Καλοήθης πλευριτική συλλογή

Benign Pleural Effusions

Lateral collection

(The text is taken from the doctoral thesis of Dr Athanasios Kleontas)

In humans, under normal conditions, the pleural cavity contains 0.26±0.1 ml/kg of pleural fluid, i.e. approximately 20 ml (10).

Pathogenesis of pleural effusion

Pleural effusion will occur when the rate of pleural fluid production exceeds the rate of fluid absorption. The main mechanisms leading to pleural fluid accumulation in the pleural cavity are (48):

the changes in the equilibrium of the component pressures
disorders in lymphatic drainage, and
changes in the permeability of the capillary microcirculation and mesothelial cells

The main factors that lead to an increase in production and decrease in fluid absorption are:

Increase production of the liquid

Increased production of interstitial fluid in the lung

Left heart failure

Pneumonia

Pulmonary embolism

Increase in intravascular pressure in the pleura

Right or left heart failure

Superior vena cava syndrome

Increase in pleural fluid protein

Reduction of pleural pressure

Atelectasis of the lung

Increase in the elastic recoil of the lung

Increase in fluid in the peritoneal cavity

Ascetic

Peritoneal dialysis

Erosion of the major thoracic duct

Reduction of the absorption of pleural fluid

Obstruction of the lymphatic vessels in the pleural wall of the pleura

Increase in venous pressure

Superior vena cava syndrome

Right heart failure

The most common causes of pleural effusion are (64):

Heart failure with reduced ejection fraction or acute heart failure
Bacterial pneumonia
Pulmonary embolism
Neoplasia
Viral infections
Cardiac surgeries

Causes of pleural effusion

The causes of benign pleural effusion are categorized as follows:

Infectious causes

Bacterial infections
Bacterial pneumonia
Parapneumonic collection and inspiration
Tuberculosis
Viral infections
Viral pneumonias
Parapneumonic collection and inspiration
HIV

Neoplastic causes

Kaposi's sarcoma
Lymphoma (chylothorax, pyothorax)
Mesothelioma
Ovarian cancer
Meigs syndrome

Lung diseases

Trapped lung
Pulmonary embolism
Pulmonary sarcoidosis
Exposure to asbestos

Cardiological diseases

Heart failure
Compressive pericarditis
Pulmonary vein stenosis
Superior vena cava syndrome
Dressler's syndrome

Liver diseases

Alcoholism
Cirrhosis
Amoebic liver abscess

Gastrointestinal diseases

Intra-abdominal abscess
Esophageal perforation
Chronic pancreatitis
Acute pancreatitis
Postoperative period of abdominal surgery

Autoimmune diseases

Rheumatoid arthritis
Systemic lupus erythematosus
Pharmacogenic seronitis
Sjogren's syndrome
Wegener's carcinoma
Churg-Strauss syndrome

Diseases of the reproductive system

Endometriosis
Ovarian hyperstimulation syndrome
Urinothorax

Other causes

Idiopath
Trauma
Iatrogenic injury
Peritoneal dialysis
Hypothyroidism
Uremic pleurisy
Pseudostraw
Ascetic
Yellow eye syndrome
Coronary heart surgery

Medicines

Amiodarone
Beta blockers
Alkaloids of the erysipelas
L-tryptophan
Methotrexate
Nitrofurantoin
Phenytoin
Praktololi
Minoxidil
Methysergides
Bromocriptine
Blueomycin
Mitomycin
Procarbazine
Cyclophosphamide
Interleukin-2
Dasatinibis
Dandrolene

In particular in the case of chylothorax, the causes are (65):

Malignant obstruction of the thoracic duct
Trauma
Iatrogenic injuries
Genetic causes
Thoracic duct atresia
Communication of the thoracic duct with the pleural cavity
Trauma during childbirth
Other causes
Lymphangioleiomyomatosis
Gorham's disease
Noonan syndrome

Correlation between etiological factor of pleural effusion and clinical picture

Depending on the etiopathogenesis of pleural effusion, the clinical findings, as obtained during history taking and clinical examination of the patient, are also relevant (64):

Heart failure

Hypoxygenemia

Pulmonary or peripheral edema

Jugular distension

3^ος heart rate (S3 gallop)

Bacterial pneumonia

Cough

Fever

Quivering

Pulmonary embolism

Shortness of breath

Chest pain

Quivering

Unilateral swelling of the lower limb

Immobilisation or recent long journey

Obesity or pregnancy

Malignancy

History of malignancy

Tumour of lung, breast, pancreas, colon

Fever

Viral infection

Cough

Easy fatigue

Myalgia

Fever

Exanthema

Pericarditis

Acute chest pain

Jugular distension

Pericardial collection

Electrocardiographic changes

Pulmonary vein stenosis

Recent cardiac catheterization

Pulmonary hypertension

Superior vena cava syndrome

Facial swelling

Swelling of the upper limbs

Thoracic epiphlebitis

Intra-abdominal abscess

Abdominal pain

Quivering

Nausea

Vomiting

Fever

Cirrhosis of the liver

Ascetic

Medusa head (abdominal epiglottis)

Palmar erythema

History of alcoholism or viral hepatitis

Esophageal perforation

Chest or abdominal pain

Fever

Esophageal volume

Gastroesophageal reflux disease

Recent upper digestive endoscopy

Pancreatitis

Abdominal pain

Nausea

Vomiting

Anorexia

Increased levels of amylase and lipase

Endometriosis

Pelvic pain

Infertility

Dysmenorrhea

Meigs syndrome

History of ovarian cancer

Ovarian hyperstimulation syndrome

Infertility treatment history

Abdominal pain

Urinothorax

Urinary obstruction

Recent urological surgery

Mesothelioma

Pleural volume

History of exposure to asbestos

Chylothorax

Chest volume

Chest injury

Lipids in the pleural fluid

Pseudostraw

Rheumatoid disease
History of tuberculosis or pleurisy
Nephrotic syndrome

Swelling

Proteinuria

Rheumatoid arthritis

Swelling and joint pain

Yellow eye syndrome

Lymphedema

Yellow nails

Bronchiectasis

Diagnostic approach to pleural effusion

In summary, the initial diagnostic approach to suspected pleural effusion involves the following steps (66):

Chest radiograph (supine, anteroposterior, lateral, lateral supine) and imaging confirmation of pleural effusion (Figure 10A)
Diagnostic thoracocentesis (best performed under echo-guided thoracic ultrasound - echo-guided thoracocentesis)
Pleural fluid analysis
Cytological examination
Blood test
- Haematocrit
- White blood cell count and type
Biochemical test
- pH
- Glucose
- Lactic dehydrogenase (LDH)
- Albumin
- Total proteins
- In special cases:
  - Adenosine diaminase (ADA)
  - Cholesterol
  - Triglycerides
  - B-type natriuretic peptide (BNP)
  - Urias
  - Creatinine
  - Amylase
- Cancer markers
Microbiological examination
- Cultivation for pathogens and fungi
- Direct Gram staining
Calculation of Light criteria to differentiate whether the liquid is a di- or exudate
- Pleural fluid protein/serum protein ratio > 0.5
- Pleural fluid LDH/serum LDH ratio > 0.6
- Pleural fluid LDH > 2/3 of the upper normal value of blood serum LDH
Transthoracic ultrasound for the detection of diaphragms, inclusions and masses
Chest CT in complicated parapneumonic collections (Figure 10B, 10C)
Percutaneous biopsy or better thoracoscopy for drainage and taking biopsies

Chest X-rays with pleural effusion of the right hemithorax

Computed tomography of the chest with pleural effusion of the right hemithorax

Computed tomography of the chest with pleural effusion of the left hemithorax

Diagnostic assessment of pleural fluid markers

Macroscopic examination of pleural fluid

The macroscopic characteristics of pleural fluid, such as colour, complexion, clarity, consistency and odour can help us in the differential diagnosis of its aetiology (66). Thus, in the case of haemorrhagic pleural fluid, whose haematocrit is > 50% of the haematocrit of the patient's peripheral blood, we are tipped off that it is haemothorax. In general, bleeding pleural fluid is seen in cases of malignancy, trauma, tuberculosis, pulmonary embolism with infarct, postoperative, ruptured arteriovenous malformations (telangiectasias) and catamenial pneumothorax. In the case of milky complexion, there is a strong suspicion of chylothorax or pseudochylothorax. In the case of fever caused by anaerobic microbes, the pleural fluid is cloudy, purulent and foul-smelling. When food debris is found in the pleural fluid, the possibility of rupture of the oesophagus is high. If the pleural fluid is yellowish-green (like bile), there is a possibility of cholothorax. When the pleural fluid looks like anchovy sauce, it is a rupture of an amoebic abscess. If the pleural fluid has an ammonia smell, it is probably a urinothorax. Black pleural fluid has been reported in cases of malignant melanoma, Aspergillus niger and Rhizopus oryzae infection and rupture of the pancreatic cyst (67).

Haematological examination of pleural fluid

This test essentially determines the red blood cell count and the number and type of white blood cells (68):

When red blood cells (RBC) > 100000/mL (100 × 10⁶/L), then the primary disease may be:
- Malignancy
- Trauma
- Parapneumonic collection
- Pulmonary embolism
- Hereditary haemorrhagic telangiectasia
- Catamenial pneumothorax
When the white blood cell count (WBC) > 10000/mm3 (10 × 109/L), then the likelihood of fever increases

Neutrophils > 50% of white blood cells recommend:
- Parapneumonic collection
- Empyema
- Pulmonary embolism
- Malignant pleural effusion (20% of cases)
- Acute tuberculous pleurisy (7% of cases)
- Intra-abdominal diseases
- Lymphocytes make up 80% of white blood cells:
- Tuberculosis
- Lymphoma
- Chronic rheumatic pleurisy
- Sarcoidosis
- Late pleurisy after cardiac surgery

Cytological examination of pleural fluid

Cytological examination of pleural fluid can help diagnose malignant neoplasms in 60% of cases. Usually no more than two samples are needed. Further study of the samples by immunohistochemistry can establish the exact identification of the neoplasia. The presence of non-leukocytic cells in the pleural fluid usually indicates the presence of malignancy. The presence of mesothelial cells in the process of mitosis may mimic adenocarcinoma. Usually the results obtained by the cytology laboratory have the following characteristics (66):

Insufficient sample - absence of mesothelial cells or only degenerated cells
Satisfactory sample, without identification of neoplastic cells (this does not exclude the existence of malignancy)
Presence of atypical cells - presence of inflammatory or neoplastic cells
Suspicious for malignancy sample - cells with malignant characteristics observed
Malignant pleural effusion - definite identification of neoplastic cells (immunohistochemistry required)

Biochemical examination of pleural fluid

The biochemical examination of the pleural fluid first helps to characterise the pleural fluid as a di- or exudate and then, by detecting specific substances, the differential diagnosis of the primary disease is made. This is followed by an analysis of the most important substances identified qualitatively and quantitatively in pleural fluid (68):

Proteins

When the protein level is > 3 g/dL (30 g/L), it is an exudate (an insufficient criterion in itself) (68)
Pleural fluid protein/serum protein ratio > 0.5, recommends exudative collection (68)
In patients with heart failure receiving diuretic treatment, if the difference between serum and pleural fluid proteins is greater than 3.1 g/dL (31 g/L), it is a diathromy (68)

Galactic dehydrogenase (LDH)

If LDH > 2/3 of the upper normal value of serum LDH, then it is an exudate (68)
If pleural fluid LDH/serum LDH ratio > 0.6, recommends exudative collection (68)
LDH is elevated (usually > 500 units/L) in 75% of patients with tuberculous pleurisy (69)
Very high LDH levels (usually > 1000 units/L) are detected in complicated parapneumonic collections and tuberculous pleurisy (68)

Glucose

Glucose < 60 mg/dL (3.3 mmol/L) is seen in complicated parapneumonic effusion, tuberculosis, neoplasia and rheumatoid arthritis (68)
Glucose < 29 mg/dL (1.6 mmol/L) is seen in rheumatoid arthritis (66)
Pleural fluid that shows low glucose levels usually also shows low pH and high LDH levels (68)

Adenosine diaminase (ADA)

ADA > 40 units/L (667 nanocatal/L [nkat/L]) indicates (70):
- Tuberculosis (90% of cases)
- Embolism (90% of cases)
- Complicated parapneumonic effusion (30% of cases)
- Neoplasia (5% of cases)
- Rheumatoid arthritis

pH < 2 recommends drainage of the collection (66)
pH < 3 is observed in (66):
- Malignant pleural effusion
- Complicated pleural infection
- Disease of connective tissue (e.g. rheumatoid arthritis)
- Tuberculous pleurisy
- Esophageal perforation

Nucleic acid enhancement (NAA)

NAA can confirm tuberculous pleurisy with (71):
- Sensitivity 62%
- Specialty 98%

Interferon c

Gamma interferon appears to have moderate sensitivity (48-88%) and specificity (82%) for the diagnosis of extrapulmonary tuberculosis (72)

Amylase

Abnormal amylase values are observed in (73):
Neoplasms (mainly adenocarcinoma), usually sialate amylase
Acute pancreatitis
Pseudocyst of the pancreas
Esophageal perforation, usually salivary amylase
Rupture of an ectopic pregnancy
It is not a routine test when there is no clinical suspicion of pancreatitis or ruptured oesophagus

Cholesterol and triglycerides

In the case of chylothorax (66):
- The presence of chylomicrons confirms chylothorax
- Triglycerides > 110 mg/dL (1.24 mmol/L) confirm chylothorax
- Triglycerides < 50 mg/dL (0.56 mmol/L) exclude chylothorax
- Cholesterol levels are low and no cholesterol crystals are detected
In the case of pseudochylothorax (66):
- Cholesterol > 200 mg/dL (5.18 mmol/L) confirms pseudochylothorax
- The presence of cholesterol crystals confirms pseudochylothorax
- Usually no chylomicrons are detected

Creatinine

Bidiremia with pleural fluid creatinine/serum creatinine ratio > 1, and low pH is seen in case of urinothorax (66)

N-terminal pro-B-type natriuretic peptide (NT-proBNP)

NT-proBNP > 1500 pg/mL observed in heart failure

Cancer markers

May be useful in the differential diagnosis of malignant from benign pleural effusions
The sensitivity and specificity of each indicator shall be reported (74)(75)(76)(77)(78)(79):
- CEA: sensitivity 54.9% and specificity 96.2%
- CA3: sensitivity 50.7% and specificity 98.3%
- CA9: sensitivity 25-37.6% and specificity 96-98%
- CA 125: sensitivity 48% and specificity 85%
- CYFRA1: sensitivity 55-62.5% and specificity 91-93.2%
- VEGF: sensitivity 75% and specificity 72%
- Telomerase: sensitivity 76% and specificity 87%
- Survivin: sensitivity 74% and specificity 85%
- Mesothelin: sensitivity 19-68% and specificity 88-100%

Albumin

The difference between serum blood albumin minus pleural fluid albumin < 1.2 g/dL is observed in exudates (87% of cases) (80)

Distinction of pleural fluid into di- or exudate

Identification of the type of pleural fluid, i.e. whether it is a di- or exudate, is essential in order to start the differential diagnosis process. Bidroma is usually caused by an imbalance of hydrostatic pressure and intravascular volume and typical causes of its formation are heart failure and liver cirrhosis. In most cases, the diastroma is reduced by proper treatment of the primary disease. Similarly, exudate is mainly formed when local intrathoracic factors prevent drainage of pleural fluid, in cases such as pneumonia, fever, malignancies and thromboembolism. Several criteria have therefore been proposed to objectively distinguish the type of pleural effusion. The best known and widely applied are Light's modified criteria (66):

Pleural fluid protein/serum protein ratio > 0.5
Pleural fluid LDH/serum LDH ratio > 0.6
Pleural fluid LDH > 2/3 of the upper normal value of blood serum LDH
Pleural fluid protein > 3 g/dL (29 g/L)

One criterion is sufficient to confirm that the type of liquid is an exudate

Similarly, other alternative criteria have been proposed to achieve the same distinction, such as (80):

Pleural fluid LDH > 45% of the upper normal value of blood serum LDH
Pleural fluid cholesterol > 45 mg/dL (1.16 mmol/L)
Pleural fluid protein > 2.9 g/dL (29 g/L)
The difference of serum protein minus pleural fluid protein < 1 g/dL (31 g/L)
The difference between serum blood albumin minus pleural fluid albumin < 2 g/dL (12 g/L)

One criterion is sufficient to confirm that the type of liquid is an exudate

Several studies have been carried out to compare the above criteria. Most notably, Table 1 shows the superiority of Light's criteria over the others (81). Other studies confirm that the protein, lactate dehydrogenase (LDH) and cholesterol criteria have a 90% sensitivity rate in identifying pleural fluid as exudative (82).

Πίνακας 1

Diagnostic characteristics of pleural fluid markers

Causes of diphtheria pleural effusion

The most common causes of bifidromatic pleural effusion include (66):

Left heart failure
Cirrhosis of the liver

Less common causes include (66):

Hypoalbuminemia
Peritoneal dialysis
Hypothyroidism
Nephrotic syndrome
Mitral valve stenosis

Finally, rare causes include (66):

Compressive pericarditis

Urinothorax
Meigs syndrome

Causes of exudative pleural effusion

The most common causes of exudative pleural effusion include (66):

Malignancies
Parapneumonic collections
Tuberculosis
Empyema

Less common causes include (66):

Pulmonary embolism
Rheumatoid arthritis and other autoimmune pleuritis
Benign asbestos pleural effusion
Pancreatitis
After a myocardial infarction
After coronary heart surgery

Finally, rare causes include (66):

Yellow-vein syndrome and other diseases of the lymphatic system
Pharmacotherapy-induced pleural effusion
Mycotic

Additional diagnostic tools in the investigation of pleural effusion

Transthoracic ultrasound

Can easily show the existence of free or encapsulated pleural effusion (septum)

Ultrasound shows higher specificity but lower sensitivity, compared with chest CT with contrast, in the diagnosis of malignant pleural effusion, as shown in Table 2 (83).

Πίνακας 2

Diagnostic characteristics of imaging techniques

CT scan of the chest with contrast

It should be performed before thoracentesis to highlight benign or malignant pleural thickening (66)
It should be performed for complicated, inflamed, pleural effusion when drainage by tube is unsuccessful and surgery is likely to follow (66)
Should be performed in patients with undiagnosed, exudative, pleural effusion to diagnose the cause (66)

Calibration of the probability of malignant pleural effusion based on CT scan

A scoring system with a sensitivity of 74% and specificity of 92% has been proposed to determine whether a pleural effusion is malignant or benign according to the following chest CT imaging criteria (84):
5 points for the presence of pleural nodule or mass or thickening > 1cm
3 points for the presence of liver metastases
3 points for the presence of an intra-abdominal mass
3 points for the presence of an intrapulmonary mass or nodule > 1cm
2 points for the absence of pleural effusions
2 points for the absence of pericardial effusion
2 points for the absence of an enlarged cardiac silhouette

Total points > 7 confirms malignant pleural effusion

Thoracoscopy under local anaesthesia

It should be performed when malignant pleural effusion is suspected and thoracocentesis is ineffective (66)
Recommended for patients in good general condition and suspected malignant pleural effusion (85)
Thoracoscopic pleural biopsy is considered one of the most effective tests for detecting a positive culture of mycobacterium mycobacterium (66)
Can be used diagnostically and therapeutically (86)
It is a safe procedure with a mortality rate of 0.34%, major complications 1.8% and minor complications 7.3% (86)
May help in the differential diagnosis of undiagnosed pleural effusions (87)
Thoracoscopy with rigid instruments appears to be superior to that with semi-rigid instruments in demonstrating the etiology of pleural effusion (88)

Percutaneous pleural biopsy

It is indicated in patients with undiagnosed pleural effusion and suspected malignancy, when nodular formations are found on CT scan (66)
Abrams needle biopsy may be useful in areas with an increased incidence of TB (66)
Cutting needle biopsy under thoracoscopic or imaging guidance shows greater efficacy than Abrams needle biopsy in patients with suspected malignant pleural effusion (89)
In patients with suspected malignant pleurisy, to improve diagnostic accuracy, a culture and histological examination of the specimens should be sent along with the culture and histological examination (66)
Abrams needle biopsy under CT imaging guidance can approach the results of thoracoscopic biopsy (90)
Cutting needle biopsy guided by transthoracic ultrasound may be useful in determining the cause of pleural effusion (91)

Bronchoscopy

Not indicated as a routine test for the investigation of an undiagnosed pleural effusion (66)
Relevant in patients with haemoptysis or suspected endobronchial obstruction (66)

Management of patients with pleural effusion

Figure 3

Diagnostic algorithm for patients with pleural effusion (92)

Modified by: Fig. 3 McGrath EE¹, Anderson PB.

Diagnosis of pleural effusion: a systematic approach.

Am J Crit Care. 2011 Mar;20(2):119-27

Initial management begins with thoracocentesis and/or placement of a drainage tube to drain the pleural effusion and relieve the patient of symptoms such as respiratory distress (64). Figure 3 above shows one of the relevant algorithms.

Management of patients with benign pleural effusion

In patients with benign pleural effusion, after palliative drainage of the effusion, treatment focuses on treating the underlying disease that is secondary to the pleural effusion (66). When treatment of the primary disease cannot control the recurrence of the pleural effusion, pleurodesis is required. Typically, the iodinated povidone iodide technique has a success rate of 89% and is a good therapeutic approach for patients with recurrent, benign, pleural effusions (93). The presence of bilateral pleural effusion is associated with higher mortality compared with unilateral effusion (94). A proportion of 8-12% of patients with benign pleural effusion may develop malignancy in the first three years after the first appearance of the effusion (95)(96). The relevant algorithm for management follows below depending on the clinical suspicion (97):

postoperative pleural effusion (figure 4)
parapneumonic collection (figure 5)
tuberculous pleurisy (figure 6)
chylothorax and haemothorax (figure 7)
haemothorax (figure 8)

Figure 4

Diagnostic algorithm for patients with postoperative pleural effusion (97)

Modified by: Fig.6 Villena Garrido et al