Acute liver failure
Acute liver failure (ALF), also known as fulminant hepatic failure, is a rare and rapidly progressive condition characterized by the sudden onset of severe liver dysfunction in individuals without preexisting chronic liver disease, typically developing within days to weeks and leading to coagulopathy (international normalized ratio [INR] ≥1.5) and hepatic encephalopathy.[1] This life-threatening syndrome results from massive hepatocyte necrosis or apoptosis, impairing the liver's essential functions such as detoxification, protein synthesis, and metabolic regulation, often necessitating urgent hospitalization and potentially liver transplantation.[2] The incidence of ALF is rare, estimated at 1-2 cases per million people annually in developed countries such as the United States (approximately 2,000 cases per year), with regional variations in etiology; for instance, drug-induced cases account for about 46% of ALF in North America, while viral hepatitis predominates in developing regions.[1][3] The most common cause of ALF in Western countries is acetaminophen (paracetamol) toxicity, responsible for nearly half of cases, often due to intentional or accidental overdose, while viral infections such as hepatitis A, B, or E are leading etiologies in Asia and Africa, comprising up to 50-90% of instances in those areas.[1] Other notable triggers include idiosyncratic drug reactions (e.g., to antibiotics, nonsteroidal anti-inflammatory drugs, or herbal supplements), toxins like Amanita phalloides mushrooms, autoimmune hepatitis, Wilson's disease, ischemic hepatitis from hypotension or vascular occlusion, and occasionally indeterminate causes in 5-70% of cases depending on the region.[2][3] Pathophysiologically, these insults provoke an inflammatory cascade, mitochondrial dysfunction, and oxidative stress, culminating in multiorgan failure if untreated.[1] Clinically, ALF presents with nonspecific early symptoms such as fatigue, nausea, vomiting, anorexia, and right upper quadrant pain, progressing to hallmark features including jaundice (yellowing of skin and eyes), ascites (abdominal swelling), altered mental status from encephalopathy, coagulopathy with easy bruising or bleeding, and signs of systemic involvement like hypotension, tachycardia, or renal impairment.[2][3] Diagnosis relies on clinical criteria—absence of chronic liver disease, elevated INR, and encephalopathy—supported by laboratory tests showing markedly increased aminotransferases (AST/ALT >1000 IU/L), hyperbilirubinemia, and imaging to rule out other causes, with liver biopsy occasionally needed for etiology confirmation.[1] Complications are severe, encompassing cerebral edema (a leading cause of death), infections, gastrointestinal bleeding, acute kidney injury, and metabolic derangements like hypoglycemia or lactic acidosis.[2] Management of ALF is primarily supportive in an intensive care setting, focusing on stabilizing hemodynamics with intravenous fluids and vasopressors, correcting coagulopathy, preventing infections with prophylactic antibiotics, and addressing encephalopathy through measures like lactulose or mannitol for cerebral edema.[3] Specific therapies include N-acetylcysteine as the antidote for acetaminophen toxicity, antiviral agents for hepatitis, or corticosteroids for autoimmune cases, but liver transplantation remains the definitive treatment for those with poor prognostic indicators such as high INR, advanced encephalopathy, or unfavorable etiology, offering 1-year survival rates exceeding 80-90%.[1] Overall prognosis varies by cause and timeliness of intervention; acetaminophen-induced ALF has up to 75% spontaneous recovery, whereas indeterminate or drug-induced non-acetaminophen cases carry higher mortality without transplant.[1][3]Definition and Terminology
Definition
Acute liver failure (ALF) is defined as a rapid deterioration of liver function leading to coagulopathy and hepatic encephalopathy in individuals without preexisting liver disease. According to the American Association for the Study of Liver Diseases (AASLD), the condition is characterized by an acute hepatic insult resulting in impaired synthetic function, evidenced by an international normalized ratio (INR) of ≥1.5 (with or without liver transplantation) and any degree of encephalopathy, occurring within 26 weeks of illness onset.[4] This definition emphasizes failure of hepatic synthetic function—particularly protein synthesis leading to coagulopathy—over isolated elevations in transaminases, which may occur in other forms of acute liver injury without progression to failure.[4] Preexisting chronic liver disease must be excluded, though exceptions include cases of Wilson's disease, vertically acquired hepatitis B virus infection, or autoimmune hepatitis if diagnosed within the 26-week window.[4] ALF is subclassified based on the interval from onset of jaundice to development of encephalopathy, which helps predict etiology and prognosis. Hyperacute liver failure occurs when encephalopathy develops within 7 days of jaundice, often linked to severe viral or toxic insults with rapid progression.[4] Acute liver failure spans 7 to 21 days, while subacute liver failure extends from more than 21 days up to 26 weeks, typically featuring a more insidious course with higher risks of cerebral edema.[4] These temporal subtypes, adopted internationally, refine the broad ALF framework by highlighting variations in clinical tempo.[1] The conceptual framework for ALF has evolved since the 1970s, when Trey and Davidson introduced the term "fulminant hepatic failure" to describe encephalopathy developing within 8 weeks of symptom onset in patients without prior liver disease, focusing on rapid, potentially reversible hepatic injury. Subsequent refinements in the 1980s and 1990s, including elements from the King's College criteria—originally developed in 1989 for prognostic assessment—shifted emphasis toward quantifiable markers like INR thresholds and encephalopathy grading to standardize diagnosis across etiologies.[4] Modern AASLD guidelines, updated in 2011, favor "acute liver failure" over historical synonyms to encompass a wider temporal spectrum up to 26 weeks while maintaining core criteria of acute onset and synthetic dysfunction.[4]Terminology
The term "fulminant hepatic failure" was first coined in 1970 by Trey and Davidson to describe a rapid and potentially reversible condition characterized by the onset of hepatic encephalopathy within eight weeks of the initial symptoms of liver injury in patients without preexisting liver disease.[5] This nomenclature, derived from the Latin fulminare meaning "to strike with lightning," emphasized the sudden and explosive nature of the liver dysfunction. Earlier historical references often used "massive hepatic necrosis" to denote the extensive pathological destruction of hepatocytes leading to acute liver decompensation, a descriptor rooted in autopsy findings of widespread parenchymal collapse.[6] In the 1990s, evolving understanding of the condition's variable timelines prompted a shift toward "acute liver failure" (ALF) as the preferred term, reflecting a broader spectrum of disease progression rather than implying uniform rapidity. This change, formalized in consensus recommendations by the International Association for the Study of the Liver (IASL) in 1999, aimed to standardize nomenclature and avoid the pejorative connotations of "fulminant," which could evoke undue pessimism about prognosis.[7] The IASL subcommittee proposed classifications such as hyperacute (encephalopathy within 10 days of jaundice), fulminant (10-30 days), and subacute (5-24 weeks) to better capture temporal variations.[7] Related terms include "acute liver injury" (ALI), which describes severe hepatocellular damage with coagulopathy but without encephalopathy, serving as a milder precursor to ALF.[8] "Hyperacute liver failure" specifically denotes cases where encephalopathy develops within seven days of jaundice onset, often associated with higher risks of cerebral complications.[8] International variations persist, with European and North American guidelines favoring ALF as an umbrella term encompassing hyperacute and acute subtypes, while some Asian contexts, such as those outlined by the Indian National Association for the Study of the Liver (INASL), retain "subacute hepatic failure" for presentations with encephalopathy 5-12 weeks after jaundice to account for regionally prevalent etiologies like viral hepatitis.[9] These differences highlight the influence of 1990s consensus efforts in promoting harmonization while accommodating local clinical patterns.[7]Epidemiology
Incidence and Prevalence
Acute liver failure (ALF) is a rare condition worldwide, with an incidence estimated at fewer than 10 cases per million population annually in developed countries. In the United States, approximately 2,000 to 4,000 cases are reported each year, representing a small fraction of overall liver disease burden but carrying high morbidity and mortality. Globally, the incidence is higher in low- and middle-income countries, where infectious etiologies predominate and contribute to rates exceeding those in high-income settings.[10][11][1] Regional variations are notable, with elevated prevalence in Asia due to endemic viral hepatitis; for instance, hepatitis E virus accounts for up to 50% of ALF cases in parts of India, leading to an overall higher burden compared to Western countries. In contrast, developed regions like Western Europe and North America report lower rates, primarily driven by non-infectious causes such as drug toxicity. Overall incidence remains stable in high-income countries.[1] Demographically, ALF exhibits a bimodal age distribution, with younger adults (median age around 37 years) more commonly affected by toxin-induced cases like acetaminophen overdose, while older individuals (median age over 50 years) are prone to ischemic or vascular causes. There is a slight overall female predominance (approximately 70-75%), particularly pronounced in acetaminophen-related ALF (75% female), though gender distribution varies by etiology. The impact of the COVID-19 pandemic on ALF incidence appears minimal directly but includes indirect effects from disrupted healthcare access and delayed presentations.[11][10]Risk Factors
Acute liver failure (ALF) susceptibility varies by demographic and genetic factors. Extremes of age represent key non-modifiable risks: in pediatric populations, metabolic disorders such as hereditary tyrosinemia or mitochondrial hepatopathies predispose children to ALF, often presenting in early childhood.[12] In adults, individuals aged 30 to 50 years face heightened vulnerability, particularly from toxic exposures, while those over 40 years exhibit elevated risks linked to age-related declines in hepatic reserve and comorbidities.[1] Genetic predispositions, including polymorphisms in drug-metabolizing enzymes like CYP2E1, increase susceptibility to idiosyncratic liver injury from certain xenobiotics by altering detoxification pathways.[13] Modifiable lifestyle factors significantly amplify ALF risk. Chronic alcohol consumption synergistically exacerbates hepatotoxicity from other insults by inducing enzymes such as CYP2E1 and depleting glutathione stores, thereby heightening vulnerability in heavy drinkers.[1] Obesity serves as a backdrop, promoting underlying non-alcoholic fatty liver disease that may precipitate acute decompensation under stress, with class III obesity independently associated with poorer outcomes in ALF cases.[14] Polypharmacy, especially in the elderly, elevates risk of idiosyncratic drug-induced liver injury through cumulative drug interactions and metabolic overload.[1] Environmental exposures further predispose susceptible individuals. In low-resource settings, limited regulation facilitates access to hepatotoxins, correlating with higher ALF incidence in developing regions compared to high-income countries.[15] Occupational hazards, such as prolonged contact with industrial solvents like tetrachloroethylene or carbon tetrachloride, can trigger acute hepatic injury leading to ALF in exposed workers.[16] Comorbid conditions and recent trends compound these risks. Immunosuppression, as seen in HIV or post-transplant states, heightens susceptibility to hepatic decompensation by impairing immune surveillance and promoting reactivation of latent hepatitides.[1] Pregnancy alters hepatic metabolism and increases risk for conditions like acute fatty liver of pregnancy, particularly in the third trimester.[15]Causes
Infectious Causes
Infectious causes of acute liver failure (ALF) primarily involve viral pathogens, particularly hepatotropic viruses, which account for a significant proportion of cases in developing regions, though they are less common in Western countries where drug-induced etiologies predominate.[1] Among these, acute viral hepatitis due to hepatitis A virus (HAV), hepatitis B virus (HBV), and hepatitis E virus (HEV) represents the most frequent infectious triggers, often leading to massive hepatocyte necrosis and rapid progression to ALF in susceptible individuals.[17] These infections are typically self-limited in the majority of cases but can result in fulminant hepatic failure in 1-2% of acute episodes, with higher risks in certain populations such as pregnant women or those with underlying liver disease.[17] Hepatitis A virus, transmitted via the fecal-oral route through contaminated food or water, is a common cause of acute hepatitis worldwide, particularly in areas with poor sanitation.[1] In acute HAV infection, progression to ALF occurs in approximately 0.1-0.5% of cases; however, HAV accounts for up to 27% of ALF cases in countries without routine vaccination programs, often presenting with severe jaundice and coagulopathy.[17] Hepatitis B virus, acquired through bloodborne, sexual, or perinatal exposure, leads to ALF in less than 1% of acute infections but is notably severe in cases of reactivation among chronic carriers or superinfection, especially under immunosuppression.[17] Hepatitis E virus, also spread fecal-orally and often linked to contaminated water sources, is a leading infectious etiology of ALF in endemic areas, with up to 22% of infected pregnant women developing severe liver injury due to its propensity for rapid viral replication.[17] Beyond hepatotropic viruses, non-hepatotropic viruses such as herpes simplex virus (HSV), Epstein-Barr virus (EBV), and cytomegalovirus (CMV) can precipitate ALF, predominantly in immunocompromised hosts through direct hepatocyte invasion or systemic dissemination.[1] HSV infection, transmitted via direct contact, results in ALF in up to 74% of reported cases, characterized by a fulminant course with high mortality if untreated.[17] EBV, spread through saliva, and CMV, via bodily fluids, rarely cause ALF in immunocompetent individuals but have been associated with post-2020 reports of rare links to emerging infections like COVID-19, where severe hepatic involvement mimics viral hepatitis.[1] Bacterial and parasitic infections contribute rarely to ALF, typically in the context of sepsis or zoonotic exposure in tropical or rural settings. Leptospirosis, caused by Leptospira species and transmitted through contact with infected animal urine-contaminated water or soil, can manifest as Weil's disease with acute liver injury progressing to failure, accompanied by jaundice and renal dysfunction.[18] Q fever, due to Coxiella burnetii inhalation from contaminated livestock aerosols, occasionally leads to fulminant hepatic failure with granulomatous hepatitis, though it is underrecognized outside endemic areas.[19] Fungal infections, such as those from Candida or Aspergillus, are exceptional causes, almost exclusively in severely immunocompromised patients with disseminated disease.[1] Geographic variations underscore the influence of endemicity and socioeconomic factors on infectious ALF etiologies; for instance, HEV accounts for up to 50% of ALF cases in India, reflecting high prevalence in South Asia due to waterborne transmission.[1] In East Asia, HBV remains a dominant cause, contributing to 40% of ALF in Japan and a substantial portion in China, driven by chronic carriage rates exceeding 5-10% in the population.[1] These patterns align with broader epidemiological trends, where viral infections comprise over 40% of ALF in developing countries compared to under 12% in the West.[1] Diagnosis of infectious ALF relies on targeted serologic testing and molecular assays to identify the pathogen promptly, as early detection is crucial for differentiating from other causes. Serologies such as anti-HAV IgM, HBsAg with anti-HBc IgM for HBV, and anti-HEV IgM guide initial evaluation, while polymerase chain reaction (PCR) for viral DNA/RNA (e.g., HBV DNA, HEV RNA, HSV DNA) confirms active replication in fulminant cases.[17] For non-viral infections, clinical suspicion based on exposure history prompts serologies or cultures, such as anti-leptospiral antibodies or C. burnetii PCR, often supplemented by liver biopsy showing characteristic inclusions or granulomas.[1]Toxic and Drug-Induced Causes
Toxic and drug-induced causes represent a significant proportion of acute liver failure (ALF) cases, particularly in developed countries, where they account for up to 50% of etiologies due to widespread access to pharmaceuticals and environmental exposures.[20] These insults primarily involve direct hepatotoxic effects or hypersensitivity reactions, leading to rapid hepatocellular necrosis and impaired liver function.[21] Among them, acetaminophen overdose stands out as the leading cause in Western nations. Acetaminophen (paracetamol) is the most common precipitant of ALF in the United States and Europe, responsible for approximately 46% of cases.[20] This toxicity arises from dose-dependent metabolism via cytochrome P450 enzymes, producing the reactive metabolite N-acetyl-p-benzoquinone imine (NAPQI), which depletes hepatic glutathione stores and causes oxidative stress, mitochondrial dysfunction, and centrilobular necrosis.[22] Overdoses often occur in suicidal intent, accounting for about 50% of cases, while therapeutic misadventures—such as repeated supratherapeutic dosing during fasting or chronic illness—comprise the remainder, with co-factors like alcohol exacerbating NAPQI formation by inducing CYP2E1.[23] Without prompt intervention, this progresses to fulminant hepatic failure in 20-30% of severe cases.[24] Beyond acetaminophen, various pharmaceuticals induce ALF through idiosyncratic mechanisms. Anticonvulsants such as phenytoin can trigger immune-mediated hypersensitivity, leading to hepatocellular injury in susceptible individuals via T-cell activation and cytokine release.[25] Antibiotics like isoniazid, used in tuberculosis treatment, pose risks through reactive metabolites that form adducts with cellular proteins, causing necrosis or cholestasis, particularly in slow acetylators.[21] Herbal supplements contribute increasingly, with kava linked to severe hepatotoxicity from pyrone constituents inhibiting gamma-aminobutyric acid uptake and promoting apoptosis, and green tea extract catechins inducing oxidative damage in high doses.[26] Industrial and environmental toxins also drive ALF via intrinsic hepatotoxicity. Ingestion of Amanita phalloides mushrooms releases amatoxins, which non-covalently bind and inhibit RNA polymerase II, halting mRNA transcription and protein synthesis in hepatocytes, resulting in massive necrosis within 48-72 hours.[27] Solvents like carbon tetrachloride (CCl4) cause acute injury through cytochrome P450-mediated bioactivation to trichloromethyl radicals, generating lipid peroxidation and centrilobular damage that can culminate in multi-organ failure.[28] Drug-induced ALF follows two primary patterns: intrinsic toxicity, which is predictable and dose-related (e.g., acetaminophen or CCl4, where severity correlates with exposure level), and idiosyncratic reactions, which are unpredictable, host-dependent, and often immune-mediated (e.g., phenytoin or isoniazid, occurring in <1:10,000 exposures without dose threshold).[29] Co-factors such as genetic polymorphisms in detoxification enzymes, fasting, or concurrent alcohol use amplify both types by altering metabolism.[30] Recent trends indicate a rise in idiosyncratic ALF from complementary medicines, with herbal and dietary supplements implicated in 20% of U.S. cases by 2016, up from 7% pre-2007, reflecting a 10-15% increase post-2015 due to unregulated products.[20] Polypharmacy heightens this risk by promoting metabolic interactions.[31]Pathophysiology
Mechanisms of Hepatocellular Injury
Hepatocellular injury in acute liver failure (ALF) primarily involves programmed and non-programmed forms of cell death, driven by diverse triggers such as toxins, viruses, ischemia, and immune activation, leading to rapid hepatocyte loss and liver dysfunction. Key pathways include apoptosis, a caspase-dependent process resulting in orderly cell dismantling without inflammation, and necroptosis, a regulated necrosis involving receptor-interacting protein kinases (RIPK1 and RIPK3) that promotes inflammatory damage. These mechanisms are activated by death receptor signaling or intrinsic mitochondrial perturbations, amplifying injury across the hepatic lobule.[32][33] In toxin-induced ALF, such as acetaminophen overdose, the reactive metabolite N-acetyl-p-benzoquinone imine (NAPQI) forms through cytochrome P450 metabolism and covalently binds to cellular proteins, triggering both apoptosis via caspase activation and necroptosis through RIPK1/3-mediated pathways when antioxidant defenses fail. Viral etiologies, like hepatitis B virus (HBV), contribute via the HBV X protein, which sensitizes hepatocytes to apoptosis by modulating death receptor pathways and enhancing tumor necrosis factor (TNF) sensitivity, thereby lowering the threshold for cell death during acute flares. These processes often intersect, with necroptosis dominating when apoptosis is inhibited, as seen in experimental models where RIPK3 knockout attenuates liver injury.[34][35][33] Oxidative stress represents a central initiator of hepatocellular injury, stemming from mitochondrial dysfunction that generates excessive reactive oxygen species (ROS), overwhelming cellular antioxidants and promoting lipid peroxidation, protein damage, and DNA fragmentation. In acetaminophen toxicity, glutathione (GSH) depletion exacerbates this by failing to neutralize NAPQI, leading to mitochondrial permeability transition pore opening and release of pro-apoptotic factors like cytochrome c. Sustained ROS production not only drives direct necrosis but also amplifies death receptor signaling, creating a vicious cycle of injury.[36][34] Immune-mediated mechanisms further propagate hepatocyte death through innate immunity activation and cytokine storms, where pattern recognition receptors like Toll-like receptors (TLRs) on Kupffer cells and hepatocytes detect damage-associated molecular patterns (DAMPs) from dying cells, triggering proinflammatory responses. This leads to elevated cytokines such as TNF-α and interleukin-6 (IL-6), which bind death receptors on hepatocytes to induce caspase-dependent apoptosis or, under certain conditions, necroptosis via RIPK pathways, particularly in viral hepatitis or idiosyncratic drug reactions. In ALF, this systemic inflammation intensifies local injury, with TLR4 signaling shown to be pivotal in experimental models.[37][38] Ischemic mechanisms, often secondary to hypoperfusion in shock states, cause hepatocellular injury through hypoxia-induced ATP depletion, impairing ion pumps and leading to intracellular calcium overload, mitochondrial collapse, and activation of necrotic pathways. This hypoxic stress preferentially affects oxygen-poor regions, exacerbating ROS burst upon reperfusion and transitioning to necroptosis if ATP levels drop below critical thresholds.[32]00433-9/pdf) Liver zonation influences injury patterns, with centrilobular (zone 3) hepatocytes—near the central vein—being most vulnerable to hypoxic or toxic insults due to lower oxygen and GSH levels, resulting in confluent necrosis as seen in acetaminophen or ischemic ALF. In contrast, periportal (zone 1) injury predominates in immune-mediated or certain viral cases, where higher oxygen availability shifts damage toward regenerative zones, though severe ALF often progresses to panlobular involvement regardless of etiology. For instance, acetaminophen toxicity exemplifies centrilobular predominance, as elaborated in discussions of toxic causes.[39][40]Systemic Complications
In acute liver failure (ALF), the initial hepatocellular injury triggers a systemic inflammatory cascade characterized by the activation of Kupffer cells and release of proinflammatory cytokines such as tumor necrosis factor-alpha (TNF-α), interleukin-1β (IL-1β), IL-6, IL-8, and CXCL10, which amplify inflammation and promote secondary hepatocyte necrosis.[1] This response often evolves into systemic inflammatory response syndrome (SIRS), involving widespread immune activation and elevated circulating mediators that induce vasodilation, increased vascular permeability, and capillary leak, leading to tissue edema and effective hypovolemia.[1][41] Hemodynamic instability in ALF arises from splanchnic vasodilation driven by portal hypertension and reduced systemic vascular resistance (SVR), resulting in low mean arterial pressure, high cardiac output, and a hyperdynamic circulation that mimics sepsis.[1] This instability is exacerbated by endothelial dysfunction, particularly overproduction of nitric oxide (NO) by inducible NO synthase in vascular smooth muscle and endothelial cells, which contributes to profound hypotension and impaired organ perfusion.[41] The propagation of these processes leads to multiorgan failure, beginning with the liver and extending to other systems through inflammatory and hemodynamic derangements. Renal involvement manifests as hepatorenal syndrome type 1, a form of acute kidney injury affecting 40-80% of patients due to splanchnic vasodilation and renal vasoconstriction, often compounded by hypovolemia or acute tubular necrosis.[1][41] Pulmonary complications include acute respiratory distress syndrome (ARDS), though less common, arising from capillary leak and inflammatory injury to the alveolar-capillary membrane, leading to hypoxemia.[1] Cerebral effects stem from hyperammonemia, which crosses the blood-brain barrier and induces astrocyte swelling, contributing to intracranial hypertension independent of direct inflammatory effects on the brain.[1][41] Vicious cycles perpetuate these complications, as infections—occurring in 60-80% of cases, often with Gram-negative bacteria—further intensify the inflammatory response and SIRS, worsening hemodynamic instability and multiorgan dysfunction.[41] The gut-liver axis plays a central role, with impaired intestinal barrier function promoting bacterial translocation from the gut lumen into the portal circulation, releasing pathogen-associated molecular patterns that activate hepatic and systemic immunity, thereby amplifying cytokine production and sustaining the inflammatory loop.[1][42]Signs and Symptoms
Acute liver failure (ALF) initially presents with nonspecific symptoms such as fatigue, nausea, vomiting, anorexia, and right upper quadrant abdominal pain, often resembling viral hepatitis or other acute illnesses. These early signs typically develop within days to weeks and progress rapidly to more severe manifestations, including jaundice (yellowing of the skin and eyes), ascites (abdominal swelling due to fluid accumulation), and signs of systemic involvement like hypotension, tachycardia, or renal impairment. Hallmark complications include hepatic encephalopathy and coagulopathy, detailed below.[1][2]Hepatic Encephalopathy
Hepatic encephalopathy (HE) represents a critical neurological complication in acute liver failure (ALF), characterized by rapidly progressive brain dysfunction due to liver insufficiency. It is a defining feature of ALF, typically requiring at least grade II severity for diagnosis alongside coagulopathy. In ALF, HE arises from the accumulation of neurotoxins and systemic inflammation, leading to altered mental status that can culminate in coma and death if untreated.[1][43] The severity of HE is commonly graded using the West Haven criteria, which categorize the condition into four stages based on clinical manifestations:- Grade I: Mild confusion, shortened attention span, euphoria or anxiety, and subtle personality changes, often noticeable only to close observers.
- Grade II: Lethargy, disorientation to time, inappropriate behavior, and minimal impairment in daily functioning.
- Grade III: Somnolence or semi-stupor, gross disorientation to place, responsive only to vigorous stimuli, with potential for asterixis and hyperreflexia.
- Grade IV: Coma, with no response to painful stimuli, frequently associated with cerebral edema leading to herniation.[44][45][46]
Coagulopathy and Bleeding
Coagulopathy is a hallmark of acute liver failure (ALF), characterized by impaired hemostasis due to the liver's central role in producing coagulation proteins, and serves as a diagnostic criterion alongside hepatic encephalopathy. In ALF, the rapid decline in hepatocyte function leads to reduced synthesis of procoagulant factors, including II, V, VII, IX, and X, resulting in prolonged prothrombin time (PT) and international normalized ratio (INR), often exceeding 1.5 as a definitional threshold.[48] Additionally, fibrinogen levels may drop due to decreased hepatic production, though qualitative defects like dysfibrinogenemia—marked by abnormal polymerization—affect up to 86% of patients, further compromising clot formation.[48] Thrombocytopenia, with median counts around 132,000/μL, arises primarily from impaired platelet production secondary to reduced thrombopoietin synthesis by the damaged liver, compounded by thrombin-mediated consumption in some cases.[48][49] Clinically, overt bleeding is uncommon in ALF despite severe laboratory derangements, occurring in approximately 10.6% of patients within the first week, predominantly as spontaneous mucosal or gastrointestinal hemorrhage; esophageal varices are rare given the absence of chronic portal hypertension.[48] Prolonged PT/INR remains the most reliable marker of synthetic liver dysfunction, correlating with disease severity rather than bleeding risk directly.[50] The hemostatic imbalance presents a paradox: while procoagulant deficiencies suggest a bleeding diathesis, a rebalanced state often emerges from concurrent reductions in anticoagulants like protein C (levels as low as 5%) and antithrombin, alongside elevations in factor VIII and von Willebrand factor, maintaining near-normal thrombin generation in many patients.[48][51] However, in severe ALF with systemic inflammation, disseminated intravascular coagulation (DIC) can develop, featuring low fibrinogen, elevated D-dimers, and microvascular thrombosis that exacerbates multi-organ failure.[52] Monitoring hemostasis in ALF relies on serial INR and fibrinogen assessments to gauge liver function and transfusion needs, though INR alone overestimates bleeding propensity.[48] Thromboelastography (TEG) provides a dynamic, whole-blood evaluation, revealing normal or even hypercoagulable profiles in up to 63% of patients despite INR >3, with prolonged reaction time (R-time) better predicting actual hemorrhage.[51] A key complication is intracranial bleeding, which is rare but heightened in coagulopathic patients with encephalopathy requiring invasive intracranial pressure monitoring, where procedural hemorrhage rates reach 10.3%.[48]Diagnosis
Clinical Assessment
The clinical assessment of acute liver failure begins with a thorough history taking to establish the timeline and potential precipitants of the condition. Patients or their relatives should be questioned regarding the onset of jaundice and the development of hepatic encephalopathy, as the interval between these events is critical for classification and prognosis. Exposure history is essential, including recent use of medications, herbal supplements, recreational drugs, or travel to regions endemic for viral hepatitis, while carefully excluding evidence of underlying chronic liver disease such as prior episodes of decompensation or known cirrhosis.[8][1] Physical examination focuses on identifying key manifestations of liver dysfunction while ruling out chronic features. Jaundice, typically evident as scleral icterus and skin yellowing, is a hallmark finding, often accompanied by asterixis—a flapping tremor elicited by wrist extension—indicating encephalopathy. Ascites is usually minimal or absent in acute cases but may appear in subacute presentations; vital signs should be monitored closely for signs of hemodynamic instability, such as hypotension or tachycardia suggestive of shock. The absence of stigmata like spider angiomata or palmar erythema helps differentiate acute from chronic liver disease.[8][53][1] Classification by timing is determined during assessment, with hyperacute liver failure defined by encephalopathy onset within 7 days of jaundice, acute liver failure by onset between 8 and 28 days, often linked to better cerebral outcomes but higher risk of sudden deterioration in hyperacute cases, and subacute cases involving a 5- to 12-week interval, which carry a poorer prognosis without intervention.[8][1] Red flags warranting urgent attention include rapid progression of encephalopathy, hypoglycemia (which signals severe metabolic derangement), and signs of sepsis such as fever or altered mentation, as these predict complications like multiorgan failure.[8][1] Initial stabilization prioritizes the ABCs—ensuring airway patency (with intubation if encephalopathy progresses to grade >3 or for airway protection in advanced stages), adequate breathing, and circulation—followed by securing large-bore intravenous access for fluid resuscitation and monitoring, all prior to further diagnostic pursuits. This structured evaluation integrates history and examination to guide immediate management and confirm alignment with the definition of acute liver failure, characterized by coagulopathy and encephalopathy in a previously healthy liver.[8][53]Laboratory and Imaging Studies
Laboratory studies are essential for confirming acute liver failure (ALF) by demonstrating severe hepatocellular injury and synthetic dysfunction in patients without preexisting liver disease. Key tests include measurement of serum aminotransferases, where aspartate aminotransferase (AST) and alanine aminotransferase (ALT) levels typically exceed 1000 IU/L, reflecting extensive hepatocyte necrosis, though these elevations alone are not diagnostic as they can occur in other acute liver injuries.[1] Total and direct bilirubin levels rise due to impaired hepatic conjugation and excretion, often reaching several milligrams per deciliter, providing evidence of cholestasis or hepatocyte dysfunction.[54] The international normalized ratio (INR) is prolonged (≥1.5), serving as a critical marker of impaired synthetic function and a defining criterion for ALF, with values >6.5 indicating high risk for poor outcomes.[1] Serum ammonia levels are frequently elevated, particularly in association with hepatic encephalopathy, though arterial measurements are preferred for accuracy and do not exclude other causes of altered mental status.[54] Renal function tests, such as serum creatinine, help identify hepatorenal syndrome or concurrent acute kidney injury, which complicates up to 50% of ALF cases.[1] Etiology-specific laboratory investigations guide the identification of underlying causes. Viral hepatitis serologies, including IgM antibodies for hepatitis A and E, hepatitis B surface antigen, and hepatitis C viral load, are routinely performed to detect infectious triggers.[54] Acetaminophen (paracetamol) serum levels and protein adducts are measured urgently in suspected overdose cases, remaining detectable for up to 7 days post-ingestion.[54] For suspected Wilson's disease, serum ceruloplasmin levels below 20 mg/dL, along with serum free copper >25 µg/dL, support the diagnosis.[54] Autoimmune markers such as antinuclear antibodies (ANA) and anti-smooth muscle antibodies (ASMA) are assessed in cases suggestive of autoimmune hepatitis.[1] Additional supportive tests include blood cultures to exclude sepsis as a precipitant or complication, and a toxicology screen to identify other potential hepatotoxins, particularly in patients with risk factors like intravenous drug use.[54] Imaging studies complement laboratory findings by evaluating hepatic architecture and excluding alternative diagnoses. Abdominal ultrasound with Doppler is the initial modality of choice to assess vascular patency, such as in Budd-Chiari syndrome, and to rule out features of chronic liver disease like cirrhosis or portal hypertension.[55] Contrast-enhanced computed tomography (CT) or magnetic resonance imaging (MRI) provides detailed assessment of parenchymal homogeneity, detects masses or abscesses, and evaluates for intra-abdominal complications, though non-contrast options may be preferred in renal impairment.[54] Normal imaging does not preclude ALF, as parenchymal changes may be subtle in early or ischemic forms.[1] Interpretation of these studies requires caution to avoid pitfalls. For instance, AST and ALT may normalize or remain only mildly elevated in late-stage ALF or ischemic hepatitis due to exhaustion of hepatocyte reserves, potentially leading to underdiagnosis if not correlated with clinical context and INR.[1] INR prolongation can also stem from extrahepatic factors like disseminated intravascular coagulation, necessitating comprehensive evaluation.[54] Coagulopathy markers such as INR are integral here but detailed further in discussions of bleeding risks.[1]Treatment
Supportive Care
Supportive care forms the cornerstone of management for acute liver failure (ALF), aiming to maintain hemodynamic stability, prevent secondary organ dysfunction, and mitigate complications such as hepatic encephalopathy and coagulopathy while awaiting potential recovery or definitive therapy. This approach emphasizes intensive care unit (ICU) admission for all patients with evidence of encephalopathy or severe coagulopathy, where multidisciplinary teams provide vigilant oversight to address the rapid clinical deterioration characteristic of ALF. Advances in supportive strategies have contributed to improved survival rates, exceeding 60% in recent decades through optimized critical care practices.[56] Patients with ALF and hepatic encephalopathy of grade II or higher require immediate transfer to an ICU for continuous monitoring of vital signs, neurological status, and fluid balance, with evaluations performed at least every 2 hours to detect early signs of cerebral edema or deterioration.[41] Endotracheal intubation and mechanical ventilation are mandatory for grade III or IV encephalopathy to secure the airway and facilitate controlled sedation if needed, while avoiding unnecessary sedatives in non-intubated patients to prevent exacerbation of encephalopathy.[57] Intracranial pressure (ICP) monitoring via an epidural or intraventricular catheter is recommended selectively in high-risk cases, such as those with severe encephalopathy at transplant centers, targeting a cerebral perfusion pressure of 60-80 mmHg.[57] Strict fluid management is essential to prevent overload, which can worsen cerebral edema, with central venous pressure guiding resuscitation.[41] Hemodynamic instability is common in ALF due to vasodilation and relative hypovolemia; initial resuscitation with isotonic crystalloids like normal saline restores volume without excessive sodium load.[57] For refractory hypotension, norepinephrine is the preferred vasopressor to maintain a mean arterial pressure (MAP) of at least 65 mmHg, particularly in patients with renal impairment, while avoiding over-resuscitation that could precipitate pulmonary edema or ICP elevation.[41] Vasopressin may be added as an adjunct in cases unresponsive to norepinephrine, but its use requires caution in encephalopathic patients due to potential vasoconstrictive effects on cerebral blood flow.[57] Renal dysfunction affects up to 50% of ALF patients and demands proactive protection; nephrotoxic agents such as nonsteroidal anti-inflammatory drugs and aminoglycosides must be strictly avoided, alongside maintenance of adequate renal perfusion through hemodynamic optimization.[41] Continuous renal replacement therapy (CRRT) is the modality of choice for acute kidney injury, offering advantages in hemodynamic stability, ammonia clearance, and correction of acidosis or electrolyte imbalances over intermittent hemodialysis.[57] Early initiation of CRRT is advised for hyperammonemia exceeding 150-200 µmol/L or oliguric renal failure to support multiorgan recovery.[41] Nutritional support is critical in ALF to counter catabolism and hypoglycemia, with early enteral nutrition preferred via nasogastric tube once gastrointestinal motility is confirmed, targeting 20-30 kcal/kg/day and 1.2-1.5 g/kg/day of protein without undue restriction.[57] Branched-chain amino acid-enriched formulas are recommended to reduce hepatic encephalopathy risk and improve nitrogen balance, particularly in encephalopathic patients, as they bypass impaired liver metabolism.[58] Frequent blood glucose monitoring is required, with intravenous dextrose infusions to prevent hypoglycemia, a frequent issue due to depleted glycogen stores.[41] If enteral feeding is contraindicated, parenteral nutrition should be instituted promptly, with lipids limited to avoid hypertriglyceridemia.[57] Additional general measures include gastrointestinal bleeding prophylaxis with proton pump inhibitors (PPIs) or H2-receptor antagonists to prevent stress ulcers in intubated patients, balanced against the risk of ventilator-associated pneumonia.[41] Vigilant infection surveillance through daily cultures and prompt empirical antibiotics for suspected sepsis is vital, given the high infection burden in ALF.[57] Coagulopathy requires regular assessment of international normalized ratio (INR) and fibrinogen levels, with fresh frozen plasma reserved for active bleeding rather than prophylactic use.[57]Specific Interventions
Specific interventions for acute liver failure (ALF) target the underlying etiology to mitigate progression and improve outcomes, with therapies tailored to causes such as drug toxicity, viral infections, and metabolic disorders. N-acetylcysteine (NAC) is the cornerstone treatment for acetaminophen-induced ALF, administered intravenously using a standardized protocol that includes a loading dose of 150 mg/kg over 1 hour, followed by 50 mg/kg over 4 hours and 100 mg/kg over 16 hours, which effectively replenishes glutathione stores and prevents hepatotoxicity when initiated early. This regimen has been shown to nearly completely avert liver injury if given within 8-16 hours of overdose, as per American Association for the Study of Liver Diseases (AASLD) guidelines.[59][60] Emerging evidence supports NAC's use in non-acetaminophen ALF, where it improves transplant-free survival, particularly in early-stage disease without advanced hepatic encephalopathy. A 2009 randomized controlled trial demonstrated that intravenous NAC increased transplant-free survival from 30% to 52% in early-stage non-acetaminophen ALF, with benefits attributed to its antioxidant and anti-inflammatory effects. More recent meta-analyses from the 2020s, including a 2021 systematic review, indicate that NAC reduces overall mortality by approximately 20-30% in these patients, with subgroup analyses showing enhanced efficacy in viral and indeterminate etiologies, though results are less consistent in advanced coma grades.[61][62][63] For viral etiologies, antiviral therapies are employed to suppress replication and halt liver injury. In hepatitis B virus (HBV)-associated ALF, nucleoside analogs such as entecavir are recommended as first-line oral therapy, inhibiting HBV DNA polymerase and improving short-term survival rates compared to untreated cases, according to AASLD and European Association for the Study of the Liver (EASL) guidelines. Entecavir's high potency and low resistance profile make it preferable, with studies showing reduced viral load and stabilization of liver function within weeks of initiation. Supportive antiviral management is also used for hepatitis A (HAV) and E (HEV), though these often resolve spontaneously without specific agents.[64][65] Liver transplantation remains the definitive intervention for irreversible ALF, with indications guided by prognostic criteria to identify patients unlikely to recover spontaneously. The King's College Criteria (KCC) for acetaminophen-induced ALF include arterial pH <7.3 after fluid resuscitation or international normalized ratio (INR) >6.5, alongside factors like creatinine >3.4 mg/dL and encephalopathy grade ≥3, predicting poor prognosis with >95% accuracy and prompting urgent listing. For non-acetaminophen causes, KCC incorporate etiology-specific variables such as age >40 or <10 years, jaundice >7 days before encephalopathy, and INR >3.5. The Model for End-Stage Liver Disease (MELD) score, calculated from serum bilirubin, INR, and creatinine, is used for organ allocation prioritization in the United States, with scores ≥30 indicating high urgency and exception status often granted for ALF to expedite transplantation. Post-transplant 1-year survival rates for ALF recipients range from 70-90%, influenced by etiology and pre-transplant stability, with living-donor options achieving up to 85% survival in select centers.[66][67][68] Extracorporeal liver support systems serve as adjunctive measures for specific etiologies, particularly as bridges to transplantation. The Molecular Adsorbent Recirculating System (MARS), an albumin dialysis-based device, removes protein-bound toxins and improves hemodynamics in ALF, with randomized trials showing potential for enhanced native liver recovery or successful bridging, especially in drug-induced or viral ALF. For Wilson's disease presenting as ALF, plasma exchange (plasmapheresis) rapidly depletes copper and removes toxic metabolites, with reported transplant-free survival around 40% in case series when performed as three consecutive sessions using fresh frozen plasma replacement, per EASL guidelines.[69][70][71] Experimental therapies, including stem cell approaches and bioartificial liver devices, are under investigation to support regeneration or provide temporary hepatic function. Mesenchymal stem cell (MSC) infusions, derived from bone marrow or umbilical cord, have shown promise in phase I/II trials for ALF, reducing inflammation and promoting hepatocyte repair, with a 2024 meta-analysis reporting 20-40% improvement in 6-month survival rates in acute-on-chronic liver failure subsets. As of November 2025, multiple phase II trials are evaluating allogeneic MSCs, such as NCT02857010 (completed with ongoing analysis for safety and efficacy in bridging to recovery). Bioartificial liver devices, like the Extracorporeal Liver Assist Device (ELAD) using porcine hepatocytes, are in phase II testing, demonstrating temporary stabilization of encephalopathy and bilirubin levels in ALF patients, though larger randomized trials are needed to confirm survival benefits beyond bridging.[72][73][74]Prognosis
Prognostic Models
Prognostic models for acute liver failure (ALF) are validated scoring systems designed to predict mortality risk and guide clinical decisions, particularly regarding liver transplantation eligibility. These tools integrate clinical, laboratory, and etiological factors to identify patients with poor outcomes despite supportive care. The most established models, such as the King's College Criteria (KCC), were developed to address the rapid progression of ALF and the need for timely intervention.[75][76] The King's College Criteria, introduced in 1989, remain the cornerstone for prognostication in ALF and are etiology-specific. For acetaminophen-induced ALF, poor prognosis is indicated by an arterial pH less than 7.3 after resuscitation or a combination of international normalized ratio (INR) greater than 6.5, serum creatinine greater than 3.4 mg/dL (300 µmol/L), and grade III or IV hepatic encephalopathy. For non-acetaminophen-induced ALF, criteria include an INR greater than 6.5 or an INR greater than 3.5 alongside at least three unfavorable factors, such as age over 40 years, non-A/non-B hepatitis or idiosyncratic drug reaction as etiology, duration of jaundice before encephalopathy exceeding 7 days, or serum bilirubin exceeding 17.5 mg/dL (300 µmol/L). These thresholds help stratify patients for transplantation, with meta-analyses showing sensitivity of 68% to 95% and specificity around 82% for predicting poor outcomes, though performance varies by etiology.[75][76][77] The Model for End-Stage Liver Disease (MELD) score, originally developed for chronic liver disease allocation, has been adapted for ALF prognostication and prioritizes patients on transplant waitlists. It is calculated as MELD = 3.8 × log₁₀(serum bilirubin in mg/dL) + 11.2 × log₁₀(INR) + 9.6 × log₁₀(serum creatinine in mg/dL) + 6.4, with higher scores (e.g., >30) indicating increased short-term mortality risk in ALF. Studies confirm its utility in predicting hospital mortality, particularly for non-acetaminophen cases, though it may underestimate risk in hyperacute presentations.[78][79][80] Other models, such as the Chronic Liver Failure Consortium-Acute-on-Chronic Liver Failure (CLIF-C ACLF) score, incorporate multi-organ failure assessments beyond hepatic parameters, including respiratory, cardiovascular, and renal function, to predict outcomes in severe ALF cases. The Sequential Organ Failure Assessment (SOFA) score evaluates ICU-level severity by scoring dysfunction in six organ systems, providing dynamic prognostication during hospitalization. Both tools enhance risk stratification in complex ALF scenarios but are less specific to isolated acute presentations.[81][82][83] Despite their value, these models have limitations, including reduced accuracy in hyperacute ALF where rapid deterioration outpaces static scoring, and variability in sensitivity across etiologies. Recent updates from the 2020s incorporate arterial lactate levels (e.g., >3.5 mmol/L) to improve predictive power, as elevated lactate reflects metabolic derangement and correlates with mortality independently of traditional criteria. Ongoing research aims to refine these systems for better precision in transplantation decisions.[84][85][86]Outcomes and Survival
Acute liver failure (ALF) carries a historically high mortality rate, but advancements in critical care and liver transplantation have significantly improved outcomes. In the 1970s, survival was approximately 20%, whereas contemporary rates exceed 60% due to enhanced medical management and access to emergency liver transplantation (ELT).[87] Observational data from U.S. centers between 1998 and 2013 indicate overall 21-day survival rose from 67.1% to 75.3%, with transplant-free survival increasing from 45.1% to 56.2%.[88] These improvements occurred alongside reduced use of invasive interventions, such as mechanical ventilation (from 65.7% to 56.1%) and vasopressors (from 34.9% to 27.8%), suggesting optimized supportive care contributes to better prognosis.[88] Survival in ALF varies markedly by etiology, with acetaminophen (APAP) toxicity often showing higher rates of spontaneous recovery but also elevated waitlist mortality among transplant candidates. In a national cohort of 1,691 ALF patients listed for transplantation from 2002 to 2019, overall waitlist mortality was 17.3%, highest in APAP cases at 22.8% compared to 13.0% for hepatitis B virus (HBV), 10.2% for autoimmune hepatitis (AIH), and 15.2% for drug-induced liver injury (DILI).[89] Spontaneous survival without transplantation was 10.0% overall, reaching 19.3% in APAP but only 1.0% in HBV.[89] Transplantation rates were 72.7% across etiologies, with APAP patients less likely to receive grafts (57.9%) than those with HBV (86.0%) or AIH (88.3%).[89] Prognostic models like the King's College Criteria help identify candidates for ELT, predicting poor outcomes in cases such as pH <7.3 or INR >6.5 in APAP-induced ALF.[87] Post-transplantation survival is generally excellent and not significantly influenced by ALF etiology. In the 1998–2013 cohort, 21-day post-transplant survival improved from 88.3% to 96.3%, with 22.3% of all patients receiving transplants.[88] Long-term data from 2,759 transplanted ALF patients (2002–2020) show 1-year survival at 83–95% and 5-year survival at 76–90%, depending on cause; for instance, Wilson disease yielded 90% 5-year survival, while APAP achieved 76%.[90] In-hospital post-transplant mortality was 9.0% in the national cohort, with no etiology-based differences in overall or graft survival.[89] However, APAP patients faced a higher risk of brain death post-transplant (5.3% vs. 1.1% in AIH).[89] Factors adversely affecting long-term survival include Black race (hazard ratio 1.47), diabetes (1.81), and hepatic encephalopathy (1.27).[90]| Etiology | Waitlist Mortality (%) | Transplantation Rate (%) | Spontaneous Survival (%) | 5-Year Post-Transplant Survival (%) |
|---|---|---|---|---|
| Acetaminophen (APAP) | 22.8 | 57.9 | 19.3 | 76 |
| Hepatitis B Virus (HBV) | 13.0 | 86.0 | 1.0 | Not specified |
| Autoimmune Hepatitis (AIH) | 10.2 | 88.3 | 1.6 | Not specified (1-year: 83) |
| Drug-Induced Liver Injury (DILI) | 15.2 | 80.0 | 4.8 | Not specified |
| Wilson Disease | Not specified | 93 (by day 5) | Not specified | 90 |