Jaundice

The most common signs of jaundice in adults are a yellowish discoloration of the white area of the eye (sclera) and skin, with scleral icterus presence indicating a serum bilirubin of at least 3 mg/dl. Because bilirubin is a skin irritant, jaundice is commonly associated with severe itchiness. Eye conjunctiva has a particularly high affinity for bilirubin deposition due to high elastin content. Slight increases in serum bilirubin can, therefore, be detected early on by observing the yellowing of sclerae. Traditionally referred to as scleral icterus, this term is actually a misnomer, because bilirubin deposition technically occurs in the conjunctival membranes overlying the avascular sclera. Thus, the proper term for the yellowing of "white of the eyes" is conjunctival icterus. In individuals with darker skin tones, jaundice may be less readily apparent on the skin and is more reliably observed in areas such as the sclera, palms, soles, and oral mucosa. Educational resources have increasingly highlighted this variation to support accurate clinical assessment across diverse populations. A rare sign of jaundice in childhood is the appearance of yellowish or greenish teeth. In developing children, hyperbilirubinemia can lead to yellow or green tooth discoloration as bilirubin deposits during tooth calcification. While this may occur in children with hyperbilirubinemia, tooth discoloration due to hyperbilirubinemia is not observed in individuals with adult-onset liver disease. Disorders associated with a rise in serum levels of conjugated bilirubin during early development can also cause dental hypoplasia. == Causes ==

Jaundice is a sign indicating the presence of underlying diseases involving abnormal bilirubin metabolism, liver dysfunction, or biliary-tract obstruction. In general, jaundice is present when blood levels of bilirubin exceed 3 mg/dl. Jaundice is classified into three categories, depending on which part of the physiological mechanism the pathology affects. The three categories are: Prehepatic causes Prehepatic jaundice is most commonly caused by a pathological increased rate of red blood cell (erythrocyte) hemolysis. The increased breakdown of erythrocytes → increased unconjugated serum bilirubin → increased deposition of unconjugated bilirubin into mucosal tissue. These diseases may cause jaundice due to increased erythrocyte hemolysis: • Sickle-cell anemia • Spherocytosis • Thalassemia Hepatic causes stain Hepatic jaundice is caused by abnormal liver metabolism of bilirubin. The major causes of hepatic jaundice are significant damage to hepatocytes due to infectious, drug/medication-induced, autoimmune etiology, or less commonly, due to inheritable genetic diseases. The following is a partial list of hepatic causes to jaundice: • Acute hepatitis • Chronic hepatitis • Hepatotoxicity • Cirrhosis • Drug-induced hepatitis • Alcoholic liver disease • Gilbert's syndrome (found in about 5% of the population, results in induced mild jaundice) • Crigler–Najjar syndrome, type I • Crigler–Najjar syndrome, type II • Leptospirosis Posthepatic causes (Obstructive jaundice) Posthepatic jaundice (obstructive jaundice) is caused by a blockage of bile ducts that transport bile containing conjugated bilirubin out of the liver for excretion. This is a list of conditions that can cause posthepatic jaundice: • Choledocholithiasis (common bile duct gallstones). It is the most common cause of obstructive jaundice. • Pancreatic cancer of the pancreatic head • Biliary tract strictures • Biliary atresia • Primary biliary cholangitis • Cholestasis of pregnancy • Acute Pancreatitis • Chronic Pancreatitis • Pancreatic pseudocysts • Mirizzi's syndrome • Parasites ("liver flukes" of the Opisthorchiidae and Fasciolidae) == Pathophysiology ==

Jaundice is typically caused by an underlying pathological process that occurs at some point along the normal physiological pathway of heme metabolism. A deeper understanding of the anatomical flow of normal heme metabolism is essential to appreciate the importance of prehepatic, hepatic, and posthepatic categories. Thus, an anatomical approach to heme metabolism precedes a discussion of the pathophysiology of jaundice. Normal heme metabolism Prehepatic metabolism When red blood cells complete their lifespan of about 120 days, or if they are damaged, they rupture as they pass through the reticuloendothelial system, and cell contents including hemoglobin are released into circulation. Macrophages phagocytose free hemoglobin and split it into heme and globin. Two reactions then take place with the heme molecule. The first oxidation reaction is catalyzed by the microsomal enzyme heme oxygenase and results in biliverdin (green color pigment), iron, and carbon monoxide. The next step is the reduction of biliverdin to a yellow color tetrapyrrole pigment called bilirubin by cytosolic enzyme biliverdin reductase. This bilirubin is "unconjugated", "free", or "indirect" bilirubin. Around 4 mg of bilirubin per kg of blood are produced each day. The majority of this bilirubin comes from the breakdown of heme from expired red blood cells in the process just described. Roughly 20% comes from other heme sources, however, including ineffective erythropoiesis, and the breakdown of other heme-containing proteins, such as muscle myoglobin and cytochromes. A small portion of urobilinogen is reabsorbed back into the gastrointestinal cells. Most reabsorbed urobilinogen undergoes hepatobiliary recirculation. A smaller portion of reabsorbed urobilinogen is filtered into the kidneys. In the urine, urobilinogen is converted to urobilin, which gives urine its characteristic yellow color. Hepatic pathophysiology Hepatic jaundice (hepatocellular jaundice) is due to significant disruption of liver function, leading to hepatic cell death and necrosis and impaired bilirubin transport across hepatocytes. Bilirubin transport across hepatocytes may be impaired at any point between hepatocellular uptake of unconjugated bilirubin and hepatocellular transport of conjugated bilirubin into the gallbladder. In addition, subsequent cellular edema due to inflammation causes mechanical obstruction of the intrahepatic biliary tract. Most commonly, interferences in all three major steps of bilirubin metabolism—uptake, conjugation, and excretion—usually occur in hepatocellular jaundice. Thus, an abnormal rise in both unconjugated and conjugated bilirubin (formerly called cholemia) will be present. Because excretion (the rate-limiting step) is usually impaired to the greatest extent, conjugated hyperbilirubinemia predominates. The unconjugated bilirubin still enters the liver cells and becomes conjugated in the usual way. This conjugated bilirubin is then returned to the blood, probably by rupture of the congested bile canaliculi and direct emptying of the bile into the lymph exiting the liver. Thus, most of the bilirubin in the plasma becomes the conjugated type rather than the unconjugated type, and this conjugated bilirubin, which did not go to the intestine to become urobilinogen, gives the urine a dark color. There are other causes of hepatic jaundice that are not due to significant liver dysfunction and are associated solely with the conjugation of bilirubin. One example is Gilbert syndrome where affected individuals have normal liver function but have genetic variants in their UDP-glucuronyl transferase enzyme, causing the enzyme to be less efficient in conjugating unconjugated bilirubin. == Diagnosis ==

Most people presenting with jaundice have various predictable patterns of liver panel abnormalities, though significant variation does exist. The typical liver panel includes blood levels of enzymes found primarily from the liver, such as the aminotransferases (ALT, AST), and alkaline phosphatase (ALP); bilirubin (which causes the jaundice); and protein levels, specifically, total protein and albumin. Other primary lab tests for liver function include gamma glutamyl transpeptidase (GGT) and prothrombin time (PT). No single test can differentiate between various classifications of jaundice. A combination of liver function tests and other physical examination findings is essential to arrive at a diagnosis. Laboratory tests Some bone and heart disorders can lead to an increase in ALP and the aminotransferases, so the first step in differentiating these from liver problems is to compare the levels of GGT, which are only elevated in liver-specific conditions. The second step is distinguishing from biliary (cholestatic) or liver causes of jaundice and altered laboratory results. ALP and GGT levels typically rise with one pattern while aspartate aminotransferase (AST) and alanine aminotransferase (ALT) rise in a separate pattern. If the ALP (10–45 IU/L) and GGT (18–85 IU/L) levels rise proportionately as high as the AST (12–38 IU/L) and ALT (10–45 IU/L) levels, this indicates a cholestatic problem. If the AST and ALT rise is significantly higher than the ALP and GGT rise, though, this indicates a liver problem. Finally, distinguishing between liver causes of jaundice, comparing levels of AST and ALT can prove useful. AST levels typically are higher than ALT. This remains the case in most liver disorders except for hepatitis (viral or hepatotoxic). Alcoholic liver damage may have fairly normal ALT levels, with AST 10 times higher than ALT. If ALT is higher than AST, however, this is indicative of hepatitis. Levels of ALT and AST are not well correlated to the extent of liver damage, although rapid drops in these levels from very high levels can indicate severe necrosis. Low levels of albumin tend to indicate a chronic condition, while the level is normal in hepatitis and cholestasis. Laboratory results for liver panels are frequently compared by the magnitude of their differences, not the pure number, as well as by their ratios. The AST:ALT ratio can be a good indicator of whether the disorder is alcoholic liver damage (above 10), some other form of liver damage (above 1), or hepatitis (less than 1). Bilirubin levels greater than 10 times normal could indicate neoplastic or intrahepatic cholestasis. Levels lower than this tend to indicate hepatocellular causes. AST levels greater than 15 times normal tend to indicate acute hepatocellular damage. Less than this tend to indicate obstructive causes. ALP levels greater than 5 times normal tend to indicate obstruction, while levels greater than 10 times normal can indicate drug (toxin) induced cholestatic hepatitis or cytomegalovirus infection. Both of these conditions can also have ALT and AST greater than 20 times normal. GGT levels greater than 10 times normal typically indicate cholestasis. Levels 5–10 times tend to indicate viral hepatitis. Levels less than 5 times normal tend to indicate drug toxicity. Acute hepatitis typically has ALT and AST levels rising 20–30 times normal (above 1000) and may remain significantly elevated for several weeks. Acetaminophen toxicity can result in ALT and AST levels greater than 50 times than normal. Laboratory findings depend on the cause of jaundice: • Urine: conjugated bilirubin present, urobilinogen > 2 units but variable (except in children) • Plasma proteins show characteristic changes. • Plasma albumin level is low, but plasma globulins are raised due to an increased formation of antibodies. Unconjugated bilirubin is hydrophobic, so cannot be excreted in urine. Thus, the finding of increased urobilinogen in the urine without the presence of bilirubin in the urine (due to its unconjugated state) suggests hemolytic jaundice as the underlying disease process. Urobilinogen will be greater than 2 units, as hemolytic anemia causes increased heme metabolism; one exception being the case of infants, where the gut flora has not developed). Conversely, conjugated bilirubin is hydrophilic and thus can be detected as present in the urine—bilirubinuria—in contrast to unconjugated bilirubin, which is absent in the urine. Imaging Medical imaging such as ultrasound, CT scan with contrast, and HIDA scan are useful for detecting bile-duct blockage. Ultrasound and CT scans are routinely first line as they provide rapid results while remaining noninvasive and cost-effective. Overconsumption of foods containing carotene such as carrots, leafy vegetables, squash, peaches, and oranges are the most common cause. However, it can also be associated with medical conditions such as diabetes, hypothyroidism, and anorexia nervosa. On physical exam, the two are differentiable where jaundice typically has diffuse yellowing of the skin throughout the body and carotenemia displays concentration of yellowing in specific areas of the body. • Certain medications are associated with yellowing of the skin as a side effect: quinacrine, sunitinib, and sorafenib. • Yellow discoloration of the skin can also rarely occur with hypercupremia, whether from Wilson's disease or from another metabolic derangement. Similarly, a golden-ish ring at the edges of the irises can occur (Kayser-Fleischer ring). == Treatment ==

Treatment of jaundice varies depending on the underlying cause. ==Epidemiology==

Jaundice in adults is rare. Under the five year DISCOVERY programme in the UK, annual incidence of jaundice was 0.74 per 1000 individuals over age 45, although this rate may be slightly inflated due to the main goal of the programme collecting and analyzing cancer data in the population. Jaundice is commonly associated with severity of disease with an incidence of up to 40% of patients requiring intensive care in ICU experiencing jaundice. Mean serum total bilirubin levels in adults were found to be higher in men (0.72 ± 0.004 mg/dl) than women (0.52 ± 0.003 mg/dl). Higher bilirubin levels in adults are found also in non-Hispanic white population (0.63 ± 0.004 mg/dl) and Mexican American population (0.61 ± 0.005 mg/dl) while lower in non-Hispanic black population (0.55 ± 0.005 mg/dl). Bilirubin levels are higher in active smokers. == Special populations ==

Neonatal jaundice Symptoms Jaundice in infants presents with yellowed skin and icteral sclerae. Neonatal jaundice spreads in a cephalocaudal pattern, affecting the face and neck before spreading down to the trunk and lower extremities in more severe cases. Other symptoms may include drowsiness, poor feeding, and in severe cases, unconjugated bilirubin can cross the blood-brain barrier and cause permanent neurological damage (kernicterus). Causes The most common cause of jaundice in infants is normal physiologic jaundice. Pathologic causes of neonatal jaundice include: • Formula jaundice • Hereditary spherocytosis • Glucose-6-phosphate dehydrogenase deficiency • Pyruvate kinase deficiency • ABO/Rh blood type autoantibodies • Alpha 1-antitrypsin deficiency • Alagille syndrome (genetic defect resulting in hypoplastic intrahepatic bile ducts) • Progressive familial intrahepatic cholestasis • Pyknocytosis (due to vitamin deficiency) • Cretinism (congenital hypothyroidism) • Sepsis or other infectious causes Pathophysiology Transient neonatal jaundice is one of the most common conditions occurring in newborns (children under 28 days of age) with more than 80 per cent experienceing jaundice during their first week of life. Jaundice in infants, as in adults, is characterized by increased bilirubin levels (infants: total serum bilirubin greater than 5 mg/dL). Normal physiological neonatal jaundice is due to immaturity of liver enzymes involved in bilirubin metabolism, immature gut microbiota, and increased breakdown of fetal hemoglobin (HbF). Breast milk jaundice is caused by an increased concentration of β-glucuronidase in breast milk, which increases bilirubin deconjugation and reabsorption of bilirubin, leading to persistence of physiologic jaundice with unconjugated hyperbilirubinemia. Onset of breast milk jaundice is within 2 weeks after birth and lasts for 4–13 weeks. While most cases of newborn jaundice are not harmful, when bilirubin levels are very high, brain damage—kernicterus—may occur Kernicterus is associated with increased unconjugated bilirubin (bilirubin which is not carried by albumin). Newborns are especially vulnerable to this damage, due to increased permeability of the blood–brain barrier occurring with increased unconjugated bilirubin, simultaneous to the breakdown of fetal hemoglobin and the immaturity of gut flora. This condition has been rising in recent years, as babies spend less time in sunlight. Treatment Jaundice in newborns is usually transient and dissipates without medical intervention. In cases when serum bilirubin levels are greater than 4–21 mg/dl (68–360 μmol/L), infant may be treated with phototherapy or exchanged transfusion depending on the infant's age and prematurity status. A 2014 systematic review found no evidence indicating whether outcomes were different for hospital-based versus home-based treatment. A 2021 Cochrane systematic review found that sunlight can be used to supplement phototherapy, as long as care is taken to prevent overheating and skin damage. There was not sufficient evidence to conclude that sunlight by itself is an effective treatment. ==Etymology==

Jaundice comes from the French , meaning 'yellow'; meaning 'yellow disease'. The medical term is icterus, from the Greek word . The term icterus is sometimes incorrectly used to refer to jaundice specifically of sclera. It is also referenced in the scientific name of the yellow-breasted chat (Icteria virens), whose sight was believed to cure jaundice. == References ==