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Pleural effusion

November 18, 2023

A pleural effusion is accumulation of excessive fluid in the pleural space, the potential space that surrounds each lung. Under normal conditions, pleural fluid is secreted by the parietal pleural capillaries at a rate of 0.6 millilitre per kilogram weight per hour, and is cleared by lymphatic absorption leaving behind only 5–15 millilitres of fluid, which helps to maintain a functional vacuum between the parietal and visceral pleurae. Excess fluid within the pleural space can impair inspiration by upsetting the functional vacuum and hydrostatically increasing the resistance against lung expansion, resulting in a fully or partially collapsed lung.

Pleural effusion
Diagram of fluid buildup in the pleura
SpecialtyPulmonology

Various kinds of fluid can accumulate in the pleural space, such as serous fluid (hydrothorax), blood (hemothorax), pus (pyothorax, more commonly known as pleural empyema), chyle (chylothorax), or very rarely urine (urinothorax). When unspecified, the term "pleural effusion" normally refers to hydrothorax. A pleural effusion can also be compounded by a pneumothorax (accumulation of air in the pleural space), leading to a hydropneumothorax.

Types edit

Various methods can be used to classify pleural fluid.[1] By the origin of the fluid:

By pathophysiology:

  • Transudative pleural effusion
  • Exudative pleural effusion

By the underlying cause (see next section).

Causes edit

 
Pleural effusion

Transudative edit

The most common causes of transudative pleural effusion in the United States are heart failure and cirrhosis. Nephrotic syndrome, leading to the loss of large amounts of albumin in urine and resultant low albumin levels in the blood and reduced colloid osmotic pressure, is another less common cause of pleural effusion. Pulmonary emboli were once thought to cause transudative effusions, but have been recently shown to be exudative.[2] The mechanism for the exudative pleural effusion in pulmonary thromboembolism is probably related to increased permeability of the capillaries in the lung, which results from the release of cytokines or inflammatory mediators (e.g. vascular endothelial growth factor) from the platelet-rich blood clots. The excessive interstitial lung fluid traverses the visceral pleura and accumulates in the pleural space.[citation needed]

Conditions associated with transudative pleural effusions include:[3]

Exudative edit

 
Pleural effusion Anteroposterior Chest X-ray of a pleural effusion. The A arrow shows fluid layering in the right pleural cavity. The B arrow shows the normal width of the lung in the cavity

When a pleural effusion has been determined to be exudative, additional evaluation is needed to determine its cause, and amylase, glucose, pH and cell counts should be measured.

The most common causes of exudative pleural effusions are bacterial pneumonia, cancer (with lung cancer, breast cancer, and lymphoma causing approximately 75% of all malignant pleural effusions), viral infection, and pulmonary embolism.

Another common cause is after heart surgery when incompletely drained blood can lead to an inflammatory response that causes exudative pleural fluid.

Conditions associated with exudative pleural effusions:[3]

Other/ungrouped edit

Other causes of pleural effusion include tuberculosis (though stains of pleural fluid are only rarely positive for acid-fast bacilli, this is the most common cause of pleural effusions in some developing countries), autoimmune disease such as systemic lupus erythematosus, bleeding (often due to chest trauma), chylothorax (most commonly caused by trauma), and accidental infusion of fluids.[6] Less common causes include esophageal rupture or pancreatic disease, intra-abdominal abscesses, rheumatoid arthritis, asbestos pleural effusion, mesothelioma, Meigs's syndrome (ascites and pleural effusion due to a benign ovarian tumor), and ovarian hyperstimulation syndrome.[6]

Pleural effusions may also occur through medical or surgical interventions, including the use of medications (pleural fluid is usually eosinophilic), coronary artery bypass surgery, abdominal surgery, endoscopic variceal sclerotherapy, radiation therapy, liver or lung transplantation, insertion of ventricular shunt as a treatment method of hydrocephalus,[7][8] and intra- or extravascular insertion of central lines.[citation needed]

Pathophysiology edit

Pleural fluid is secreted by the parietal layer of the pleura and reabsorbed by the lymphatics in the most dependent parts of the parietal pleura, primarily the diaphragmatic and mediastinal regions. Exudative pleural effusions occur when the pleura is damaged, e.g., by trauma, infection, or malignancy, and transudative pleural effusions develop when there is either excessive production of pleural fluid or the resorption capacity is reduced. Light's criteria[9] can be used to differentiate between exudative and transudative pleural effusions.[10]

Diagnosis edit

 
A large left-sided pleural effusion as seen on an upright chest X-ray

A pleural effusion is usually diagnosed on the basis of medical history and physical exam, and confirmed by a chest X-ray. Once accumulated fluid is more than 300 mL, there are usually detectable clinical signs, such as decreased movement of the chest on the affected side, dullness to percussion over the fluid, diminished breath sounds on the affected side, decreased vocal resonance and fremitus (though this is an inconsistent and unreliable sign), and pleural friction rub. Above the effusion, where the lung is compressed, there may be bronchial breathing sounds and egophony. A large effusion there may cause tracheal deviation away from the effusion. A systematic review (2009) published as part of the Rational Clinical Examination Series in the Journal of the American Medical Association showed that dullness to conventional percussion was most accurate for diagnosing pleural effusion (summary positive likelihood ratio, 8.7; 95% confidence interval, 2.2–33.8), while the absence of reduced tactile vocal fremitus made pleural effusion less likely (negative likelihood ratio, 0.21; 95% confidence interval, 0.12–0.37).[11]

Imaging edit

A pleural effusion appears as an area of whiteness on a standard posteroanterior chest X-ray.[12] Normally, the space between the visceral pleura and the parietal pleura cannot be seen. A pleural effusion infiltrates the space between these layers. Because the pleural effusion has a density similar to water, it can be seen on radiographs. Since the effusion has greater density than the rest of the lung, it gravitates towards the lower portions of the pleural cavity. The pleural effusion behaves according to basic fluid dynamics, conforming to the shape of pleural space, which is determined by the lung and chest wall. If the pleural space contains both air and fluid, then an air-fluid level that is horizontal will be present, instead of conforming to the lung space.[13] Chest radiographs in the lateral decubitus position (with the patient lying on the side of the pleural effusion) are more sensitive and can detect as little as 50 mL of fluid. Between 250 and 600mL of fluid must be present before upright chest X-rays can detect a pleural effusion (e.g., blunted costophrenic angles).[14]

Chest computed tomography is more accurate for diagnosis and may be obtained to better characterize the presence, size, and characteristics of a pleural effusion. Lung ultrasound, nearly as accurate as CT and more accurate than chest X-ray, is increasingly being used at the point of care to diagnose pleural effusions, with the advantage that it is a safe, dynamic, and repeatable imaging modality.[15] To increase diagnostic accuracy of detection of pleural effusion sonographically, markers such as boomerang and VIP signs can be utilized.[16]

  •  

    Massive left-sided pleural effusion (whiteness) in a patient presenting with lung cancer.

  •  

    CT scan of the chest showing a left-sided pleural effusion. The fluid usually settles at the lowest space due to gravity; in this case, at the back because the patient is supine.

  • The lung expanding within an area of pleural effusion as seen by ultrasound

  •  

    Micrograph of a pleural fluid cytopathology specimen showing malignant mesothelioma, one cause of a pleural effusion.

  •  

    A pleural effusion as seen on lateral upright chest x-ray

  • Pleural effusion as seen behind the heart.[17]

  •  

    Massive pleural effusion, later proven to be hemothorax in a South Indian male.

Thoracentesis edit

Once a pleural effusion is diagnosed, its cause must be determined. Pleural fluid is drawn out of the pleural space in a process called thoracentesis, and it should be done in almost all patients who have pleural fluid that is at least 10 mm in thickness on CT, ultrasonography, or lateral decubitus X-ray and that is new or of uncertain etiology. In general, the only patients who do not require thoracentesis are those who have heart failure with symmetric pleural effusions and no chest pain or fever; in these patients, diuresis can be tried, and thoracentesis is avoided unless effusions persist for more than 3 days.[18] In a thoracentesis, a needle is inserted through the back of the chest wall in the sixth, seventh, or eighth intercostal space on the midaxillary line, into the pleural space. The use of ultrasound to guide the procedure is now standard of care as it increases accuracy and decreases complications.[19][20] After removal, the fluid may then be evaluated for:

  1. Chemical composition including protein, lactate dehydrogenase (LDH), albumin, amylase, pH, and glucose
  2. Gram stain and culture to identify possible bacterial infections
  3. White and red blood cell counts and differential white blood cell counts
  4. Cytopathology to identify cancer cells, but may also identify some infective organisms
  5. Other tests as suggested by the clinical situation – lipids, fungal culture, viral culture, tuberculosis cultures, lupus cell prep, specific immunoglobulins

Light's criteria edit

Transudate vs. exudate
Transudate Exudate
Main causes hydrostatic
pressure,
colloid
osmotic pressure 		Inflammation-Increased
vascular permeability
Appearance Clear[21] Cloudy[21]
Specific gravity < 1.012 > 1.020
Protein content < 2.5 g/dL > 2.9 g/dL[22]
fluid protein/
serum protein		 < 0.5 > 0.5[23]
SAAG =
Serum [albumin] - Effusion [albumin]		 > 1.2 g/dL < 1.2 g/dL[24]
fluid LDH
upper limit for serum		 < 0.6 or < 23 > 0.6[22] or > 23[23]
Cholesterol content < 45 mg/dL > 45
Radiodensity on CT scan 2 to 15 HU[25] 4 to 33 HU[25]
 
Instruments for needle biopsy of the pleura.[26]

Definitions of the terms "transudate" and "exudate" are the source of much confusion. Briefly, transudate is produced through pressure filtration without capillary injury while exudate is "inflammatory fluid" leaking between cells.[27]

Transudative pleural effusions are defined as effusions that are caused by systemic factors that alter the pleural equilibrium, or Starling forces. The components of the Starling forces – hydrostatic pressure, permeability, and oncotic pressure (effective pressure due to the composition of the pleural fluid and blood) – are altered in many diseases, e.g., left ventricular failure, kidney failure, liver failure, and cirrhosis. Exudative pleural effusions, by contrast, are caused by alterations in local factors that influence the formation and absorption of pleural fluid (e.g., bacterial pneumonia, cancer, pulmonary embolism, and viral infection).[28]

An accurate diagnosis of the cause of the effusion, transudate versus exudate, relies on a comparison of the chemistries in the pleural fluid to those in the blood, using Light's criteria. According to Light's criteria (Light, et al. 1972), a pleural effusion is likely exudative if at least one of the following exists:[29]

  1. The ratio of pleural fluid protein to serum protein is greater than 0.5
  2. The ratio of pleural fluid LDH and serum LDH is greater than 0.6
  3. Pleural fluid LDH is greater than 0.6 [22] or 23[29] times the normal upper limit for serum. Different laboratories have different values for the upper limit of serum LDH, but examples include 200[30] and 300[30] IU/l.[31]

The sensitivity and specificity of Light's criteria for detection of exudates have been measured in many studies and are usually reported to be around 98% and 80%, respectively.[32][33] This means that although Light's criteria are relatively accurate, twenty percent of patients that are identified by Light's criteria as having exudative pleural effusions actually have transudative pleural effusions. Therefore, if a patient identified by Light's criteria as having an exudative pleural effusion appears clinically to have a condition that usually produces transudative effusions, additional testing is needed. In such cases, albumin levels in blood and pleural fluid are measured. If the difference between the albumin level in the blood and the pleural fluid is greater than 1.2 g/dL (12 g/L), this suggests that the patient has a transudative pleural effusion.[24] However, pleural fluid testing is not perfect, and the final decision about whether a fluid is a transudate or an exudate is based not on chemical analysis of the fluid, but an accurate diagnosis of the disease that produces the fluid.[27] The traditional definitions of transudate as a pleural effusion due to systemic factors and an exudate as a pleural effusion due to local factors have been used since 1940 or earlier (Light et al., 1972). Previous to Light's landmark study, which was based on work by Chandrasekhar, investigators unsuccessfully attempted to use other criteria, such as specific gravity, pH, and protein content of the fluid, to differentiate between transudates and exudates. Light's criteria are highly statistically sensitive for exudates (although not very statistically specific). More recent studies have examined other characteristics of pleural fluid that may help to determine whether the process producing the effusion is local (exudate) or systemic (transudate). The table above illustrates some of the results of these more recent studies. However, it should be borne in mind that Light's criteria are still the most widely used criteria.[citation needed]

The Rational Clinical Examination Series review found that bilateral effusions, symmetric and asymmetric, are the most common distribution in heart failure (60% of effusions in heart failure will be bilateral). When there is asymmetry in heart failure-associated pleural effusions (either unilateral or one side larger than the other), the right side is usually more involved than the left.[11] The instruments pictured are accurately shaped, however, most hospitals now use safer disposable trocars. Because these are single use, they are always sharp and have a much smaller risk of cross patient contamination.[citation needed]

Treatment edit

Treatment depends on the underlying cause of the pleural effusion.

Therapeutic aspiration may be sufficient; larger effusions may require insertion of an intercostal drain (either pigtail or surgical). When managing these chest tubes, it is important to make sure the chest tubes do not become occluded or clogged. A clogged chest tube in the setting of continued production of fluid will result in residual fluid left behind when the chest tube is removed. This fluid can lead to complications such as hypoxia due to lung collapse from the fluid, or fibrothorax if scarring occurs. Repeated effusions may require chemical (talc, bleomycin, tetracycline/doxycycline), or surgical pleurodesis, in which the two pleural surfaces are scarred to each other so that no fluid can accumulate between them. This is a surgical procedure that involves inserting a chest tube, then either mechanically abrading the pleura or inserting the chemicals to induce a scar. This requires the chest tube to stay in until the fluid drainage stops. This can take days to weeks and can require prolonged hospitalizations. If the chest tube becomes clogged, fluid will be left behind and the pleurodesis will fail.[citation needed]

Pleurodesis fails in as many as 30% of cases. An alternative is to place a PleurX Pleural Catheter or Aspira Drainage Catheter. This is a 15Fr chest tube with a one-way valve. Each day the patient or caregivers connect it to a simple vacuum tube and remove from 600 to 1000 mL of fluid, and can be repeated daily. When not in use, the tube is capped. This allows patients to be outside the hospital. For patients with malignant pleural effusions, it allows them to continue chemotherapy if indicated. Generally, the tube is in for about 30 days, and then it is removed when space undergoes spontaneous pleurodesis.

Tubercular pleural effusion is one of the common extrapulmonary forms of tuberculosis. Treatment consists of antituberculosis treatment (ATT). The currently recommended ATT regime is two months of isoniazid, rifampicin, ethambutol and pyrazinamide followed by four months of isoniazid, rifampicin and ethambutol.[34]

See also edit

References edit

  1. ^ "Pleural effusion". U.S. National Library of Medicine. Retrieved 2 July 2021.
  2. ^ Porcel JM, Light RW (2008). "Pleural effusions due to pulmonary embolism". Current Opinion in Pulmonary Medicine. 14 (4): 337–42. doi:10.1097/MCP.0b013e3282fcea3c. PMID 18520269. S2CID 44337698.
  3. ^ a b Galagan et al. Color Atlas of Body Fluids. CAP Press, Northfield, 2006
  4. ^ "Atelectasis". The Lecturio Medical Concept Library. Retrieved 2 July 2021.
  5. ^ de Menezes Lyra R (July 1997). "A modified outer cannula can help thoracentesis after pleural biopsy" (PDF). Chest. 112 (1): 296. doi:10.1378/chest.112.1.296. PMID 9228404.[permanent dead link]
  6. ^ a b Jany, B; Welte, T (May 2019). "Pleural Effusion in Adults—Etiology, Diagnosis, and Treatment". Deutsches Ärzteblatt International. 116 (21): 377–386. doi:10.3238/arztebl.2019.0377. PMC 6647819. PMID 31315808.
  7. ^ Gupta, A. K.; Berry, M. (April 1994). "Ventriculo-peritoneal shunt presenting with recurrent pleural effusion: Report of a new complication". Pediatric Radiology. 24 (2): 147. doi:10.1007/bf02020178. ISSN 0301-0449. PMID 8078722. S2CID 28016135.
  8. ^ Raicevic Mirjana, Nikolovski Srdjan, Golubovic Emilija. Pleural Effusion as a Ventriculo-Peritoneal Shunt Complication in Children (Meeting Abstract). Acta Med Acad. 2019;48(S1):26.
  9. ^ Porcel, José M.; Light, Richard W. (2006-04-01). "Diagnostic approach to pleural effusion in adults". American Family Physician. 73 (7): 1211–1220. ISSN 0002-838X. PMID 16623208.
  10. ^ Saguil, Aaron; Wyrick, Kristen; Hallgren, John (2014-07-15). "Diagnostic approach to pleural effusion". American Family Physician. 90 (2): 99–104. ISSN 1532-0650. PMID 25077579.
  11. ^ a b Wong CL, Holroyd-Leduc J, Straus SE (Jan 2009). "Does this patient have a pleural effusion?". JAMA. 301 (3): 309–17. doi:10.1001/jama.2008.937. PMID 19155458.
  12. ^ Corne; et al. (2002). Chest X-Ray Made Easy. Churchill Livingstone. ISBN 0-443-07008-3.
  13. ^ Squire, Lucy Frank; Novelline, Robert A. (2004). Squire's fundamentals of radiology. Cambridge: Harvard University Press. pp. 132–3. ISBN 0-674-01279-8.
  14. ^ Bell DJ, Jones J. "Pleural effusion". Radiopaedia. Retrieved July 20, 2021.
  15. ^ Volpicelli, Giovanni; Elbarbary, Mahmoud; Blaivas, Michael; Lichtenstein, Daniel A.; Mathis, Gebhard; Kirkpatrick, Andrew W.; Melniker, Lawrence; Gargani, Luna; Noble, Vicki E. (2012-04-01). "International evidence-based recommendations for point-of-care lung ultrasound". Intensive Care Medicine. 38 (4): 577–591. doi:10.1007/s00134-012-2513-4. ISSN 1432-1238. PMID 22392031.
  16. ^ Lau, James Siu Ki; Yuen, Chi Kit; Mok, Ka Leung; Yan, Wing Wa; Kan, Pui Gay (2017-11-15). "Visualization of the inferoposterior thoracic wall (VIP) and boomerang signs-novel sonographic signs of right pleural effusion". The American Journal of Emergency Medicine. 36 (7): 1134–1138. doi:10.1016/j.ajem.2017.11.023. ISSN 1532-8171. PMID 29162443. S2CID 41876899.
  17. ^ "UOTW #23 - Ultrasound of the Week". Ultrasound of the Week. 22 October 2014. Retrieved 27 May 2017.
  18. ^ Light, Richard W. "Pleural Effusion". Merck Manual for Health Care Professionals. Merck Sharp & Dohme Corp. Retrieved 21 August 2013.
  19. ^ Feller-Kopman, David (2007-07-01). "Therapeutic thoracentesis: the role of ultrasound and pleural manometry". Current Opinion in Pulmonary Medicine. 13 (4): 312–318. doi:10.1097/MCP.0b013e3281214492. ISSN 1070-5287. PMID 17534178. S2CID 21367134.
  20. ^ Gordon, Craig E.; Feller-Kopman, David; Balk, Ethan M.; Smetana, Gerald W. (2010-02-22). "Pneumothorax following thoracentesis: a systematic review and meta-analysis". Archives of Internal Medicine. 170 (4): 332–339. doi:10.1001/archinternmed.2009.548. ISSN 1538-3679. PMID 20177035.
  21. ^ a b The University of Utah • Spencer S. Eccles Health Sciences Library > WebPath images > "Inflammation".
  22. ^ a b c Heffner J, Brown L, Barbieri C (1997). "Diagnostic value of tests that discriminate between exudative and transudative pleural effusions. Primary Study Investigators". Chest. 111 (4): 970–80. doi:10.1378/chest.111.4.970. PMID 9106577.
  23. ^ a b Light R, Macgregor M, Luchsinger P, Ball W (1972). "Pleural effusions: the diagnostic separation of transudates and exudates". Ann Intern Med. 77 (4): 507–13. doi:10.7326/0003-4819-77-4-507. PMID 4642731.
  24. ^ a b Roth BJ, O'Meara TF, Gragun WH (1990). "The serum-effusion albumin gradient in the evaluation of pleural effusions". Chest. 98 (3): 546–9. doi:10.1378/chest.98.3.546. PMID 2152757.
  25. ^ a b Cullu, Nesat; Kalemci, Serdar; Karakas, Omer; Eser, Irfan; Yalcin, Funda; Boyaci, Fatma Nurefsan; Karakas, Ekrem (2013). "Efficacy of CT in diagnosis of transudates and exudates in patients with pleural effusion". Diagnostic and Interventional Radiology. 20: 116–20. doi:10.5152/dir.2013.13066. ISSN 1305-3825. PMC 4463296. PMID 24100060.
  26. ^ de Menezes Lyra R (1997). "A modified outer cannula can help thoracentesis after pleural biopsy". Chest. 112 (1): 296. doi:10.1378/chest.112.1.296. PMID 9228404.
  27. ^ a b Light RW, Macgregor MI, Luchsinger PC, Ball WC Jr (October 1972). "Pleural effusions: the diagnostic separation of transudates and exudates". Annals of Internal Medicine. 77 (4): 507–13. doi:10.7326/0003-4819-77-4-507. PMID 4642731. Retrieved 20 July 2021.
  28. ^ Light, Richard W. "Ch. 257: Disorders of the Pleura and Mediastinum". In Fauci AS, Braunwald E, Kasper DL, Hauser SL, Longo DL, Jameson JL, Loscalzo J (eds.). Harrison's Principles of Internal Medicine (17th ed.).
  29. ^ a b Light RW, Macgregor MI, Luchsinger PC, Ball WC (1972). "Pleural effusions: the diagnostic separation of transudates and exudates". Ann Intern Med. 77 (4): 507–13. doi:10.7326/0003-4819-77-4-507. PMID 4642731. S2CID 31947040.
  30. ^ a b Joseph J, Badrinath P, Basran GS, Sahn SA (November 2001). "Is the pleural fluid transudate or exudate? A revisit of the diagnostic criteria". Thorax. 56 (11): 867–70. doi:10.1136/thorax.56.11.867. PMC 1745948. PMID 11641512.
  31. ^ Joseph J, Badrinath P, Basran GS, Sahn SA (2002). "Is albumin gradient or fluid to serum albumin ratio better than the pleural fluid lactate dehydroginase in the diagnostic of separation of pleural effusion?". BMC Pulmonary Medicine. 2: 1. doi:10.1186/1471-2466-2-1. PMC 101409. PMID 11914151.  
  32. ^ Romero S, Martinez A, Hernandez L, Fernandez C, Espasa A, Candela A, Martin C (2000). "Light's criteria revisited: consistency and comparison with new proposed alternative criteria for separating pleural transudates from exudates". Respiration; International Review of Thoracic Diseases. 67 (1): 18–23. doi:10.1159/000029457. PMID 10705257. S2CID 45667293.
  33. ^ Porcel JM, Peña JM, Vicente de Vera C, Esquerda A (Feb 18, 2006). "[Reappraisal of the standard method (Light's criteria) for identifying pleural exudates]". Medicina Clinica. 126 (6): 211–3. doi:10.1157/13084870. PMID 16510093.
  34. ^ World Health Organisation (2021). . WHO. pp. 1–104. ISBN 9789241550529. Archived from the original on March 20, 2019. Retrieved 5 September 2021.

External links edit

November 18, 2023
pleural, effusion, pleural, effusion, accumulation, excessive, fluid, pleural, space, potential, space, that, surrounds, each, lung, under, normal, conditions, pleural, fluid, secreted, parietal, pleural, capillaries, rate, millilitre, kilogram, weight, hour, . A pleural effusion is accumulation of excessive fluid in the pleural space the potential space that surrounds each lung Under normal conditions pleural fluid is secreted by the parietal pleural capillaries at a rate of 0 6 millilitre per kilogram weight per hour and is cleared by lymphatic absorption leaving behind only 5 15 millilitres of fluid which helps to maintain a functional vacuum between the parietal and visceral pleurae Excess fluid within the pleural space can impair inspiration by upsetting the functional vacuum and hydrostatically increasing the resistance against lung expansion resulting in a fully or partially collapsed lung Pleural effusionDiagram of fluid buildup in the pleuraSpecialtyPulmonologyVarious kinds of fluid can accumulate in the pleural space such as serous fluid hydrothorax blood hemothorax pus pyothorax more commonly known as pleural empyema chyle chylothorax or very rarely urine urinothorax When unspecified the term pleural effusion normally refers to hydrothorax A pleural effusion can also be compounded by a pneumothorax accumulation of air in the pleural space leading to a hydropneumothorax Contents 1 Types 2 Causes 2 1 Transudative 2 2 Exudative 2 3 Other ungrouped 3 Pathophysiology 4 Diagnosis 4 1 Imaging 4 2 Thoracentesis 4 3 Light s criteria 5 Treatment 6 See also 7 References 8 External linksTypes editVarious methods can be used to classify pleural fluid 1 By the origin of the fluid Serous fluid hydrothorax Blood haemothorax Chyle chylothorax Pus pyothorax or empyema Urine urinothorax By pathophysiology Transudative pleural effusion Exudative pleural effusionBy the underlying cause see next section Causes edit nbsp Pleural effusionTransudative edit The most common causes of transudative pleural effusion in the United States are heart failure and cirrhosis Nephrotic syndrome leading to the loss of large amounts of albumin in urine and resultant low albumin levels in the blood and reduced colloid osmotic pressure is another less common cause of pleural effusion Pulmonary emboli were once thought to cause transudative effusions but have been recently shown to be exudative 2 The mechanism for the exudative pleural effusion in pulmonary thromboembolism is probably related to increased permeability of the capillaries in the lung which results from the release of cytokines or inflammatory mediators e g vascular endothelial growth factor from the platelet rich blood clots The excessive interstitial lung fluid traverses the visceral pleura and accumulates in the pleural space citation needed Conditions associated with transudative pleural effusions include 3 Congestive heart failure Liver cirrhosis Severe hypoalbuminemia Nephrotic syndrome Acute atelectasis 4 Myxedema Peritoneal dialysis Meigs s syndrome Obstructive uropathy End stage kidney diseaseExudative edit nbsp Pleural effusion Anteroposterior Chest X ray of a pleural effusion The A arrow shows fluid layering in the right pleural cavity The B arrow shows the normal width of the lung in the cavityWhen a pleural effusion has been determined to be exudative additional evaluation is needed to determine its cause and amylase glucose pH and cell counts should be measured Red blood cell counts are elevated in cases of bloody effusions for example after heart surgery or hemothorax from incomplete evacuation of blood Amylase levels are elevated in cases of esophageal rupture pancreatic pleural effusion or cancer Glucose is decreased with cancer bacterial infections or rheumatoid pleuritis pH is low in empyema lt 7 2 and maybe low in cancer If cancer is suspected the pleural fluid is sent for cytology If cytology is negative and cancer is still suspected either a thoracoscopy or needle biopsy 5 of the pleura may be performed Gram staining and culture should also be done If tuberculosis is possible examination for Mycobacterium tuberculosis either a Ziehl Neelsen or Kinyoun stain and mycobacterial cultures should be done A polymerase chain reaction for tuberculous DNA may be done or adenosine deaminase or interferon gamma levels may also be checked The most common causes of exudative pleural effusions are bacterial pneumonia cancer with lung cancer breast cancer and lymphoma causing approximately 75 of all malignant pleural effusions viral infection and pulmonary embolism Another common cause is after heart surgery when incompletely drained blood can lead to an inflammatory response that causes exudative pleural fluid Conditions associated with exudative pleural effusions 3 Parapneumonic effusion due to pneumonia Malignancy either lung cancer or metastases to the pleura from elsewhere Infection empyema due to bacterial pneumonia Trauma Pulmonary infarction Pulmonary embolism Autoimmune disorders Pancreatitis Ruptured esophagus Boerhaave s syndrome Rheumatoid pleurisy Drug induced lupusOther ungrouped edit Other causes of pleural effusion include tuberculosis though stains of pleural fluid are only rarely positive for acid fast bacilli this is the most common cause of pleural effusions in some developing countries autoimmune disease such as systemic lupus erythematosus bleeding often due to chest trauma chylothorax most commonly caused by trauma and accidental infusion of fluids 6 Less common causes include esophageal rupture or pancreatic disease intra abdominal abscesses rheumatoid arthritis asbestos pleural effusion mesothelioma Meigs s syndrome ascites and pleural effusion due to a benign ovarian tumor and ovarian hyperstimulation syndrome 6 Pleural effusions may also occur through medical or surgical interventions including the use of medications pleural fluid is usually eosinophilic coronary artery bypass surgery abdominal surgery endoscopic variceal sclerotherapy radiation therapy liver or lung transplantation insertion of ventricular shunt as a treatment method of hydrocephalus 7 8 and intra or extravascular insertion of central lines citation needed Pathophysiology editPleural fluid is secreted by the parietal layer of the pleura and reabsorbed by the lymphatics in the most dependent parts of the parietal pleura primarily the diaphragmatic and mediastinal regions Exudative pleural effusions occur when the pleura is damaged e g by trauma infection or malignancy and transudative pleural effusions develop when there is either excessive production of pleural fluid or the resorption capacity is reduced Light s criteria 9 can be used to differentiate between exudative and transudative pleural effusions 10 Diagnosis edit nbsp A large left sided pleural effusion as seen on an upright chest X rayA pleural effusion is usually diagnosed on the basis of medical history and physical exam and confirmed by a chest X ray Once accumulated fluid is more than 300 mL there are usually detectable clinical signs such as decreased movement of the chest on the affected side dullness to percussion over the fluid diminished breath sounds on the affected side decreased vocal resonance and fremitus though this is an inconsistent and unreliable sign and pleural friction rub Above the effusion where the lung is compressed there may be bronchial breathing sounds and egophony A large effusion there may cause tracheal deviation away from the effusion A systematic review 2009 published as part of the Rational Clinical Examination Series in the Journal of the American Medical Association showed that dullness to conventional percussion was most accurate for diagnosing pleural effusion summary positive likelihood ratio 8 7 95 confidence interval 2 2 33 8 while the absence of reduced tactile vocal fremitus made pleural effusion less likely negative likelihood ratio 0 21 95 confidence interval 0 12 0 37 11 Imaging edit A pleural effusion appears as an area of whiteness on a standard posteroanterior chest X ray 12 Normally the space between the visceral pleura and the parietal pleura cannot be seen A pleural effusion infiltrates the space between these layers Because the pleural effusion has a density similar to water it can be seen on radiographs Since the effusion has greater density than the rest of the lung it gravitates towards the lower portions of the pleural cavity The pleural effusion behaves according to basic fluid dynamics conforming to the shape of pleural space which is determined by the lung and chest wall If the pleural space contains both air and fluid then an air fluid level that is horizontal will be present instead of conforming to the lung space 13 Chest radiographs in the lateral decubitus position with the patient lying on the side of the pleural effusion are more sensitive and can detect as little as 50 mL of fluid Between 250 and 600mL of fluid must be present before upright chest X rays can detect a pleural effusion e g blunted costophrenic angles 14 Chest computed tomography is more accurate for diagnosis and may be obtained to better characterize the presence size and characteristics of a pleural effusion Lung ultrasound nearly as accurate as CT and more accurate than chest X ray is increasingly being used at the point of care to diagnose pleural effusions with the advantage that it is a safe dynamic and repeatable imaging modality 15 To increase diagnostic accuracy of detection of pleural effusion sonographically markers such as boomerang and VIP signs can be utilized 16 nbsp Massive left sided pleural effusion whiteness in a patient presenting with lung cancer nbsp CT scan of the chest showing a left sided pleural effusion The fluid usually settles at the lowest space due to gravity in this case at the back because the patient is supine source source source source source The lung expanding within an area of pleural effusion as seen by ultrasound nbsp Micrograph of a pleural fluid cytopathology specimen showing malignant mesothelioma one cause of a pleural effusion nbsp A pleural effusion as seen on lateral upright chest x ray source source source source Pleural effusion as seen behind the heart 17 nbsp Massive pleural effusion later proven to be hemothorax in a South Indian male Thoracentesis edit Once a pleural effusion is diagnosed its cause must be determined Pleural fluid is drawn out of the pleural space in a process called thoracentesis and it should be done in almost all patients who have pleural fluid that is at least 10 mm in thickness on CT ultrasonography or lateral decubitus X ray and that is new or of uncertain etiology In general the only patients who do not require thoracentesis are those who have heart failure with symmetric pleural effusions and no chest pain or fever in these patients diuresis can be tried and thoracentesis is avoided unless effusions persist for more than 3 days 18 In a thoracentesis a needle is inserted through the back of the chest wall in the sixth seventh or eighth intercostal space on the midaxillary line into the pleural space The use of ultrasound to guide the procedure is now standard of care as it increases accuracy and decreases complications 19 20 After removal the fluid may then be evaluated for Chemical composition including protein lactate dehydrogenase LDH albumin amylase pH and glucose Gram stain and culture to identify possible bacterial infections White and red blood cell counts and differential white blood cell counts Cytopathology to identify cancer cells but may also identify some infective organisms Other tests as suggested by the clinical situation lipids fungal culture viral culture tuberculosis cultures lupus cell prep specific immunoglobulinsLight s criteria edit Transudate vs exudate viewtalkeditTransudate ExudateMain causes hydrostaticpressure colloid osmotic pressure Inflammation Increased vascular permeabilityAppearance Clear 21 Cloudy 21 Specific gravity lt 1 012 gt 1 020Protein content lt 2 5 g dL gt 2 9 g dL 22 fluid protein serum protein lt 0 5 gt 0 5 23 SAAG Serum albumin Effusion albumin gt 1 2 g dL lt 1 2 g dL 24 fluid LDHupper limit for serum lt 0 6 or lt 2 3 gt 0 6 22 or gt 2 3 23 Cholesterol content lt 45 mg dL gt 45Radiodensity on CT scan 2 to 15 HU 25 4 to 33 HU 25 nbsp Instruments for needle biopsy of the pleura 26 Definitions of the terms transudate and exudate are the source of much confusion Briefly transudate is produced through pressure filtration without capillary injury while exudate is inflammatory fluid leaking between cells 27 Transudative pleural effusions are defined as effusions that are caused by systemic factors that alter the pleural equilibrium or Starling forces The components of the Starling forces hydrostatic pressure permeability and oncotic pressure effective pressure due to the composition of the pleural fluid and blood are altered in many diseases e g left ventricular failure kidney failure liver failure and cirrhosis Exudative pleural effusions by contrast are caused by alterations in local factors that influence the formation and absorption of pleural fluid e g bacterial pneumonia cancer pulmonary embolism and viral infection 28 An accurate diagnosis of the cause of the effusion transudate versus exudate relies on a comparison of the chemistries in the pleural fluid to those in the blood using Light s criteria According to Light s criteria Light et al 1972 a pleural effusion is likely exudative if at least one of the following exists 29 The ratio of pleural fluid protein to serum protein is greater than 0 5 The ratio of pleural fluid LDH and serum LDH is greater than 0 6 Pleural fluid LDH is greater than 0 6 22 or 2 3 29 times the normal upper limit for serum Different laboratories have different values for the upper limit of serum LDH but examples include 200 30 and 300 30 IU l 31 The sensitivity and specificity of Light s criteria for detection of exudates have been measured in many studies and are usually reported to be around 98 and 80 respectively 32 33 This means that although Light s criteria are relatively accurate twenty percent of patients that are identified by Light s criteria as having exudative pleural effusions actually have transudative pleural effusions Therefore if a patient identified by Light s criteria as having an exudative pleural effusion appears clinically to have a condition that usually produces transudative effusions additional testing is needed In such cases albumin levels in blood and pleural fluid are measured If the difference between the albumin level in the blood and the pleural fluid is greater than 1 2 g dL 12 g L this suggests that the patient has a transudative pleural effusion 24 However pleural fluid testing is not perfect and the final decision about whether a fluid is a transudate or an exudate is based not on chemical analysis of the fluid but an accurate diagnosis of the disease that produces the fluid 27 The traditional definitions of transudate as a pleural effusion due to systemic factors and an exudate as a pleural effusion due to local factors have been used since 1940 or earlier Light et al 1972 Previous to Light s landmark study which was based on work by Chandrasekhar investigators unsuccessfully attempted to use other criteria such as specific gravity pH and protein content of the fluid to differentiate between transudates and exudates Light s criteria are highly statistically sensitive for exudates although not very statistically specific More recent studies have examined other characteristics of pleural fluid that may help to determine whether the process producing the effusion is local exudate or systemic transudate The table above illustrates some of the results of these more recent studies However it should be borne in mind that Light s criteria are still the most widely used criteria citation needed The Rational Clinical Examination Series review found that bilateral effusions symmetric and asymmetric are the most common distribution in heart failure 60 of effusions in heart failure will be bilateral When there is asymmetry in heart failure associated pleural effusions either unilateral or one side larger than the other the right side is usually more involved than the left 11 The instruments pictured are accurately shaped however most hospitals now use safer disposable trocars Because these are single use they are always sharp and have a much smaller risk of cross patient contamination citation needed Treatment editTreatment depends on the underlying cause of the pleural effusion Therapeutic aspiration may be sufficient larger effusions may require insertion of an intercostal drain either pigtail or surgical When managing these chest tubes it is important to make sure the chest tubes do not become occluded or clogged A clogged chest tube in the setting of continued production of fluid will result in residual fluid left behind when the chest tube is removed This fluid can lead to complications such as hypoxia due to lung collapse from the fluid or fibrothorax if scarring occurs Repeated effusions may require chemical talc bleomycin tetracycline doxycycline or surgical pleurodesis in which the two pleural surfaces are scarred to each other so that no fluid can accumulate between them This is a surgical procedure that involves inserting a chest tube then either mechanically abrading the pleura or inserting the chemicals to induce a scar This requires the chest tube to stay in until the fluid drainage stops This can take days to weeks and can require prolonged hospitalizations If the chest tube becomes clogged fluid will be left behind and the pleurodesis will fail citation needed Pleurodesis fails in as many as 30 of cases An alternative is to place a PleurX Pleural Catheter or Aspira Drainage Catheter This is a 15Fr chest tube with a one way valve Each day the patient or caregivers connect it to a simple vacuum tube and remove from 600 to 1000 mL of fluid and can be repeated daily When not in use the tube is capped This allows patients to be outside the hospital For patients with malignant pleural effusions it allows them to continue chemotherapy if indicated Generally the tube is in for about 30 days and then it is removed when space undergoes spontaneous pleurodesis Tubercular pleural effusion is one of the common extrapulmonary forms of tuberculosis Treatment consists of antituberculosis treatment ATT The currently recommended ATT regime is two months of isoniazid rifampicin ethambutol and pyrazinamide followed by four months of isoniazid rifampicin and ethambutol 34 See also editPleural disease Empyema Heart failure Pulmonary embolism Subpulmonic effusion ThoracentesisReferences edit Pleural effusion U S National Library of Medicine Retrieved 2 July 2021 Porcel JM Light RW 2008 Pleural effusions due to pulmonary embolism Current Opinion in Pulmonary Medicine 14 4 337 42 doi 10 1097 MCP 0b013e3282fcea3c PMID 18520269 S2CID 44337698 a b Galagan et al Color Atlas of Body Fluids CAP Press Northfield 2006 Atelectasis The Lecturio Medical Concept Library Retrieved 2 July 2021 de Menezes Lyra R July 1997 A modified outer cannula can help thoracentesis after pleural biopsy PDF Chest 112 1 296 doi 10 1378 chest 112 1 296 PMID 9228404 permanent dead link a b Jany B Welte T May 2019 Pleural Effusion in Adults Etiology Diagnosis and Treatment Deutsches Arzteblatt International 116 21 377 386 doi 10 3238 arztebl 2019 0377 PMC 6647819 PMID 31315808 Gupta A K Berry M April 1994 Ventriculo peritoneal shunt presenting with recurrent pleural effusion Report of a new complication Pediatric Radiology 24 2 147 doi 10 1007 bf02020178 ISSN 0301 0449 PMID 8078722 S2CID 28016135 Raicevic Mirjana Nikolovski Srdjan Golubovic Emilija Pleural Effusion as a Ventriculo Peritoneal Shunt Complication in Children Meeting Abstract Acta Med Acad 2019 48 S1 26 Porcel Jose M Light Richard W 2006 04 01 Diagnostic approach to pleural effusion in adults American Family Physician 73 7 1211 1220 ISSN 0002 838X PMID 16623208 Saguil Aaron Wyrick Kristen Hallgren John 2014 07 15 Diagnostic approach to pleural effusion American Family Physician 90 2 99 104 ISSN 1532 0650 PMID 25077579 a b Wong CL Holroyd Leduc J Straus SE Jan 2009 Does this patient have a pleural effusion JAMA 301 3 309 17 doi 10 1001 jama 2008 937 PMID 19155458 Corne et al 2002 Chest X Ray Made Easy Churchill Livingstone ISBN 0 443 07008 3 Squire Lucy Frank Novelline Robert A 2004 Squire s fundamentals of radiology Cambridge Harvard University Press pp 132 3 ISBN 0 674 01279 8 Bell DJ Jones J Pleural effusion Radiopaedia Retrieved July 20 2021 Volpicelli Giovanni Elbarbary Mahmoud Blaivas Michael Lichtenstein Daniel A Mathis Gebhard Kirkpatrick Andrew W Melniker Lawrence Gargani Luna Noble Vicki E 2012 04 01 International evidence based recommendations for point of care lung ultrasound Intensive Care Medicine 38 4 577 591 doi 10 1007 s00134 012 2513 4 ISSN 1432 1238 PMID 22392031 Lau James Siu Ki Yuen Chi Kit Mok Ka Leung Yan Wing Wa Kan Pui Gay 2017 11 15 Visualization of the inferoposterior thoracic wall VIP and boomerang signs novel sonographic signs of right pleural effusion The American Journal of Emergency Medicine 36 7 1134 1138 doi 10 1016 j ajem 2017 11 023 ISSN 1532 8171 PMID 29162443 S2CID 41876899 UOTW 23 Ultrasound of the Week Ultrasound of the Week 22 October 2014 Retrieved 27 May 2017 Light Richard W Pleural Effusion Merck Manual for Health Care Professionals Merck Sharp amp Dohme Corp Retrieved 21 August 2013 Feller Kopman David 2007 07 01 Therapeutic thoracentesis the role of ultrasound and pleural manometry Current Opinion in Pulmonary Medicine 13 4 312 318 doi 10 1097 MCP 0b013e3281214492 ISSN 1070 5287 PMID 17534178 S2CID 21367134 Gordon Craig E Feller Kopman David Balk Ethan M Smetana Gerald W 2010 02 22 Pneumothorax following thoracentesis a systematic review and meta analysis Archives of Internal Medicine 170 4 332 339 doi 10 1001 archinternmed 2009 548 ISSN 1538 3679 PMID 20177035 a b The University of Utah Spencer S Eccles Health Sciences Library gt WebPath images gt Inflammation a b c Heffner J Brown L Barbieri C 1997 Diagnostic value of tests that discriminate between exudative and transudative pleural effusions Primary Study Investigators Chest 111 4 970 80 doi 10 1378 chest 111 4 970 PMID 9106577 a b Light R Macgregor M Luchsinger P Ball W 1972 Pleural effusions the diagnostic separation of transudates and exudates Ann Intern Med 77 4 507 13 doi 10 7326 0003 4819 77 4 507 PMID 4642731 a b Roth BJ O Meara TF Gragun WH 1990 The serum effusion albumin gradient in the evaluation of pleural effusions Chest 98 3 546 9 doi 10 1378 chest 98 3 546 PMID 2152757 a b Cullu Nesat Kalemci Serdar Karakas Omer Eser Irfan Yalcin Funda Boyaci Fatma Nurefsan Karakas Ekrem 2013 Efficacy of CT in diagnosis of transudates and exudates in patients with pleural effusion Diagnostic and Interventional Radiology 20 116 20 doi 10 5152 dir 2013 13066 ISSN 1305 3825 PMC 4463296 PMID 24100060 de Menezes Lyra R 1997 A modified outer cannula can help thoracentesis after pleural biopsy Chest 112 1 296 doi 10 1378 chest 112 1 296 PMID 9228404 a b Light RW Macgregor MI Luchsinger PC Ball WC Jr October 1972 Pleural effusions the diagnostic separation of transudates and exudates Annals of Internal Medicine 77 4 507 13 doi 10 7326 0003 4819 77 4 507 PMID 4642731 Retrieved 20 July 2021 Light Richard W Ch 257 Disorders of the Pleura and Mediastinum In Fauci AS Braunwald E Kasper DL Hauser SL Longo DL Jameson JL Loscalzo J eds Harrison s Principles of Internal Medicine 17th ed a b Light RW Macgregor MI Luchsinger PC Ball WC 1972 Pleural effusions the diagnostic separation of transudates and exudates Ann Intern Med 77 4 507 13 doi 10 7326 0003 4819 77 4 507 PMID 4642731 S2CID 31947040 a b Joseph J Badrinath P Basran GS Sahn SA November 2001 Is the pleural fluid transudate or exudate A revisit of the diagnostic criteria Thorax 56 11 867 70 doi 10 1136 thorax 56 11 867 PMC 1745948 PMID 11641512 Joseph J Badrinath P Basran GS Sahn SA 2002 Is albumin gradient or fluid to serum albumin ratio better than the pleural fluid lactate dehydroginase in the diagnostic of separation of pleural effusion BMC Pulmonary Medicine 2 1 doi 10 1186 1471 2466 2 1 PMC 101409 PMID 11914151 nbsp Romero S Martinez A Hernandez L Fernandez C Espasa A Candela A Martin C 2000 Light s criteria revisited consistency and comparison with new proposed alternative criteria for separating pleural transudates from exudates Respiration International Review of Thoracic Diseases 67 1 18 23 doi 10 1159 000029457 PMID 10705257 S2CID 45667293 Porcel JM Pena JM Vicente de Vera C Esquerda A Feb 18 2006 Reappraisal of the standard method Light s criteria for identifying pleural exudates Medicina Clinica 126 6 211 3 doi 10 1157 13084870 PMID 16510093 World Health Organisation 2021 Consolidated Guidelines on Tuberculosis Treatment Module 3 Diagnosis Rapid diagnostics for tuberculosis detection 2021 update WHO pp 1 104 ISBN 9789241550529 Archived from the original on March 20 2019 Retrieved 5 September 2021 External links editMedlinePlus Encyclopedia Pleural Effusion Pleural Effusion Images from MedPix Retrieved from https en wikipedia org w index php title Pleural effusion amp oldid 1181856780, wikipedia, wiki, book, books, library,

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