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Pericardial effusions occur when excess fluid collects in the pericardial space (a normal pericardial sac contains approximately 30-50 mL of fluid).
There is no single demographic affected, as there are many underlying causes of pericardial effusion.
Clinical presentation of pericardial effusions does not relate so much to the size of the effusion but rather the speed at which the fluid has accumulated, as slow gradual accumulation allows the pericardium to stretch and accommodate much larger volumes of fluid 4.
Regardless of volume, symptoms relate to impaired cardiac function due to intrapericardial pressure approximating intracardiac pressure leading to an impaired filling of low-pressure chambers, particularly the right atrium.
Dyspnea and reduced exercise tolerance will be early signs, progressing to severe impaired cardiac output and death in severe cases (e.g. cardiac tamponade).
- idiopathic (presumed viral, post-viral or immune-related)
- post-surgical or traumatic
- pulmonary arterial hypertension 7
- end-stage renal disease 14
- dialysis 15
Small pericardial effusions are often occult on plain film. Greater than 200 mL of pericardial fluid is usually required to become radiographically visible. Radiographic signs include:
- there can be globular enlargement of the cardiac shadow giving a water bottle configuration
- lateral CXR may show a vertical opaque line (pericardial fluid) separating a vertical lucent line directly behind the sternum (pericardial fat) anteriorly from a similar lucent vertical lucent line (epicardial fat) posteriorly; this is known as the Oreo cookie sign 5
- widening of the subcarinal angle without other evidence of left atrial enlargement may be an indirect clue 2
- a differential density sign at cardiac borders has been suggested 9, but its specificity is limited
- serially enlarging cardiothoracic ratio
- hemodynamic compromise may manifest with signs of cardiogenic pulmonary edema
Echocardiography is the method of choice to confirm the diagnosis, estimate the volume of fluid and most importantly assess the hemodynamic impact of the effusion.
An anechoic separation of pericardial layers can be identified on transthoracic echocardiography when pericardial ﬂuid exceeds 50 mL. In a supine patient, the effusion will first appear posteriorly, tracking anterior to the descending aorta and left atrium. The parasternal long-axis and subcostal four-chamber views are typically favored for inspection of the pericardial space.
Differentiation from an epicardial fat pad and a left pleural effusion, which have similar sonographic appearances, relies on the recognition of the anatomical boundaries of the fluid collection in question; pleural effusions are bounded anteriorly by the descending aorta, and a fat pad will be seen most prominently in the atrioventricular groove. Additionally, epicardial fat pads have a different echotexture, with low-level echoes scattered throughout 13.
The accepted thickness of a normal pericardium, measured on CT scans and on MR images, is often taken at 2 mm 6,10 and abnormal is considered >3-4 mm 10.
CT makes the diagnosis extremely easy but is usually obtained to try and clarify the cause of an effusion rather than to confirm the diagnosis. Pericardial effusions are a frequent incidental finding in unwell hospitalized patients.
Fluid density material is seen surrounding the heart. Careful inspection of the region is necessary to ensure that no invasive mass can be identified.
The depth of the effusion can be used to estimate the likely volume of fluid, provided the fluid is relatively evenly spread throughout the pericardium (i.e. global effusion) 4. Clearly, this does not apply to loculated effusions.
- <5 mm: 50-100 mL
- 5-10 mm: 100-250 mL
- 10-20 mm: 250-500 mL
- >20 mm: >500 mL
However, due to complex pericardial anatomy and fluid being able to pool in the pericardial recesses this relationship is not exact, and it may be better to report volume in more general terms 10-12:
- <10 mm: small
- 10-20 mm: moderate
- >20 mm: large
Treatment and prognosis
If small, asymptomatic and clinically not-suspect then conservative management is usually favored.
If large, symptomatic or there is a clinical concern of the underlying cause (e.g. infection, malignancy) then pericardiocentesis can be performed to drain the fluid. A Seldinger technique is employed, usually under ultrasound/echocardiographic guidance, to insert a drain into the pericardial space 4.
In cases where effusions are recurrent and symptomatic (e.g. malignancy) then pericardial fenestration can be performed.
- hemopericardium: has higher attenuation on CT and often a different clinical context
- cardiomegaly: can sometimes mimic an effusion
- 1. Lin E, Escott E, Garg K et-al. Practical differential diagnosis for CT and MRI. Thieme Medical Pub. (2008) ISBN:1588906558. Read it at Google Books - Find it at Amazon
- 2. Chen JT, Putman CE, Hedlund LW et-al. Widening of the subcarinal angle by pericardial effusion. AJR Am J Roentgenol. 1982;139 (5): 883-7. AJR Am J Roentgenol (abstract) - Pubmed citation
- 3. Arthur, Stephen; Beeharry-Panray, Gailash; FitzGerald, Jonathan; Loke, Ian. Hypothyroidism presenting with recurrent pericardial tamponade - BMJ Case Reports. doi:10.1136/bcr.03.2009.1674
- 4. Zamorano JL, Bax JJ, Rademakers FE. The ESC Textbook of Cardiovascular Imaging. Springer Verlag. (2010) ISBN:1848824203. Read it at Google Books - Find it at Amazon
- 5. Weissman NJ, Adelmann GA. Cardiac imaging secrets. Elsevier Health Sciences. (2004) ISBN:1560535156. Read it at Google Books - Find it at Amazon
- 6. Wang ZJ, Reddy GP, Gotway MB et-al. CT and MR imaging of pericardial disease. Radiographics. 2003;23 Spec No : S167-80. doi:10.1148/rg.23si035504 - Pubmed citation
- 7. Shimony A, Fox BD, Langleben D et-al. Incidence and significance of pericardial effusion in patients with pulmonary arterial hypertension. Can J Cardiol. 2013;29 (6): 678-82. doi:10.1016/j.cjca.2012.04.009 - Pubmed citation
- 8. Imazio M, Adler Y. Management of pericardial effusion. Eur. Heart J. 2012;34 (16): 1186-97. doi:10.1093/eurheartj/ehs372 - Pubmed citation
- 9. Tehranzadeh J, Kelley MJ. The differential density sign of pericardial effusion. Radiology. 1979;133 (1): 23-30. doi:10.1148/133.1.23 - Pubmed citation
- 10. Munden RF, Carter BW, Chiles C, MacMahon H, Black WC, Ko JP, McAdams HP, Rossi SE, Leung AN, Boiselle PM, Kent MS, Brown K, Dyer DS, Hartman TE, Goodman EM, Naidich DP, Kazerooni EA, Berland LL, Pandharipande PV. Managing Incidental Findings on Thoracic CT: Mediastinal and Cardiovascular Findings. A White Paper of the ACR Incidental Findings Committee. (2018) Journal of the American College of Radiology : JACR. doi:10.1016/j.jacr.2018.04.029 - Pubmed
- 11. Ivens EL, Munt BI, Moss RR. Pericardial disease: what the general cardiologist needs to know. (2007) Heart (British Cardiac Society). 93 (8): 993-1000. doi:10.1136/hrt.2005.086587 - Pubmed
- 12. Bogaert J, Francone M. Pericardial disease: value of CT and MR imaging. (2013) Radiology. 267 (2): 340-56. doi:10.1148/radiol.13121059 - Pubmed
- 13. Imazio M, Adler Y. Management of pericardial effusion. (2013) European heart journal. 34 (16): 1186-97. doi:10.1093/eurheartj/ehs372 - Pubmed
- 14. Azarbal A, LeWinter MM. Pericardial Effusion. Cardiol Clin. 2017 Nov;35(4):515-524. PMID: 29025543. doi:10.1016/j.ccl.2017.07.005
- 15. Karim Abdur Rehman, Jorge Betancor, Bo Xu, Arnav Kumar, Carlos Godoy Rivas, Kimi Sato, Leslie P. Wong, Craig R. Asher, Allan L. Klein. Uremic pericarditis, pericardial effusion, and constrictive pericarditis in end-stage renal disease: Insights and pathophysiology. (2017) Clinical Cardiology. 40 (10): 839. doi:10.1002/clc.22770