Liver function tests
Liver function tests (LFTs), also referred to as a liver panel, are a group of blood tests designed to evaluate the health and functionality of the liver by measuring levels of specific enzymes, proteins, and waste products in the bloodstream.[1][2] These tests help detect liver inflammation, injury, or disease, as well as monitor the progression of known liver conditions or the effectiveness of treatments.[3] LFTs are commonly ordered when symptoms suggestive of liver issues arise, such as jaundice, abdominal pain, fatigue, or unexplained weight loss, or as part of routine screening for individuals at risk due to factors like heavy alcohol use, viral hepatitis, or metabolic disorders.[1] They are particularly valuable in distinguishing between hepatocellular damage (injury to liver cells) and cholestasis (blockage of bile flow), guiding further diagnostic imaging or biopsies if abnormalities are found.[4] Abnormal results do not always indicate severe disease, as elevations can occur from medications, infections, or non-liver conditions, necessitating clinical correlation.[5] The panel typically includes several key components: alanine transaminase (ALT) and aspartate transaminase (AST), which are enzymes released during liver cell damage; alkaline phosphatase (ALP) and gamma-glutamyl transferase (GGT), markers of bile duct obstruction or alcohol-related injury; bilirubin, a byproduct of red blood cell breakdown processed by the liver; and albumin and total protein, which reflect the liver's synthetic capacity.[3] Interpretation relies on patterns of elevation—for instance, disproportionately high ALT suggests viral or toxic hepatitis, while isolated ALP increases may point to biliary issues—though reference ranges vary by age, sex, and laboratory standards.[6] Performed via a simple venipuncture, LFTs carry minimal risks like bruising, and results are usually available within hours to days.[1]Introduction
Purpose and indications
Liver function tests (LFTs) are a group of blood tests that evaluate various aspects of liver health, including the detection of liver damage, assessment of synthetic capacity (such as protein production), evaluation of biliary function, and monitoring of metabolic processes like bilirubin handling.[3] These tests measure levels of enzymes, proteins, and other substances produced or processed by the liver to provide insights into its overall performance.[2] The development of LFTs traces back to early 20th-century advancements, with the van den Bergh reaction enabling direct measurement of bilirubin as early as 1913, which was pivotal for assessing jaundice and liver dysfunction.[7] By the 1950s, the discovery and clinical application of serum transaminases, such as aspartate aminotransferase (AST) and alanine transaminase (ALT), revolutionized the ability to detect hepatocellular injury through enzyme assays.[8] The primary purposes of LFTs include detecting acute or chronic liver injury, monitoring the progression of liver diseases like hepatitis or cirrhosis, evaluating potential toxicity from medications or alcohol, and assessing surgical risk in patients with suspected liver impairment.[1] They are commonly ordered in clinical scenarios involving symptoms such as jaundice, abdominal pain, fatigue, or unexplained weight loss; risk factors including heavy alcohol use, exposure to viral hepatitis, obesity (predisposing to non-alcoholic fatty liver disease), or medication history (e.g., statins or acetaminophen); and routine screening in at-risk populations like those with diabetes or metabolic syndrome.[2][9] Abnormal LFT results often serve as an initial screening tool, guiding subsequent diagnostics such as abdominal ultrasound for structural abnormalities, serological tests for viral causes, or liver biopsy for definitive histopathological evaluation.[10] This stepwise approach helps clinicians narrow down etiologies and tailor management strategies effectively.[3]Components of a standard panel
A standard liver function test (LFT) panel, also known as a hepatic panel, typically comprises alanine transaminase (ALT), aspartate transaminase (AST), alkaline phosphatase (ALP), total bilirubin, and albumin.[3] These tests are performed on a single blood sample to evaluate key aspects of liver health efficiently.[11] Some variations include gamma-glutamyl transferase (GGT) and prothrombin time (PT) or international normalized ratio (INR) for additional assessment of cholestasis and synthetic function.[12] The inclusion of these components is driven by their ability to provide broad coverage of hepatocellular injury (ALT and AST), cholestasis (ALP and bilirubin), and protein synthesis (albumin), while maintaining cost-effectiveness through bundled testing.[12] This design allows for initial screening of diverse liver conditions without requiring separate assays, optimizing clinical workflows. Guidelines vary slightly by organization; for instance, the American College of Gastroenterology recommends a core panel of ALT, AST, ALP, and bilirubin for initial evaluation of abnormal liver chemistries. The British Society of Gastroenterology recommends an initial panel including GGT alongside bilirubin, albumin, ALT, and ALP to comprehensively assess potential liver disease.[13] Laboratory-specific panels may differ based on regional standards or equipment capabilities.[3] In clinical practice, these panels are commonly ordered under terms like "LFTs" or "hepatic function panel," with results reported in international units such as U/L for enzymes (e.g., ALT, AST, ALP) and mg/dL or μmol/L for bilirubin and g/dL for albumin.[1] The standardization of such panels emerged in the 1970s, facilitated by the advent of automated multichannel analyzers that enabled simultaneous measurement of multiple analytes, revolutionizing routine liver testing.[3]Markers of hepatocellular injury
Alanine transaminase (ALT)
Alanine transaminase (ALT), also known as serum glutamate-pyruvate transaminase (SGPT), is a pyridoxal 5'-phosphate-dependent enzyme that catalyzes the reversible transamination reaction between L-alanine and α-ketoglutarate, producing pyruvate and L-glutamate.[14] This process facilitates the transfer of amino groups, essential for amino acid catabolism and the integration of carbon skeletons into gluconeogenesis and the tricarboxylic acid cycle.[14] ALT is predominantly localized in the cytosol of hepatocytes, with the liver containing the majority of the body's ALT activity—far exceeding concentrations in other tissues such as the kidneys, heart, and skeletal muscle.[14][15] In its physiological role, ALT supports nitrogen metabolism by enabling the conversion of alanine derived from muscle protein breakdown into usable substrates for hepatic energy production and glucose synthesis during fasting or stress.[14] This enzyme's high specificity to the liver underscores its utility as a biomarker for hepatocellular integrity, as damage to liver cells disrupts the cytosolic barrier, allowing ALT to leak into the circulation.[16] Serum ALT activity is quantified through a spectrophotometric assay, which measures the rate of NADH oxidation coupled to the pyruvate produced in the enzymatic reaction, with results expressed in units per liter (U/L).[17] This method relies on the enzyme's dependence on pyridoxal phosphate as a coenzyme, ensuring accurate detection of even low-level activity in clinical samples.[14] Elevations in ALT serum levels primarily stem from hepatocyte necrosis, as seen in conditions like viral hepatitis or hepatotoxin exposure (e.g., acetaminophen overdose), where cellular disruption releases the cytosolic enzyme into the bloodstream.[18][15] Although minor contributions can arise from extrahepatic sources such as muscle injury or renal damage, these are infrequent due to substantially lower ALT concentrations outside the liver.[16][15] Clinically, ALT demonstrates high sensitivity for detecting hepatocellular injury, rising rapidly after the onset of injury and peaking days to weeks later depending on the etiology, such as 1-3 days in acute toxic injury or 7-14 days in viral hepatitis, which allows for early identification of acute liver damage.[18][14] Compared to aspartate transaminase (AST), ALT exhibits greater liver specificity owing to its predominant hepatic localization.[16]Aspartate transaminase (AST)
Aspartate transaminase (AST), also known as serum glutamic-oxaloacetic transaminase (SGOT), is an enzyme that catalyzes the reversible transamination reaction between aspartate and α-ketoglutarate to form oxaloacetate and glutamate.[19] This reaction is pyridoxal phosphate-dependent and occurs in both the cytosol and mitochondria of cells.[19] AST exists in two isoenzymes: a cytosolic form comprising about 20% of total activity and a mitochondrial form accounting for the remaining 80%, with the latter being more prominent in hepatocytes. Physiologically, AST plays a crucial role in amino acid metabolism, facilitating the malate-aspartate shuttle for transferring reducing equivalents across the mitochondrial membrane, contributing to gluconeogenesis by generating oxaloacetate, and supporting the urea cycle through aspartate provision for argininosuccinate synthesis.[20] The enzyme is widely distributed across tissues, with the highest concentrations found in the liver, cardiac muscle, skeletal muscle, kidneys, brain, pancreas, lungs, erythrocytes, and leukocytes.[21] In the liver, AST is predominantly mitochondrial, reflecting its involvement in cellular energy metabolism. AST levels in serum are measured using a kinetic spectrophotometric assay at 37°C, similar to that for alanine transaminase (ALT), where the rate of NADH oxidation is monitored in a coupled reaction with malate dehydrogenase.[19] Normal reference ranges are typically 10-40 U/L for men and 9-32 U/L for women, though values can vary by laboratory and population.[22] Unlike ALT, which is more liver-specific, AST has significant extrahepatic sources, leading to elevations in conditions such as myocardial infarction (from cardiac tissue release), skeletal muscle trauma or rhabdomyolysis, and hemolysis (from erythrocytes).[23] The AST/ALT ratio can help differentiate hepatic from non-hepatic causes, as extrahepatic elevations often show disproportionately higher AST relative to ALT.[24] In clinical practice, AST serves as a marker of hepatocellular injury but is less specific for liver disease due to its broad tissue distribution; however, it is particularly useful in evaluating alcoholic liver disease, where AST levels typically predominate over ALT, often with a ratio exceeding 2:1, reflecting mitochondrial damage from alcohol toxicity.[25] Elevated AST in this context aids in diagnosis and monitoring, though it must be interpreted alongside other tests to confirm hepatic origin.[3]De Ritis ratio (AST/ALT)
The De Ritis ratio, named after Italian hepatologist Fernando De Ritis, is defined as the ratio of serum aspartate transaminase (AST) activity to alanine transaminase (ALT) activity and serves as a diagnostic tool in evaluating patterns of liver injury. It was first described in 1957 in a seminal study examining transaminase levels in patients with viral hepatitis, where the authors noted distinct enzyme elevation patterns that could differentiate disease etiologies.[26][27] The physiological basis of the De Ritis ratio lies in the subcellular localization and tissue distribution of AST and ALT within hepatocytes. ALT is primarily cytosolic and more specific to the liver, whereas AST is present in both cytosol and mitochondria and is also expressed in extrahepatic tissues such as cardiac and skeletal muscle. In acute viral or toxic liver injuries, cytosolic damage leads to greater ALT release relative to AST, resulting in a ratio typically below 1. Conversely, in alcoholic liver disease or advanced cirrhosis, mitochondrial injury disproportionately elevates AST, often yielding a ratio exceeding 2.[27][25] Calculation of the De Ritis ratio is straightforward, involving simple division of the measured serum AST concentration (in units per liter, U/L) by the ALT concentration, yielding a unitless value. In healthy individuals, the ratio approximates 1, reflecting balanced baseline enzyme activities.[28][27] Clinically, the De Ritis ratio aids in distinguishing between etiologies of hepatocellular injury. A ratio greater than 2 is suggestive of alcoholic hepatitis or cirrhosis, where mitochondrial disruption predominates, while a ratio less than 1 is characteristic of nonalcoholic fatty liver disease (NAFLD) or viral hepatitis, indicating primarily cytosolic hepatocyte damage. Ratios exceeding 10 may signal extrahepatic contributions, such as muscle injury, rather than primary liver pathology.[27][29][25] Despite its utility, the De Ritis ratio has limitations as a diagnostic marker. It is not intended for standalone use and requires integration with clinical history, imaging, and other liver function tests for accurate interpretation. Factors such as the temporal dynamics of enzyme release—where ALT peaks earlier than AST in some injuries—medications, and non-liver sources of enzyme elevation can alter the ratio, potentially leading to misdiagnosis if viewed in isolation.[25][28]Markers of cholestasis
Alkaline phosphatase (ALP)
Alkaline phosphatase (ALP) is a membrane-bound glycoprotein enzyme that catalyzes the hydrolysis of phosphate monoesters at an alkaline pH, typically around 10.[30] This enzymatic activity facilitates the removal of phosphate groups from various substrates, playing a role in phosphate metabolism across multiple tissues.[31] In the liver, ALP is predominantly localized on the microvillar surface of bile canaliculi and sinusoidal membranes of hepatocytes.[31] Serum ALP exists as several isoenzymes derived from different tissues, with the liver isoform comprising approximately 50% of total activity and the bone isoform about 40%, while smaller contributions come from the intestine, placenta, and other sources such as kidney and leukocytes.[31] These isoenzymes can be distinguished through techniques like electrophoresis or heat inactivation; the liver isoform is relatively heat-stable, retaining activity after heating to 56–65°C, whereas the bone isoform is more thermolabile.[31] The placental isoform, prominent during pregnancy, is also heat-stable but differs in electrophoretic mobility from the hepatic form.[31] Physiologically, the role of hepatic ALP is not fully understood but is hypothesized to involve the transport of metabolites across the canalicular membrane, contributing to bile formation and flow.[31] Its expression is upregulated in response to biliary pressure or cholestatic conditions, where bile acid accumulation induces de novo synthesis and release of the enzyme from the canalicular membrane.[32] This adaptive response helps mitigate cellular damage from bile acid retention but results in elevated serum levels.[33] ALP activity in serum is commonly measured using a colorimetric assay that employs p-nitrophenylphosphate (pNPP) as the substrate; under alkaline conditions, ALP hydrolyzes pNPP to produce p-nitrophenol, a yellow-colored product quantifiable by absorbance at 405 nm.[31] This method, standardized by the International Federation of Clinical Chemistry (IFCC), provides a sensitive and specific quantification of total ALP activity without requiring prior separation of isoenzymes.[34] Elevations in serum ALP are primarily indicative of cholestasis, arising from intrahepatic causes such as primary biliary cholangitis (PBC) or extrahepatic obstructions like gallstones (choledocholithiasis).[35] In these scenarios, impaired bile flow leads to increased ALP synthesis and shedding into the bloodstream.[33] Non-hepatic differentials include bone disorders (e.g., Paget's disease or osteomalacia) due to the bone isoenzyme and physiological increases during pregnancy from the placental isoform.[36]Gamma-glutamyltransferase (GGT)
Gamma-glutamyltransferase (GGT), also known as gamma-glutamyl transpeptidase, is an enzyme that catalyzes the transfer of the gamma-glutamyl group from glutathione to various acceptor substrates, such as amino acids or peptides, facilitating the hydrolysis of gamma-glutamyl bonds.[37] This enzyme is primarily membrane-bound and is highly expressed in the epithelial cells of the liver, kidney, and pancreas, with significant activity in the biliary tract.[38] Physiologically, GGT plays a key role in the gamma-glutamyl cycle, which is essential for the transport of amino acids across cell membranes and the maintenance of glutathione homeostasis, a critical antioxidant.[39] It also contributes to detoxification processes by enabling the metabolism of glutathione conjugates of xenobiotics, thereby aiding in the elimination of potentially harmful compounds.[40] The expression of GGT is inducible by xenobiotics and oxidative stress through the Nrf2 signaling pathway, which upregulates its transcription to enhance cellular protection against electrophiles and reactive oxygen species.[40] GGT activity in serum is typically measured using a kinetic spectrophotometric assay, where the enzyme transfers the gamma-glutamyl group from the synthetic substrate gamma-glutamyl-p-nitroanilide to an acceptor like glycylglycine, releasing p-nitroaniline, whose formation is quantified by absorbance at 405 nm.[41] Clinically, GGT is a sensitive marker elevated in conditions such as chronic alcohol consumption, even in the absence of overt liver damage, due to its induction by ethanol metabolites.[38] It is also raised by certain drugs, including phenytoin and barbiturates, which induce hepatic enzyme expression.[24] In cholestasis, GGT levels increase, often co-elevating with alkaline phosphatase (ALP), but unlike ALP, GGT remains normal in bone diseases, aiding in distinguishing hepatic from skeletal sources of ALP elevation.[42] The utility of GGT includes screening for alcohol abuse, where persistently elevated levels indicate ongoing consumption or poor treatment compliance, and as an early marker in biliary obstruction, where it rises prior to ALP.[43][44]5' Nucleotidase
5'-Nucleotidase (5'NT), also known as CD73, is a glycosyl phosphatidylinositol-anchored ectoenzyme predominantly located on the plasma membrane of hepatocytes and biliary epithelial cells. It catalyzes the hydrolysis of extracellular 5'-nucleoside monophosphates, such as adenosine monophosphate (AMP), to their corresponding nucleosides and inorganic phosphate, with adenosine being the primary product.[45] This enzymatic activity facilitates the salvage of nucleotides by enabling the uptake and recycling of nucleosides into cellular metabolic pathways.[45] In physiological contexts, 5'NT contributes to purine nucleotide homeostasis and modulates extracellular adenosine levels, which exert cytoprotective and anti-inflammatory effects in the liver. Serum levels of 5'NT rise in conjunction with alkaline phosphatase (ALP) during hepatobiliary disorders, particularly those involving cholestasis or biliary obstruction, reflecting release from damaged plasma membranes.[31] Elevations are observed in conditions such as primary biliary cholangitis (PBC) and hepatic metastases, where biliary epithelium involvement is prominent.[46] Measurement of 5'NT typically involves enzymatic assays that quantify activity using AMP as the substrate, often coupled with colorimetric or spectrophotometric detection of phosphate release.[47] These methods are less routinely performed than those for other markers due to their relative expense and the availability of simpler alternatives like gamma-glutamyltransferase (GGT).[3] Clinically, 5'NT serves as a confirmatory test for hepatic-origin ALP elevations, demonstrating parallel increases that help differentiate liver disease from bone or placental sources; for instance, non-pregnant patients with isolated ALP rises benefit from this specificity.[31] It proves valuable in evaluating infiltrative liver processes, such as malignancies metastasizing to the liver, or autoimmune cholangiopathies like PBC, where it supports diagnosis when standard panels are ambiguous.[46] Compared to GGT, 5'NT offers greater specificity for biliary epithelial damage, as it is not induced by alcohol consumption or certain xenobiotics that affect GGT levels.[48] This makes it a preferable adjunct in scenarios where alcohol history confounds interpretation, though its lower sensitivity limits routine use.[3] As a specialized test, 5'NT complements ALP isoenzyme fractionation by providing functional evidence of hepatobiliary involvement without requiring electrophoretic separation.[31]Markers of bilirubin metabolism
Total bilirubin
Total bilirubin refers to the overall concentration of bilirubin in the blood, which is an orange-yellow pigment derived from the catabolism of heme, primarily from the breakdown of hemoglobin in senescent red blood cells, accounting for approximately 80% of daily bilirubin production.[49] This total encompasses both unconjugated (indirect) bilirubin, which is unbound and lipid-soluble, and conjugated (direct) bilirubin, which is water-soluble after hepatic processing.[49] In the physiological pathway, unconjugated bilirubin, released from heme degradation in the reticuloendothelial system, is transported in plasma tightly bound to albumin to prevent toxicity and deposition in tissues.[49] Upon reaching the liver, it is taken up by hepatocytes and conjugated in the endoplasmic reticulum by the enzyme UDP-glucuronosyltransferase 1A1 (UGT1A1) to form bilirubin mono- and diglucuronides, which are then actively secreted into bile canaliculi for excretion into the intestine.[49] This process ensures efficient elimination, with about 250-400 mg of bilirubin produced and cleared daily in adults.[49] Total bilirubin is measured using the diazo reaction, originally described by van den Bergh, in which bilirubin reacts with diazotized sulfanilic acid to form a colored azobilirubin complex, quantified spectrophotometrically at around 540-570 nm.[50] The total bilirubin level is determined directly from the sample after addition of an accelerator like methanol to solubilize unconjugated bilirubin, while direct bilirubin is measured from the immediate reaction; indirect bilirubin is then calculated by subtraction.[49] Elevations in total bilirubin can arise from pre-hepatic causes, such as excessive production due to hemolysis; hepatic causes, including impaired conjugation or excretion from conditions like viral hepatitis or cirrhosis; or post-hepatic causes, such as biliary obstruction preventing bile flow.[51] These disruptions in bilirubin metabolism lead to hyperbilirubinemia, with patterns helping differentiate the underlying pathology.[51] Clinically, total bilirubin levels exceeding 2.5 mg/dL typically manifest as jaundice, with yellowing of the skin, sclera, and mucous membranes due to pigment deposition.[50] Unconjugated bilirubin, in particular, is neurotoxic when unbound fractions cross the blood-brain barrier, potentially causing kernicterus—a form of bilirubin encephalopathy—in severe cases, especially in neonates.[52] Fractionation into direct and indirect components provides further diagnostic insight, as detailed in subsequent analyses.[49]Direct and indirect bilirubin
Direct bilirubin, also known as conjugated bilirubin, is the water-soluble form produced when unconjugated bilirubin undergoes glucuronidation in hepatocytes via the enzyme UDP-glucuronosyltransferase 1A1 (UGT1A1), forming bilirubin diglucuronide for excretion into bile.[49] Indirect bilirubin, or unconjugated bilirubin, is the lipid-soluble, non-polar form generated from heme catabolism in the reticuloendothelial system and transported in plasma bound to albumin, rendering it insoluble in water and unable to be filtered by the kidneys.[49] Measurement of direct and indirect bilirubin relies on the diazo reaction (Van den Bergh method), where bilirubin reacts with diazotized sulfanilic acid to form colored azobilirubin detectable spectrophotometrically; direct bilirubin reacts rapidly without accelerators, while indirect bilirubin requires an accelerator such as caffeine, methanol, or ethanol to solubilize it for reaction, with indirect levels calculated as total bilirubin minus direct bilirubin.[49] This fractionation provides insight into the stage of bilirubin metabolism affected, complementing total bilirubin assessment by identifying whether elevations stem from overproduction, conjugation defects, or excretion issues.[49] In pre-hepatic conditions, such as hemolytic anemias or Gilbert syndrome—a benign genetic disorder caused by reduced UGT1A1 activity due to promoter mutations—indirect bilirubin predominates, reflecting increased heme breakdown or impaired conjugation without liver parenchymal damage.[49] Conversely, hepatic or post-hepatic disorders elevate direct bilirubin; for instance, Dubin-Johnson syndrome results from mutations in the multidrug resistance-associated protein 2 (MRP2) gene, impairing canalicular excretion of conjugated bilirubin, while biliary obstruction (e.g., from gallstones or tumors) causes reflux of conjugated bilirubin into blood due to blocked bile flow.[53][51] Clinically, when direct bilirubin exceeds 50% of total bilirubin, it strongly suggests cholestasis or obstructive pathology, prompting further evaluation with imaging or biopsy to differentiate intrahepatic from extrahepatic causes.[54] Isolated indirect hyperbilirubinemia, particularly in Gilbert syndrome, often requires no treatment but genetic confirmation via UGT1A1 testing to rule out more serious hepatic issues.[49] These distinctions aid in etiologic diagnosis, guiding management from supportive care in hemolytic states to interventions like ursodeoxycholic acid or surgery in obstructive cases.[51]Tests of synthetic function
Albumin
Albumin is the most abundant protein in human plasma, constituting approximately 50% of total serum protein, and serves as a key indicator of the liver's synthetic function in clinical assessments. It is a small globular protein with a molecular weight of 66.5 kilodaltons (kDa), composed of 585 amino acids arranged in three homologous domains, which enable its versatile binding capabilities.[55] Albumin maintains about 80% of the plasma oncotic pressure, preventing fluid extravasation into tissues and supporting vascular volume stability, though earlier estimates attributed around 40% to its direct contribution in certain contexts.[55] Its plasma half-life is approximately 19-20 days, reflecting a slow turnover that makes it a marker of chronic rather than acute hepatic processes.[56] Synthesis of albumin occurs exclusively in the hepatocytes of the liver, primarily on polysomes in the rough endoplasmic reticulum, with healthy adults producing 10-15 grams per day to sustain steady-state plasma levels of 35-50 mg/mL.[57] This production accounts for nearly 25% of the liver's total protein synthesis capacity and is tightly regulated by colloid osmotic pressure (or osmolarity) in the interstitial fluid surrounding hepatocytes, which stimulates synthesis when plasma volume decreases.[58] Additionally, inflammatory cytokines such as tumor necrosis factor-alpha (TNF-α), interleukin-1 (IL-1), and interleukin-6 (IL-6) suppress albumin gene transcription and synthesis, linking hepatic output to systemic inflammatory states.[59] Serum albumin levels are typically measured through dye-binding assays, such as the bromocresol green (BCG) method, where the dye binds selectively to albumin, causing a color change quantifiable by spectrophotometry, or by immunoturbidimetric assays that use antibodies to form measurable aggregates.[60] The BCG method is widely used for its simplicity and cost-effectiveness but can overestimate levels in patients with inflammation or low albumin concentrations due to non-specific binding, while immunoturbidimetry offers higher specificity.[61] In liver function testing, hypoalbuminemia (serum levels below 3.5 g/dL) primarily signals impaired chronic hepatic synthetic capacity, as seen in advanced chronic liver diseases like cirrhosis, where hepatocyte damage progressively reduces production.[3] It also occurs in malnutrition due to insufficient amino acid substrates for synthesis and in nephrotic syndrome from urinary protein loss, though these non-hepatic causes must be differentiated clinically.[62] Due to its prolonged half-life, albumin is not a reliable acute marker for sudden liver injury, such as viral hepatitis or toxin exposure, where levels remain stable initially despite rapid hepatocellular necrosis.[3] Beyond oncotic regulation, albumin functions as a carrier protein, binding and transporting endogenous substances like bilirubin, unconjugated fatty acids, hormones, and ions, as well as exogenous drugs such as warfarin, phenytoin, and many antibiotics, thereby influencing their pharmacokinetics and bioavailability.[57] As a negative acute phase protein, its synthesis decreases during inflammation or infection in response to cytokine-mediated suppression, exacerbating hypoalbuminemia in critically ill patients and correlating with worse outcomes independent of nutritional status.[59]Prothrombin time (PT) and international normalized ratio (INR)
Prothrombin time (PT) is a blood test that evaluates the extrinsic and common pathways of coagulation by measuring the time required for plasma to clot after the addition of tissue factor (thromboplastin) and calcium.[63] It primarily assesses the activity of clotting factors VII, X, V, II (prothrombin), and fibrinogen, all of which are synthesized by the liver except for factor VIII.[63] The international normalized ratio (INR) standardizes PT results across laboratories to account for variations in thromboplastin reagents, originally developed for monitoring warfarin therapy but widely applied in liver disease assessment.[64] The liver is the primary site of synthesis for most coagulation factors involved in PT, including the vitamin K-dependent factors II, VII, IX, and X, which require gamma-carboxylation in the liver for functional activity.[65] These factors exhibit varying half-lives that influence the timing of coagulopathy in liver dysfunction: factor VII has the shortest at 3-6 hours, factor IX approximately 24 hours, factor X 40-48 hours, and factor II the longest at 60-72 hours.[66][67] This differential turnover means early liver impairment often prolongs PT due to rapid depletion of factor VII, while advanced disease affects longer-lived factors.[68] PT is measured by adding a thromboplastin reagent to citrated plasma and recording the time to fibrin clot formation, compared against a control value; normal PT ranges from 11-13.5 seconds.[69] INR is calculated using the formula INR = (PT patient / PT mean normal)^ISI, where ISI (international sensitivity index) reflects the reagent's responsiveness, typically 0.9-1.7 for sensitive thromboplastins.[70] In liver function evaluation, PT and INR are not routine components of basic panels but are critical for assessing synthetic capacity, particularly in chronic or acute liver failure. Clinically, prolonged PT and elevated INR indicate impaired hepatic synthesis of clotting factors and are hallmarks of end-stage liver disease, vitamin K deficiency, or disseminated intravascular coagulation (DIC).[69] They play a key role in prognostic scoring, such as the Model for End-Stage Liver Disease (MELD) score, which incorporates INR to predict mortality and prioritize liver transplantation.[71] An INR greater than 1.5 often signifies significant synthetic failure in liver disease, correlating with increased bleeding risk and poor outcomes.[72] In cases of vitamin K deficiency contributing to prolongation, administration of vitamin K can reverse the abnormality within 24-48 hours if liver parenchymal function is preserved, highlighting the test's utility in distinguishing nutritional from intrinsic hepatic defects.[73] However, in advanced cirrhosis, response to vitamin K is limited due to synthetic impairment, underscoring PT/INR as markers of irreversible dysfunction.[74]Specialized and adjunct tests
Ceruloplasmin
Ceruloplasmin is a 132 kDa alpha-2 globulin glycoprotein synthesized primarily in the liver, functioning as a ferroxidase enzyme that facilitates iron oxidation and carries approximately 95% of plasma copper in its holo form, which binds up to six copper atoms per molecule.[75][76] It is produced in hepatocytes and secreted into the bloodstream as an acute-phase reactant, with its synthesis upregulated during inflammation via interleukin-6 signaling; the holoenzyme has a plasma half-life of about 5 days, while the apoenzyme (lacking copper) degrades more rapidly with a half-life of 5-6 hours.[75][77] Ceruloplasmin levels are measured through blood tests using immunologic methods such as nephelometry or immunoturbidimetry to quantify protein concentration, or enzymatic assays that assess its oxidase activity by monitoring the oxidation of substrates like o-dianisidine.[75][78] In clinical practice, ceruloplasmin serves as a specialized marker for disorders of copper metabolism, notably Wilson's disease, an autosomal recessive condition caused by mutations in the ATP7B gene that impair copper incorporation into the protein, resulting in low serum levels typically below 20 mg/dL (normal range 20-40 mg/dL) in about 90% of affected individuals.[79][80] Conversely, levels may be elevated as an acute-phase response in conditions such as inflammation, infection, trauma, or during pregnancy due to estrogen influence.[75][81] Its diagnostic utility lies in evaluating suspected Wilson's disease as part of a targeted panel that includes 24-hour urinary copper excretion (often >100 μg/24 h) and slit-lamp examination for Kayser-Fleischer rings, though it is not a routine component of standard liver function tests due to its specificity for copper-related pathologies and potential overlap with other conditions like malnutrition or heterozygote carriers.[82][83][84]Alpha-fetoprotein (AFP)
Alpha-fetoprotein (AFP) is a 70 kDa glycoprotein that serves as the primary fetal analog to albumin, functioning as a major plasma protein during early development. It is predominantly produced by the yolk sac and fetal liver, with synthesis beginning around the fourth week of gestation and peaking in the fetal circulation before declining postnatally.[85][86] In the fetus, AFP plays a transient role in nutrient transport, binding substances such as fatty acids, bilirubin, and heavy metals to support growth and development, while its expression is largely suppressed in healthy adults, resulting in serum levels typically below 10 ng/mL.[87][88] AFP concentrations are measured via immunoassays, most commonly enzyme-linked immunosorbent assay (ELISA), which quantifies levels in serum or plasma with high sensitivity; serial monitoring is employed in high-risk populations, such as those with cirrhosis or chronic hepatitis B virus infection, to detect trends suggestive of malignancy.[89][90] Clinically, AFP serves as a key tumor marker, with levels exceeding 200 ng/mL strongly indicating hepatocellular carcinoma (HCC) in at-risk individuals, though elevations also occur in non-malignant conditions including acute or chronic hepatitis (affecting up to 25% of cases), pregnancy, and germ cell tumors such as yolk sac tumors.[87][91][92] The American Association for the Study of Liver Diseases (AASLD) guidelines endorse AFP in combination with abdominal ultrasound for HCC surveillance every six months in high-risk patients, using a cutoff of 20 ng/mL to prompt further evaluation; however, its standalone sensitivity for early-stage HCC is limited (around 60%), leading to debates on its routine utility and a trend toward favoring imaging-alone approaches in some contexts.[93][94]Lactate dehydrogenase (LDH)
Lactate dehydrogenase (LDH) is a ubiquitous enzyme that exists as a tetramer composed of two polypeptide subunits, designated H (heart-type) and M (muscle-type), which combine to form five distinct isoenzymes: LDH1 (H₄), LDH2 (H₃M), LDH3 (H₂M₂), LDH4 (HM₃), and LDH5 (M₄). The LDH5 isoenzyme, predominant in hepatic tissue, is particularly enriched in liver cells due to their reliance on glycolytic metabolism.[95][96] Physiologically, LDH catalyzes the reversible interconversion of lactate and pyruvate in the final step of anaerobic glycolysis, oxidizing NADH to NAD⁺ to sustain ATP production under low-oxygen conditions. In the liver, this process supports gluconeogenesis by converting lactate to pyruvate during the Cori cycle. Upon cellular injury or necrosis, LDH is released from damaged hepatocytes into the circulation, serving as a marker of tissue breakdown.[95][97] LDH activity is quantified through spectrophotometric assays that measure the rate of NADH oxidation (or production in the reverse direction) by monitoring absorbance changes at 340 nm, reflecting the enzyme's catalytic efficiency. Total LDH levels provide a broad indicator of cell damage, while isoenzyme fractionation via agarose gel electrophoresis or other chromatographic methods distinguishes tissue-specific origins by identifying predominant isoforms.[95][98] In liver function assessment, elevated total LDH occurs in ischemic or necrotic conditions such as shock liver (also known as ischemic hepatitis), where profound hypoxia leads to rapid hepatocyte death, as well as in hepatic malignancies and confounding extrahepatic processes like hemolysis. Isoenzyme analysis enhances specificity; a predominant rise in LDH5 (often exceeding LDH4 levels) indicates hepatic involvement, distinguishing liver injury from other sources.[95][99][100] As an adjunct test, LDH is valuable in evaluating severe acute liver injury, where disproportionately high levels relative to aminotransferases suggest ischemic etiology and correlate with poor prognosis when incorporated into scores like MELD-LDH. In hepatocellular carcinoma (HCC), serial LDH measurements track tumor burden, reflecting glycolytic activity and hypoxia-driven progression, with elevated levels predicting worse outcomes in patients undergoing therapies like sorafenib.[101][102][103]Interpretation and clinical patterns
Reference ranges and variability
Reference ranges for liver function tests (LFTs) are established using data from healthy reference populations and provide benchmarks for interpreting results, though they can vary by laboratory due to methodological differences.[3] These ranges typically encompass the central 95% of values from individuals without liver disease, adjusted for factors such as age and sex where applicable.[3] Common LFTs include enzymes like alanine aminotransferase (ALT) and aspartate aminotransferase (AST), markers of biliary function like alkaline phosphatase (ALP) and gamma-glutamyl transferase (GGT), bilirubin for heme metabolism, albumin for synthetic capacity, and prothrombin time (PT) expressed as international normalized ratio (INR) for coagulation.[104] The following table summarizes representative reference ranges for key LFTs in adults, based on established clinical guidelines; values may differ slightly by lab and population.| Test | Typical Adult Reference Range | Units |
|---|---|---|
| Alanine aminotransferase (ALT) | 7–56 | U/L |
| Aspartate aminotransferase (AST) | 10–40 | U/L |
| Alkaline phosphatase (ALP) | 44–147 | U/L |
| Gamma-glutamyl transferase (GGT) | 9–48 (men); 6–42 (women) | U/L |
| Total bilirubin | 0.1–1.2 | mg/dL |
| Albumin | 3.5–5.0 | g/dL |
| International normalized ratio (INR) | 0.8–1.2 | - |
Diagnostic patterns of abnormality
Diagnostic patterns of abnormality in liver function tests (LFTs) are categorized based on the predominant elevations in specific markers, facilitating differential diagnosis of underlying liver pathology. These patterns include hepatocellular, cholestatic, mixed or infiltrative, and synthetic failure, each reflecting distinct mechanisms of liver injury or dysfunction. The R-value, calculated as (ALT/ULN) / (ALP/ULN) where ULN denotes the upper limit of normal, aids in classification: an R-value greater than 5 indicates a hepatocellular pattern, less than 2 a cholestatic pattern, and 2 to 5 a mixed pattern.[23] The hepatocellular pattern is characterized by marked elevations in aminotransferases, typically with ALT and AST exceeding 5 times the ULN, accompanied by only mild increases in alkaline phosphatase (ALP) and bilirubin. This pattern suggests primary injury to hepatocytes and is commonly seen in conditions such as viral hepatitis, ischemic hepatitis, or toxin-induced damage, including acetaminophen overdose. For instance, in acute viral hepatitis, ALT levels can rise dramatically, often surpassing 1000 IU/L, while ALP remains less than twice the ULN.[10][46] In contrast, the cholestatic pattern features prominent elevations in ALP and gamma-glutamyl transferase (GGT), generally more than 3 times the ULN, with modest rises in aminotransferases and bilirubin. This indicates obstruction or impairment of bile flow and is exemplified by extrahepatic bile duct obstruction, such as from gallstones or malignancy, or intrahepatic cholestasis in primary biliary cholangitis (PBC). Isolated GGT elevation, often without significant changes in other LFTs, is a hallmark of chronic alcohol consumption, reflecting induction of hepatic enzymes rather than overt injury.[10][46] The mixed or infiltrative pattern involves concurrent elevations across multiple LFT categories, with aminotransferases, ALP, and bilirubin all increased, often without a dominant marker. This nonspecific profile arises in systemic conditions like sepsis, autoimmune hepatitis, or infiltrative diseases such as malignancy or amyloidosis, where widespread hepatic involvement complicates localization.[10][46] Synthetic failure pattern manifests as derangements in markers of hepatic protein production and coagulation, including hypoalbuminemia and prolonged prothrombin time (PT) or elevated international normalized ratio (INR), typically in the setting of chronic liver disease. This indicates advanced fibrosis or cirrhosis, where hepatocyte synthetic capacity is compromised; for example, in decompensated cirrhosis, albumin levels below 3.5 g/dL and INR greater than 1.5 contribute to staging via the Child-Pugh score, which integrates these with bilirubin and clinical features to assess prognosis.[117][46] Additional diagnostic clues within these patterns include the De Ritis ratio (AST/ALT), which exceeds 2 in alcoholic liver disease due to preferential mitochondrial AST release, contrasting with ratios below 1 in viral hepatitis. Elevated alpha-fetoprotein (AFP) in the context of rising aminotransferases may signal hepatocellular carcinoma (HCC), particularly in patients with chronic hepatitis B or cirrhosis.[46]| Pattern | Key Elevations | Typical Conditions | Diagnostic Utility |
|---|---|---|---|
| Hepatocellular | ALT/AST >5x ULN; mild ALP/bilirubin | Viral hepatitis, toxins | Points to hepatocyte necrosis; R-value >5 |
| Cholestatic | ALP/GGT >3x ULN; modest ALT/bilirubin | Bile duct obstruction, PBC | Indicates biliary impairment; isolated GGT in alcohol use |
| Mixed/Infiltrative | All markers elevated | Sepsis, malignancy | Suggests multifocal or systemic involvement; R-value 2-5 |
| Synthetic Failure | Low albumin; high INR/PT | Cirrhosis | Assesses prognostic staging (e.g., Child-Pugh) |