100 Hepatopulmonary Syndrome
Definition
Hepatopulmonary syndrome (HPS) is defined by abnormal oxygen exchange in association with intrapulmonary vascular dilatation (IPVD) in patients with liver disease.1 The presence of other cardiopulmonary disease that alters gas exchange does not exclude this diagnosis.2–5 HPS is most commonly associated with cirrhosis1 and portal hypertension, but neither of these are required.6 The correlation between the degree of liver dysfunction and the presence7–8 and severity3–4,7,9–10 of this syndrome is debated.
Clinical Features
HPS usually presents as dyspnea6,11 in patients who are already known to have liver disease. HPS-induced shortness of breath often is relieved when the patient is lying down,11–12 and therefore is referred to as platypnea. There are no consistently noted physical examination findings.6,13 Hypoxia is often worse in the standing position (orthodeoxia),12 and it generally can be corrected with sufficient supplemental oxygen.1,3,4,10,14
Pathophysiology
Dilated precapillary vessels and pleural-based arteriovenous connections are noted at autopsy in cases of HPS.15 Current thinking suggests that these abnormal vessels develop due to a functional excess of pulmonary vasodilators1; they cause hypoxia through ventilation/perfusion (V/Q) mismatching, arteriovenous (AV) shunting, and limitation of oxygen diffusion to red blood cells (RBCs) in the center of the vessel.15–17 The hyperdynamic circulation, which is characteristic of cirrhosis, likely exacerbates this problem by decreasing RBC transit time through the pulmonary capillaries, further limiting oxygen diffusion.15,17 Orthodeoxia is due to a worsening of V/Q mismatch and AV shunting in the standing position.18
Nitric oxide (NO) has been implicated as a key vasodilator in HPS. Exhaled NO levels are increased in patients with cirrhosis compared to healthy controls and in HPS patients compared to cirrhotic patients without HPS; NO levels correlate with the severity of cirrhosis and gas exchange abnormalities.19 In rat models of HPS induced by ligation of the common bile duct (CBDL), increased levels of endothelial20 and inducible NO synthase (eNOS and iNOS, respectively) have been observed, and administration of a nitric oxide synthase inhibitor prevents the development of pulmonary vasodilation and HPS.21
Excess eNOS is located in the pulmonary arteries and capillaries and is associated with impaired vasoconstriction; levels of this enzyme correlate with the degree of gas exchange abnormalities.20 CBDL rats demonstrate increased hepatic production of endothelin-1 (ET-1)22 and increased vascular expression of the endothelin-B receptor (ET-B)23 in proportion to the severity of gas exchange abnormalities22,24; interaction between ET-1 and the ET-B receptor, therefore, is believed to be the trigger for increased eNOS expression. This theory is further supported by data that show a reduction in eNOS expression and an improvement in HPS when CBDL animals are treated with endothelin-B receptor antagonists.24
iNOS is expressed in macrophages found in the lungs of CBDL rats,21 while treatment of these rats with norfloxacin is associated with a reduction in the rate of gram-negative bacterial translocation, accumulation of pulmonary macrophages, production of iNOS, and severity of HPS.25 Pulmonary macrophages in CBDL rats also have been noted to express elevated levels of heme-oxygenase-1 (HO-1), an enzyme that catalyzes formation of the vasodilating gas, carbon monoxide (CO).26 Increased levels of carboxyhemoglobin (COHb) have been observed in rat26 as well as human27 subjects with HPS, and treatment with an HO-1 inhibitor normalizes COHb levels and partially alleviates HPS in CBDL rats.26 These data suggest that CO also contributes to pulmonary vasodilation in this syndrome. Finally, tumor necrosis factor alpha (TNF-α) rises in CBDL animals in association with ET-1 and endotoxin levels, and it has been proposed to influence accumulation of the iNOS- and HO-1-producing pulmonary macrophages.28 Administration of pentoxifylline, a phosphodiesterase inhibitor that suppresses production of TNF-α, is associated with a reduction in TNF-α levels, pulmonary macrophage accumulation, ET-B receptor and eNOS expression, and severity of HPS.29
Diagnosis
HPS should be considered in any patient with liver disease and dyspnea or hypoxia. Evaluation begins with an arterial blood gas (ABG), with the patient resting in the seated position and breathing room air.6,17 No specific gas exchange criteria for HPS have been universally accepted,30 but a 2004 European Respiratory Society (ERS) task force advised further evaluation when the PaO2 is less than 80 mm Hg or the alveolar-arterial oxygen gradient (A-a gradient) is 15 mm Hg or greater (≥20 mm Hg for patients over age 64).17
Accurate HPS diagnosis requires the presence of ABG changes that cannot be fully explained by comorbid cardiopulmonary disease. Conditions that frequently coexist with cirrhosis that may influence gas exchange include chronic obstructive pulmonary disease (COPD), congestive heart failure, restrictive lung disease due to ascites or hepatic hydrothorax, α1-antitrypsin deficiency, and portopulmonary hypertension (distinguished from HPS by its increased pulmonary artery pressure and vascular resistance; in HPS, pulmonary artery pressure and vascular resistance are low).31 Patients should have a chest x-ray (CXR) and pulmonary function tests12 to assess for pulmonary disease; of note, increased markings at the lung bases on CXR1,6,8 and/or a reduced diffusion capacity for carbon monoxide (DLCO)3–4,7,13,18 are common findings in HPS and, in isolation, do not exclude the diagnosis. Cardiac function is evaluated by echocardiogram, often concurrently with IPVD assessment (see later discussion).
When a gas exchange abnormality is present and not fully explained by another cardiopulmonary disease, the patient should be evaluated for the presence of IPVDs. Contrast-enhanced echocardiography (CEE) is commonly used for this purpose; advantages include that it is widely available, it permits concurrent evaluation for cardiac causes of abnormal gas exchange, and it can distinguish intracardiac from intrapulmonary shunt based on the number of cardiac cycles required for agitated saline to pass from the right to left atrium.12 CEE is highly sensitive for the presence IPVDs30 and may document them in up to 82% of patients tested.32 Compared with patients without IPVDs, those with a positive CEE have a greater incidence of dyspnea33 and abnormal CXRs,9,33 as well as more severe cirrhosis9,32–33 and gas exchange abnormalities.9,33 However, many patients with IPVDs demonstrated by CEE do not have gas exchange abnormalities,5,8,13,32–33 and so this test is not very specific for HPS.30
Technetium-99m-labeled macroaggregated albumin (99mTc MAA) lung perfusion scanning is an alternative test for IPVDs. It is expensive, requires radiation exposure,13 and cannot document the site of shunting, but it is able to provide a quantitative shunt fraction13,17,30 that correlates directly with the A-a gradient3,10,14 and inversely with the room air PaO23,10,14,34 and oxygen saturation.34 Perfusion scanning is less sensitive than CEE for the detection of IPVDs,5 but positive results are rare in patients without HPS.5,10,34 Because of these test characteristics, CEE has been advocated as the first-line modality for evaluating patients with liver disease and abnormal gas exchange.5,10,17 If CEE is positive but the relative contributions of other cardiopulmonary disease and possible HPS are not clear, lung perfusion scanning can determine if HPS is present.5,10,12,17