share how I explain the condition to patients. The heart has four chambers: two on the top (right and left atria) and two on the bottom (right and left ventricles). As our heart is forming before we are born, the wall between the two bottom chambers is solid, but the wall between the two top chambers is not.
One wall grows up from the bottom, while the other grows down from the top. Where they overlap is a flap — not a hole, as some people have described. The reason for this structure is that once we are born, the purpose of the right side of the heart is to pump blood to the lungs to get oxygen, and then the blood returns to the left side of the heart, where it is pumped to the body.
As a fetus, however, we don’t use our lungs; they are collapsed and full of fluid. Oxygenated blood comes from the placenta, empties into the inferior vena cava, and then goes to the right atrium. In the fetus, the right side of the heart tries to pump blood to the collapsed, fluid-filled lungs, which is difficult and results in higher pressures in the right atrium than in the left atrium. This differential pushes open the flap between the two top chambers and allows the oxygenated blood from the placenta to bypass the right side of the heart and enter the left atrium. From there, the oxygenated blood goes to the left ventricle and is pumped to the body.
When we are born, the lungs open, which makes pumping blood to them much easier. This results in lower pressure in the right atrium compared with the left atrium and slams the flap shut. In about 75% of people, this flap between the two atria will seal within the first year or so of life and make a solid wall. In about 25% of people, however, it never seals and is called a patent foramen ovale. The presence of a PFO is a normal variant in humans and not a disease.
In the 25% of divers who have this flap between the atria, bubbles that the lungs normally filter can cross from the right atrium to the left atrium under certain loading conditions, resulting in decompression sickness (DCS).
When doing a bubble study, we inject agitated saline into a vein, which results in tiny bubbles that reflect the ultrasound. This mass of bubbles enters the right atrium and should go to the right ventricle and then to the lungs. In people with a PFO, however, the bubbles will cross from the right atrium to the left atrium. We determine the PFO’s size by observing how many bubbles go across and if they cross at rest or require a manoeuvre, such as a Valsalva, to cross.
As best we can tell, a PFO increases the risk of DCS by about fivefold. While that may sound bad, remember that it is a relative risk. The absolute risk of DCS in a diver with a PFO is quite small. For recreational diving, the risk of DCS is about two episodes per 10,000 dives. Therefore, a diver with a PFO could expect about 10 DCS episodes per 10,000 dives or one episode per 1,000 dives, which is a small absolute risk.
If a diver suspects recurrent DCS might be due to a PFO, they will usually undergo a bubble study. A surgical solution is a PFO closure, as Dr. Doug Ebersole is performing here. It is an outpatient procedure that normally takes less than an hour.
To clear up any confusion divers may have about patent foramen ovale (PFO), I will share how I explain the condition to patients. The heart has four chambers: two on the top (right and left atria) and two on the bottom (right and left ventricles). As our heart is forming before we are born, the wall between the two bottom chambers is solid, but the wall between the two top chambers is not.
One wall grows up from the bottom, while the other grows down from the top. Where they overlap is a flap — not a hole, as some people have described. The reason for this structure is that once we are born, the purpose of the right side of the heart is to pump blood to the lungs to get oxygen, and then the blood returns to the left side of the heart, where it is pumped to the body.
As a fetus, however, we don’t use our lungs; they are collapsed and full of fluid. Oxygenated blood comes from the placenta, empties into the inferior vena cava, and then goes to the right atrium. In the fetus, the right side of the heart tries to pump blood to the collapsed, fluid-filled lungs, which is difficult and results in higher pressures in the right atrium than in the left atrium. This differential pushes open the flap between the two top chambers and allows the oxygenated blood from the placenta to bypass the right side of the heart and enter the left atrium. From there, the oxygenated blood goes to the left ventricle and is pumped to the body.
When we are born, the lungs open, which makes pumping blood to them much easier. This results in lower pressure in the right atrium compared with the left atrium and slams the flap shut. In about 75% of people, this flap between the two atria will seal within the first year or so of life and make a solid wall. In about 25% of people, however, it never seals and is called a patent foramen ovale. The presence of a PFO is a normal variant in humans and not a disease.
In the 25% of divers who have this flap between the atria, bubbles that the lungs normally filter can cross from the right atrium to the left atrium under certain loading conditions, resulting in decompression sickness (DCS).
When doing a bubble study, we inject agitated saline into a vein, which results in tiny bubbles that reflect the ultrasound. This mass of bubbles enters the right atrium and should go to the right ventricle and then to the lungs. In people with a PFO, however, the bubbles will cross from the right atrium to the left atrium. We determine the PFO’s size by observing how many bubbles go across and if they cross at rest or require a manoeuvre, such as a Valsalva, to cross.
As best we can tell, a PFO increases the risk of DCS by about fivefold. While that may sound bad, remember that it is a relative risk. The absolute risk of DCS in a diver with a PFO is quite small. For recreational diving, the risk of DCS is about two episodes per 10,000 dives. Therefore, a diver with a PFO could expect about 10 DCS episodes per 10,000 dives or one episode per 1,000 dives, which is a small absolute risk.
When a diver with a PFO gets DCS, we have to determine if the PFO is a contributing factor. Research indicates that four types of DCS are related to a PFO: cerebral, spinal, inner ear, and cutaneous (skin).
Whether or not a diver with DCS has a PFO, the options are always to either stop diving or dive more conservatively. The issue is the inert gas load, not the PFO itself, so anything that limits inert gas loading will decrease the likelihood of recurrent DCS. We recommend diving shallower, staying within no-decompression limits, making fewer dives per day, using nitrox with your computer set to air, performing long safety stops, and not engaging in any strenuous activity for several hours after diving.
If a diver has recurrent DCS of any of the four types related to a PFO despite using conservative dive practices, we may offer a PFO closure, which is an outpatient procedure that takes less than an hour. After the procedure, the diver takes aspirin and clopidogrel (Plavix) for three to six months and then has a repeat echocardiogram with a bubble study. If that shows no right-to-left shunting, the diver can return to diving without restrictions.
Douglas Ebersole, MD, is an interventional cardiologist and director of Lakeland Regional Health’s Structural Heart Program in Lakeland, Florida. He serves as a cardiology consultant for DAN.
Whether or not a diver with DCS has a PFO, the options are always to either stop diving or dive more conservatively. The issue is the inert gas load, not the PFO itself, so anything that limits inert gas loading will decrease the likelihood of recurrent DCS. We recommend diving shallower, staying within no-decompression limits, making fewer dives per day, using nitrox with your computer set to air, performing long safety stops, and not engaging in any strenuous activity for several hours after diving.
If a diver has recurrent DCS of any of the four types related to a PFO despite using conservative dive practices, we may offer a PFO closure, which is an outpatient procedure that takes less than an hour. After the procedure, the diver takes aspirin and clopidogrel (Plavix) for three to six months and then has a repeat echocardiogram with a bubble study. If that shows no right-to-left shunting, the diver can return to diving without restrictions.
Douglas Ebersole, MD, is an interventional cardiologist and director of Lakeland Regional Health’s Structural Heart Program in Lakeland, Florida. He serves as a cardiology consultant for DAN.
Posted in Alert Diver Southern Africa, Dive Fitness, Dive Safety FAQ
Posted in PFO, Patent foramen ovale, Heart
Posted in PFO, Patent foramen ovale, Heart
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