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Pulmonary Artery Stenosis

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Pulmonary artery stenosis (PAS) is a narrowing of the pulmonary artery. The pulmonary artery is a blood vessel moving blood from the right side of the heart to the lungs. This narrowing can be due to many causes including infection during pregnancy, a heart defect present at birth, a problem with blood clotting in childhood or early adulthood, or a genetic change.1 The narrowing can occur at many different points along the pulmonary artery. The specific location of stenosis indicates how severe the disease is and what treatment options someone has. Most people with high-risk PAS are neonates, a newborn child, and young children. This is because the more severe the disease the more likely it is to present with symptoms and obviously signs. With these high-risk patients, it is necessary and acceptable to treat because letting this disease persist can lead to worsening blood pressure, poor heart function, and worsening vessel disease in other parts of the body.2

The blood flows in a very specific and methodical way through the body. Blood that has already delivered oxygen to body returns to the right upper chamber of the heart. It then gets pumped though the tricuspid valve and into the lower right chamber. The blood is then pumped through the pulmonary valve into the pulmonary artery and toward the lungs. The blood then receives oxygen in the lungs and is transported back to the left side of the heart before being pumped to the rest of the body.3 When the pulmonary artery, a vessel taking blood away from the heart, becomes narrow it still needs to pump the same amount of blood which causes the heart to have to pump harder. This increased force of pumping increases blood pressure on the right side of the heart and forces the heart muscle to work harder.1

Pulmonary artery stenosis should be differentiated from pulmonary valve stenosis. The pulmonary valve is the opening between the right heart and the pulmonary artery. Since it is right before the pulmonary artery narrowing of the valve and have similar effects to that of narrowing of the vessel itself. The most important reason to recognize the difference is because treatment varies for both. Also, the consequences of each disease long term can vary and present with other comorbid factors. Simply put, knowing specifically which of these a patient has is important to help treat them and prevent future problems.4

Symptoms of Pulmonary Artery Stenosis5

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Pulmonary artery stenosis symptoms depend on the specific location and cause of the narrowing, though many individuals do present with similar symptoms. Common symptoms include:5

·      Shortness of breath

·      Fatigue

·      Quick breathing (tachypnea)

·      Fast heart rate (tachycardia)


Other symptoms are caused by lack of oxygenated blood flow to the body. As discussed previously, blood travels through the pulmonary artery to the lungs to get oxygen. If blood has trouble getting to the lungs, the rest of the body will not receive enough oxygen. This causes individuals to present with:5

·      Dizziness

·      Episodes of passing out (brain not receiving enough oxygen and blood)

·      Inability to keep up with physical activity or not wanting to be physically active

·      Blue discoloration of the lips, fingers, or toes (cyanosis)


When blood cannot move from the right side of the heart to the lungs because of the narrowing, it can cause the blood to back up. This can lead to swelling in parts of the body like the hands and feet and can present similarly to right sided heart failure.5

Causes of Pulmonary Artery Stenosis

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Though 40% of individuals don’t have any other underlying heart problems, PAS can still occur in 2-3% of individuals with underlying heart disease they were born with:

·      Tetralogy of Fallot: a condition characterized by an obstruction in blood leaving the right side of the heart, enlargement in the lower right chamber of the heart, an opening between the right and left lower chambers of the heart, and mispositioned aorta.

·      Pulmonary Atresia: a condition where the pulmonary valve does not form, and blood is unable to travel from the right side of the heart to the lungs.

·      Truncus Arteriosus: One large vessel leaves the heart instead of two separate vessels, one from the right, one from the left.

·      Aortic Valve Stenosis: The valve allowing blood to leave the left side of the heart is narrowed.

·      Atrial Septal Defect: A hole between the right and left upper chambers in the heart is present allowing blood from the left to enter the right.

·      Ventricular Septal Defect: a hole between the right and left lower chambers of the heart allowing blood from the left, higher pressure side, to enter the right.

·      Transposition of the great vessels: A condition where the aorta and pulmonary artery swap where they receive blood from. Blood from the left side of the heart enters the pulmonary artery and goes to the lungs instead of the body and the blood from the right side of the heart (without oxygen) enters the aorta and goes to the body instead of the lungs.

·      Patent Ductus Arteriosus: the ductus arteriosus connects the pulmonary artery and aorta before birth and just after birth. In this condition the ductus does not shrink and close but remains open and causes extra blood to flow into the lungs and left side of the heart.5


There are also genetic and infectious causes of pulmonary artery stenosis. The most common of these are:

·      Williams Syndrome and Alagille Syndrome: mutation in the elastin gene resulting in an abnormality in the structure of the pulmonary arteries along with abnormalities in other organs.4

·      Noonan’s Syndrome: genetic mutation in a pathway regulating what other genes are expressed.4

·      Ehlers-Danlos Syndrome: mutation in collagen and other portions of connective tissue that make up parts of the body like blood vessels.4

·      Takayasu’s Arteritis: inflammatory disease results in damage, hardening, and occlusion to blood vessels leading to narrowing.[6]

·      Rubella: infection during pregnancy can lead to heart abnormalities in neonates5

Diagnosis of Pulmonary Artery Stenosis

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There is no immediate way to know if a child has PAS, but if an abnormal heart sounds, also known as a murmur, is heard on physical exam, further testing is ordered to evaluate the cause.

·      Electrocardiogram (EKG): electrical recording of the heart that can show irregular heartbeats and changes in the heart muscle.

·      Chest X-ray: shows shape and size of the heart and surrounding vessels.

·      Echocardiogram: using sound waves to get a real time picture of the heart including the muscles, valves, and vessels.

·      Computed Tomography (CT) Scan: using a series of x-rays to create a detailed view of the heart and vessels. Using contrast dye can allow for visualization of blood flow and any narrowing that may be present.5,6

·      Cardiac Catheterization: a procedure usually done by a heart specialist. It involves inserting a catheter (small tube) through a vessel and navigating it to the heart for better imaging and testing. Specialists can also perform treatments while the catheter is inserted.

·      Pulmonary Angiogram: dye enhanced x-ray of the pulmonary arteries and veins.5

Treatment of Pulmonary Artery Stenosis

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There are currently 3 mainstays of treatment for pulmonary artery stenosis. Those are balloon angioplasty, cutting balloon angioplasty, and stenting. Prior to the development of balloon angioplasty, surgical angioplasty was the main treatment method.4 Because of lack of efficacy, limited accessibility to certain areas of stenosis, increased risk for scarring, and a high rate of repeat stenosis, surgical angioplasty is only used if other methods fail or if surgeons are able to directly visualize the narrowing while repairing another heart defect. Some studies have shown only a 62% surgical success rate for surgical angioplasty. This would still call for other forms of treatment in about 4/10 patients while exposing them to increased risks of open surgery.2

Balloon angioplasty is a less invasive method to help expand the diameter of a vessel to improve narrowing. In this treatment a catheter with a balloon on the end is inserted into a larger, peripheral vessel and moved to the area of narrowing. The goal of this treatment method is to tear two of the three layers of the artery which increases both the vessel’s diameter and the flow of blood throw the vessel. Initially a soft balloon was used but only about 60% of patients had at least a 50% increase in blood flow. This is similar is efficacy to surgical angioplasty with a large reduction in associated risks. Later on a stiffer balloon was used and efficacy improved to 72% with no increase in associated risks.4

After the procedure is performed, there are several key factors that help determine if the procedure was successful/will remain successful. These are: 1) evidence on imaging or tissue sampling of tearing of the vessel wall, 2) larger ratio of balloon diameter to vessel diameter, 3) cause of the pulmonary artery stenosis (surgically caused stenosis is more likely to be successful), and 4) location of the narrowing as vessels further from the heart are more elastic and more difficult to treat with just balloon angioplasty.4

One of the major concerns with balloon angioplasty is the rate of restenosis. Even when there is evidence of tearing of the vessel wall, the rate of restenosis (or repeat narrowing) is between 15-44%. Studies have also shown the rate of restenosis increases as time from the procedure increases. ­Rates of complications overall are estimated around 22%, with 10% being higher risk complications. Other complications from this procedure are likely from too much damage to vessels and include full vessel tears, deep vein thrombosis (clot in the vessel), complete rupture of the pulmonary artery, and pulmonary edema (fluid in the lungs causing worsening breathing).4

The major reasons for simple balloon angioplasty failure are inability to tear the vessel wall, restenosis, areas of narrowing due to compression by another internal body part rather than issues with the vessel itself. To help counteract the first, cutting balloon angioplasty was invented. This method utilizes balloons with a blade that can cut through vessel walls rather than simply causing vessel wall tearing via crushing/expansion of the balloon. When the balloon is not inflated the blades are protected inside the balloon folds, ensuring they will not accidentally damage other vessels.4 After the use of the cutting balloon, a larger, higher-pressure balloon can be used to improve efficacy. Multicenter studies show the same safety profiles for simple versus cutting balloon angioplasty with rates of adverse effects of 2% and 3% respectively. When a high-pressure balloon was used after cutting balloon angioplasty the rate of effectiveness increased from 52% to 85%.2 It should also be noted cutting balloon angioplasty provides more areas of vessel damage especially in vessels further from the heart. Overall it is noted that cutting balloon angioplasty has similar complications and restenosis rates as simple, but offers a more effective treatment as well as being a better option for smaller areas of stenosis.4

To solve the latter two problems of restenosis and external compression of a vessel, metal stents were introduced. These stents would be deployed via a catheter. They could be expanded at the site specifically. The stents form a rigid structure that would hold in place and remain inside the vessel. Newer studies have shown successful dilation in 90% of patients on average with some newer studies indicating a 100% success rate. The benefits of these stents is not only their long term efficacy but the prevention of long term heart disease. Stents helped improve right sided heart pressures, blood flow to the lungs, and pressure difference between the right and left sides of the heart. Stents have been noted to be sustainable with replacement for up to 15 years, much longer than if a patient received any sort of balloon angioplasty. Stents have the lowest rate of restenosis at 2-3%.4

Stents also allowed for normal growth of the vessels during childhood and adolescent years, and did not damage the heart or vasculature. Though, because young children grow very rapidly, 30-50% of children who received stents did require replacement with a larger stent in the first 2 years of placement. Complication rates are around 12% and include misplacement due to blood flow over time, vessel damage from the metal stent moving, or formation of a clot on the stent leading to blocked blood flow. Because of these concerns and necessary removal of the stent if these were to occur, a patient would need to have the stent monitored frequently after placement.4

Another concern with stents is fracturing, or breaking, of the stent due to repetitive pressure. One study early in stent usage for pulmonary artery stenosis showed fracturing in about 21% of patients. 80% of these patients then had significant vessel obstruction because of the break. With continual improvements to stents, the newer data reveals a 13% adverse event rate with only 1.2% being major adverse events, such as a fracture leading to major vessel obstruction. Success rate for dilation in this study was 99%, much higher than the 72% for cutting balloon angioplasty. Of note, studies have shown the adverse event rate decreases as the patient’s age increases, likely due to less significant growth in the vessel. Some studies do indicate the need for replacement of a stent as high as 43%, but this rate does increase over time. Currently the recommendations are to treat younger patients with balloon angioplasty until they are older and the risk for metal stents is significantly reduced.2 Future advancement for bioresorbable stents (stents that would be absorbed by the body) is in the works as this would reduce the need to continually replace stents in growing humans.2,4


References

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1. University of California San Francisco. (n.d.). Pulmonary artery stenosis. ucsfbenioffchildrens.org. https://www.ucsfbenioffchildrens.org/conditions/pulmonary-artery-stenosis#:~:text=Pulmonary%20artery%20stenosis%20is%20a,right%20side%20of%20the%20heart

2. Patel AB, Ratnayaka K, Bergersen L. (2019). A review: Percutaneous pulmonary artery stenosis therapy: state-of- the-art and look to the future. Cardiology in the Young 29: 93–99. doi: 10.1017/ S1047951118001087

3. University of Pittsburgh Medicla Center. (n.d.). Pulmonary artery stenosis: Interventional Cardiology Program: UPMC Children’s. Children’s Hospital of Pittsburgh. https://www.chp.edu/our-services/heart/cardiology/interventional-cardiology-program/conditions/pulmonary-artery-stenosis

4. Kim, C. W., Aronow, W. S., Dutta, T., Spevack, D. M., & Frishman, W. H. (2020). Treatment of peripheral pulmonary artery stenosis. Cardiology in Review, 29(3), 115–119. https://doi.org/10.1097/crd.0000000000000300

5. Pulmonary artery stenosis: Causes, symptoms and treatment. Cleveland Clinic. (n.d.). https://my.clevelandclinic.org/health/diseases/17399-pulmonary-artery-stenosis

6. Leitman EM, McDermott S. Pulmonary arteries: imaging of pulmonary embolism and beyond. Cardiovasc Diagn Ther. 2019 Aug;9(Suppl 1):S37-S58. doi: 10.21037/cdt.2018.08.05. PMID: 31559153; PMCID: PMC6732114.