{"id":445,"date":"2023-12-04T10:25:13","date_gmt":"2023-12-04T15:25:13","guid":{"rendered":"https:\/\/pressbooks.bccampus.ca\/dcbiol2200\/chapter\/accessory-organs-in-digestion-the-liver-pancreas-and-gallbladder\/"},"modified":"2023-12-04T10:49:45","modified_gmt":"2023-12-04T15:49:45","slug":"accessory-organs-in-digestion-the-liver-pancreas-and-gallbladder","status":"web-only","type":"chapter","link":"https:\/\/pressbooks.bccampus.ca\/dcbiol2200\/chapter\/accessory-organs-in-digestion-the-liver-pancreas-and-gallbladder\/","title":{"raw":"The Normal Liver and Gallbladder","rendered":"The Normal Liver and Gallbladder"},"content":{"raw":"\n<div class=\"textbox textbox--learning-objectives\"><header class=\"textbox__header\">\n<p class=\"textbox__title\">Learning Objectives<\/p>\n\n<\/header>\n<div class=\"textbox__content\">\n\nBy the end of this section, you will be able to:\n<ul>\n \t<li>State the main digestive roles of the liver and gallbladder<\/li>\n \t<li>Identify three main features of liver histology that are critical to its function<\/li>\n \t<li>Discuss the composition and function of bile<\/li>\n<\/ul>\n<\/div>\n<\/div>\nChemical digestion in the small intestine relies on the activities of three accessory digestive organs: the [pb_glossary id=\"1134\"]liver[\/pb_glossary], [pb_glossary id=\"1081\"]pancreas[\/pb_glossary], and gallbladder (<a class=\"autogenerated-content\" href=\"#fig-ch24_06_01\">Figure 10.1<\/a>). The digestive role of the liver is to produce [pb_glossary id=\"1119\"]bile[\/pb_glossary] and export it to the duodenum. The gallbladder primarily stores, concentrates, and releases bile.\n\n[caption id=\"\" align=\"aligncenter\" width=\"390\"]<img src=\"https:\/\/pressbooks.bccampus.ca\/dcbiol2200\/wp-content\/uploads\/sites\/2131\/2023\/12\/2422_Accessory_Organs.jpg\" alt=\"This diagram shows the accessory organs of the digestive system. The liver, spleen, pancreas, gallbladder and their major parts are shown.\" width=\"390\" height=\"1002\" data-media-type=\"image\/jpg\"> <strong>Figure 10.1<\/strong> <em>The Liver, Spleen, Pancreas and Upper Duodenum<\/em>[\/caption]\n<h2>The Liver<\/h2>\nThe <span data-type=\"term\">liver<\/span> is the largest gland in the body, weighing about three pounds in an adult. It is also one of the most important organs. In addition to being an accessory digestive organ, it plays a number of roles in metabolism and regulation of blood plasma composition. The liver lies inferior to the diaphragm in the right upper quadrant of the abdominal cavity and receives protection from the surrounding ribs.\n\nThe liver is divided into two primary lobes: a large right lobe and a much smaller left lobe. In the right lobe, some anatomists also identify an inferior quadrate lobe and a posterior caudate lobe, which are defined by internal features. The liver is connected to the abdominal wall and diaphragm by five peritoneal folds referred to as ligaments. These are the falciform ligament, the coronary ligament, two lateral ligaments, and the ligamentum teres hepatis. The falciform ligament and ligamentum teres hepatis are actually remnants of the umbilical vein, and separate the right and left lobes anteriorly. The lesser omentum tethers the liver to the lesser curvature of the stomach.\n\nThe <span data-type=\"term\">[pb_glossary id=\"1136\"]porta hepatis[\/pb_glossary]<\/span> (\u201cgate\/door to the liver\u201d) is where the <span data-type=\"term\">[pb_glossary id=\"1128\"]hepatic artery[\/pb_glossary]<\/span> and <span data-type=\"term\">[pb_glossary id=\"1130\"]hepatic portal vein[\/pb_glossary]<\/span> enter the liver. These two vessels, along with the [pb_glossary id=\"1124\"]common hepatic duct[\/pb_glossary], run behind the lateral border of the lesser omentum on the way to their destinations. As shown in <a class=\"autogenerated-content\" href=\"#fig-ch24_06_02\">(Figure 10.2)<\/a>, the hepatic artery delivers oxygenated blood from the heart to the liver. The hepatic portal vein delivers approximately 80% of&nbsp; total blood flow to the liver; portal vein blood is partially deoxygenated, but contains nutrients absorbed from the small intestine and actually supplies more oxygen to the liver than do the much smaller hepatic arteries. In addition to nutrients, drugs and toxins are also absorbed. After processing the bloodborne nutrients and toxins, the liver releases nutrients needed by other cells back into the blood, which drains into the [pb_glossary id=\"1122\"]central vein[\/pb_glossary] and then through the [pb_glossary id=\"1132\"]hepatic vein[\/pb_glossary] to the inferior vena cava. With this hepatic portal circulation, all blood from the alimentary canal passes through the liver. This largely explains why the liver is the most common site for the metastasis of cancers that originate in the alimentary canal.\n\n[caption id=\"\" align=\"aligncenter\" width=\"420\"]<img src=\"https:\/\/pressbooks.bccampus.ca\/dcbiol2200\/wp-content\/uploads\/sites\/2131\/2023\/12\/2423_Microscopic_Anatomy_of_Liver.jpg\" alt=\"This image shows the microscopic anatomy of the liver. The top panel shows the liver; the center panel shows a magnified view of the connective tissue and the lobules. The bottom panel shows a further magnified view of a lobule, identifying the veins, bile duct and the sinusoids.\" width=\"420\" height=\"824\" data-media-type=\"image\/jpg\"> <strong>Figure 10.2<\/strong> <em>Microscopic Anatomy of the Liver - The liver receives oxygenated blood from the hepatic artery and nutrient-rich deoxygenated blood from the hepatic portal vein.<\/em>[\/caption]\n<h3>Histology<\/h3>\nThe liver has three main components: [pb_glossary id=\"1133\"]hepatocytes[\/pb_glossary], bile canaliculi, and [pb_glossary id=\"1131\"]hepatic sinusoids[\/pb_glossary]. A <span data-type=\"term\">hepatocyte<\/span> is the liver\u2019s main cell type, accounting for around 80 percent of the liver's volume. These cells play a role in a wide variety of secretory, metabolic, and endocrine functions. Plates of hepatocytes called hepatic laminae radiate outward from the central vein in each <span data-type=\"term\">[pb_glossary id=\"1129\"]hepatic lobule[\/pb_glossary]<\/span>.\n\nBetween adjacent hepatocytes, grooves in the cell membranes provide room for each <span data-type=\"term\">[pb_glossary id=\"1120\"]bile canaliculus[\/pb_glossary]<\/span> (plural = canaliculi). These small ducts transport the bile that is produced and secreted by hepatocytes. From here, bile flows first into bile ductules and then into bile ducts. The bile ducts unite to form the larger right and left hepatic ducts, which themselves merge and exit the liver as the <span data-type=\"term\">common hepatic duct<\/span>. This duct then joins with the cystic duct from the gallbladder, forming the <span data-type=\"term\">[pb_glossary id=\"1123\"]common bile duct[\/pb_glossary]<\/span> through which bile flows into the duodenum of the small intestine.\n\n<span data-type=\"term\">Hepatic sinusoids<\/span> are an open, porous blood space lined with simple squamous endothelial cells that takes the form of discontinuous fenestrated capillaries.&nbsp; Sinusoids are formed by the merging of nutrient-rich hepatic portal veins and oxygen-rich hepatic arteries and therefore carry mixed blood containing nutrients from the alimentary canal as well as oxygen.&nbsp; Sinusoids are instrumental in that they infiltrate each hepatic laminae delivering their contents to the hepatocytes.&nbsp; From their central position, hepatocytes absorb and process the nutrients, toxins, and waste materials carried by the blood. Materials such as [pb_glossary id=\"1121\"]bilirubin[\/pb_glossary] are processed and excreted into the bile canaliculi. Other materials including proteins, lipids, and carbohydrates are processed and secreted into the sinusoids at levels that maintain specific levels within the blood.&nbsp; Hepatocytes have the ability to store excess lipid, carbohydrates and amino acids until the blood plasma levels become depleted.&nbsp; Maintaining blood plasma composition is very important as each of these blood plasma components are required by cells of the entire body.&nbsp; The liver therefore has an important role in ensuring maintenance, survival, and homeostasis of all of the tissues and organs.\n\nOnce the hepatic sinusoids have passed by the hepatocytes within each laminae, the sinusoids merge and send blood through a <span data-type=\"term\">central vein<\/span>. Blood then flows through a <span data-type=\"term\">hepatic vein<\/span> into the inferior vena cava (IVC). This means that blood and bile flow in opposite directions. The hepatic sinusoids also contain star-shaped <span data-type=\"term\">[pb_glossary id=\"1138\"]reticuloendothelial cells[\/pb_glossary]<\/span> (Kupffer cells), phagocytes that remove dead red and white blood cells, bacteria, and other foreign material that enter the sinusoids. The <span data-type=\"term\">[pb_glossary id=\"1137\"]portal triad[\/pb_glossary]<\/span> is a distinctive arrangement around the perimeter of hepatic lobules, consisting of three basic structures: a bile duct, a hepatic artery branch, and a hepatic portal vein branch.\n<h3>Bile<\/h3>\nIn order to underscore the importance of the bile that is produced by hepatocytes.&nbsp; It is important to remember that the food that is eaten does contain fat which is a valuable energy source and building block for the body.&nbsp; Recall that lipids are hydrophobic, that is, they do not dissolve in water. Thus, before they can be digested in the watery environment of the small intestine, large lipid globules must be broken down into smaller lipid globules, a process called emulsification. <span data-type=\"term\">Bile<\/span> is a mixture secreted by the liver to accomplish the emulsification of lipids in the small intestine.\n\nHepatocytes secrete about one liter of bile each day. A yellow-brown or yellow-green alkaline solution (pH 7.6 to 8.6), bile is a mixture of water, bile salts, bile pigments, phospholipids (such as lecithin), electrolytes, cholesterol, and triglycerides. The components most critical to emulsification are bile salts and phospholipids, both of which have a nonpolar (hydrophobic) region as well as a polar (hydrophilic) region. The hydrophobic region interacts with the large lipid molecules, whereas the hydrophilic region interacts with the watery chyme in the intestine. This results in the large lipid globules being pulled apart into many tiny lipid fragments of about 1 <em data-effect=\"italics\">\u00b5<\/em>m in diameter. This change dramatically increases the surface area available for lipid-digesting enzyme activity.&nbsp; Emulsification is similar to way dish soap can disperse oil slicks or fats that can be seen on the top of dishwater.\n\nBile salts act as emulsifying agents, so they are also important for the intestine's ability to digest and then absorb lipids. While most constituents of bile are eliminated in feces, bile salts are reclaimed by the <span data-type=\"term\">[pb_glossary id=\"1126\"]enterohepatic circulation[\/pb_glossary]<\/span>. Once bile salts reach the ileum, they are absorbed and returned to the liver in the hepatic portal blood. The hepatocytes absorb and then excrete the bile salts as part of the newly formed bile. Thus, this precious resource is recycled.\n\n<span data-type=\"term\">Bilirubin<\/span>, the main bile pigment, is a waste product produced when the spleen removes old or damaged red blood cells from the circulation. These breakdown products, including proteins, iron, and toxic bilirubin, are transported to the liver via the splenic vein of the hepatic portal system. In the liver, proteins and iron are recycled, whereas bilirubin is processed and then excreted in the bile. It accounts for the green color of bile. Bilirubin is eventually transformed by intestinal bacteria into stercobilin, a brown pigment that gives your stool its characteristic colour! In some disease states, bile does not enter the intestine, resulting in white (\u2018acholic\u2019) stool with a high fat content, since virtually no fats are able to be broken down or absorbed in the absence of bile.\n\nHepatocytes work non-stop, but bile production increases when fatty chyme enters the duodenum and stimulates the secretion of the gut hormone secretin. Between meals, bile is produced but conserved. The valve-like hepatopancreatic ampulla closes, allowing bile to divert to the [pb_glossary id=\"1127\"]gallbladder[\/pb_glossary], where it is concentrated and stored until the next meal.\n<div id=\"fs-id1708440\" class=\"anatomy interactive\" data-type=\"note\" data-has-label=\"true\" data-label=\"\">\n\nWatch this <a href=\"http:\/\/openstax.org\/l\/liver\" target=\"_blank\" rel=\"noopener\">video on liver<\/a> to see the structure of the liver and how this structure supports the functions of the liver, including the processing of nutrients, toxins, and wastes. At rest, about 1500 mL of blood per minute flow through the liver. What percentage of this blood flow comes from the hepatic portal system?\n<h2>The Gallbladder<\/h2>\nThe <span data-type=\"term\">gallbladder<\/span> is 8\u201310 cm (~3\u20134 in) long and is nested in a shallow area on the posterior aspect of the right lobe of the liver. This muscular sac stores, concentrates, and, when stimulated, propels the bile into the duodenum via the common bile duct. It is divided into three regions. The fundus is the widest portion and tapers medially into the body, which in turn narrows to become the neck. The neck angles slightly superiorly as it approaches the hepatic duct. The [pb_glossary id=\"1125\"]cystic duct[\/pb_glossary] is 1\u20132 cm (less than 1 in) long and turns inferiorly as it bridges the neck and hepatic duct.\n\nThe simple columnar epithelium of the gallbladder mucosa is organized in rugae, similar to those of the stomach. There is no submucosa in the gallbladder wall. The wall\u2019s middle, muscular coat is made of smooth muscle fibers. When these fibers contract, the gallbladder\u2019s contents are ejected through the <span data-type=\"term\">cystic duct<\/span> and into the bile duct (<a class=\"autogenerated-content\" href=\"#fig-ch24_06_04\">Figure 10.3<\/a>). Visceral peritoneum reflected from the liver capsule holds the gallbladder against the liver and forms the outer coat of the gallbladder. The gallbladder's mucosa absorbs water and ions from bile, concentrating it by up to 10-fold.\n\n[caption id=\"\" align=\"aligncenter\" width=\"380\"]<img src=\"https:\/\/pressbooks.bccampus.ca\/dcbiol2200\/wp-content\/uploads\/sites\/2131\/2023\/12\/2425_Gallbladder.jpg\" alt=\"This figure shows the gallbladder and its major parts are labeled.\" width=\"380\" height=\"641\" data-media-type=\"image\/jpg\"> <strong>Figure 10.3 Gallbladder<\/strong> - <em>The gallbladder stores and concentrates bile, and releases it into the two-way cystic duct when it is needed by the small intestine.<\/em>[\/caption]\n\n<\/div>\n<h1>Chapter Review<\/h1>\nChemical digestion in the small intestine cannot occur without the help of the liver and pancreas. The liver produces bile and delivers it to the common hepatic duct. Bile contains bile salts and phospholipids, which emulsify large lipid globules into tiny lipid droplets, a necessary step in lipid digestion and absorption. The gallbladder stores and concentrates bile, releasing it when it is needed by the small intestine.\n\nThe pancreas produces the enzyme- and bicarbonate-rich [pb_glossary id=\"1135\"]pancreatic juice[\/pb_glossary] and delivers it to the duodenum of the small intestine through ducts. Pancreatic juice buffers the acidic gastric juice in chyme, inactivates pepsin from the stomach, and enables the optimal functioning of digestive enzymes in the small intestine.\n<h1>Review Questions<\/h1>\n[h5p id=\"95\"]\n<h1>Adaption<\/h1>\n<p style=\"text-align: start\">This chapter is adapted from the following text:<\/p>\n<p style=\"text-align: start\"><a href=\"https:\/\/openstax.org\/books\/anatomy-and-physiology\/pages\/23-6-accessory-organs-in-digestion-the-liver-pancreas-and-gallbladder\" target=\"_blank\" rel=\"noopener\">Accessory organs of the digestive<\/a>&nbsp;<strong>in&nbsp;<\/strong><a href=\"https:\/\/openstax.org\/books\/anatomy-and-physiology\/pages\/23-6-accessory-organs-in-digestion-the-liver-pancreas-and-gallbladder\" target=\"_blank\" rel=\"noopener\">Anatomy and Physiology<\/a>&nbsp;by&nbsp;OSCRiceUniversity&nbsp;is licensed under a&nbsp;<a href=\"https:\/\/creativecommons.org\/licenses\/by\/4.0\/\">Creative Commons Attribution 4.0 International License<\/a><\/p>\n","rendered":"<div class=\"textbox textbox--learning-objectives\">\n<header class=\"textbox__header\">\n<p class=\"textbox__title\">Learning Objectives<\/p>\n<\/header>\n<div class=\"textbox__content\">\n<p>By the end of this section, you will be able to:<\/p>\n<ul>\n<li>State the main digestive roles of the liver and gallbladder<\/li>\n<li>Identify three main features of liver histology that are critical to its function<\/li>\n<li>Discuss the composition and function of bile<\/li>\n<\/ul>\n<\/div>\n<\/div>\n<p>Chemical digestion in the small intestine relies on the activities of three accessory digestive organs: the <a class=\"glossary-term\" aria-haspopup=\"dialog\" aria-describedby=\"definition\" href=\"#term_445_1134\">liver<\/a>, <a class=\"glossary-term\" aria-haspopup=\"dialog\" aria-describedby=\"definition\" href=\"#term_445_1081\">pancreas<\/a>, and gallbladder (<a class=\"autogenerated-content\" href=\"#fig-ch24_06_01\">Figure 10.1<\/a>). The digestive role of the liver is to produce <a class=\"glossary-term\" aria-haspopup=\"dialog\" aria-describedby=\"definition\" href=\"#term_445_1119\">bile<\/a> and export it to the duodenum. The gallbladder primarily stores, concentrates, and releases bile.<\/p>\n<figure style=\"width: 390px\" class=\"wp-caption aligncenter\"><img loading=\"lazy\" decoding=\"async\" src=\"https:\/\/pressbooks.bccampus.ca\/dcbiol2200\/wp-content\/uploads\/sites\/2131\/2023\/12\/2422_Accessory_Organs.jpg\" alt=\"This diagram shows the accessory organs of the digestive system. The liver, spleen, pancreas, gallbladder and their major parts are shown.\" width=\"390\" height=\"1002\" data-media-type=\"image\/jpg\" \/><figcaption class=\"wp-caption-text\"><strong>Figure 10.1<\/strong> <em>The Liver, Spleen, Pancreas and Upper Duodenum<\/em><\/figcaption><\/figure>\n<h2>The Liver<\/h2>\n<p>The <span data-type=\"term\">liver<\/span> is the largest gland in the body, weighing about three pounds in an adult. It is also one of the most important organs. In addition to being an accessory digestive organ, it plays a number of roles in metabolism and regulation of blood plasma composition. The liver lies inferior to the diaphragm in the right upper quadrant of the abdominal cavity and receives protection from the surrounding ribs.<\/p>\n<p>The liver is divided into two primary lobes: a large right lobe and a much smaller left lobe. In the right lobe, some anatomists also identify an inferior quadrate lobe and a posterior caudate lobe, which are defined by internal features. The liver is connected to the abdominal wall and diaphragm by five peritoneal folds referred to as ligaments. These are the falciform ligament, the coronary ligament, two lateral ligaments, and the ligamentum teres hepatis. The falciform ligament and ligamentum teres hepatis are actually remnants of the umbilical vein, and separate the right and left lobes anteriorly. The lesser omentum tethers the liver to the lesser curvature of the stomach.<\/p>\n<p>The <span data-type=\"term\"><a class=\"glossary-term\" aria-haspopup=\"dialog\" aria-describedby=\"definition\" href=\"#term_445_1136\">porta hepatis<\/a><\/span> (\u201cgate\/door to the liver\u201d) is where the <span data-type=\"term\"><a class=\"glossary-term\" aria-haspopup=\"dialog\" aria-describedby=\"definition\" href=\"#term_445_1128\">hepatic artery<\/a><\/span> and <span data-type=\"term\"><a class=\"glossary-term\" aria-haspopup=\"dialog\" aria-describedby=\"definition\" href=\"#term_445_1130\">hepatic portal vein<\/a><\/span> enter the liver. These two vessels, along with the <a class=\"glossary-term\" aria-haspopup=\"dialog\" aria-describedby=\"definition\" href=\"#term_445_1124\">common hepatic duct<\/a>, run behind the lateral border of the lesser omentum on the way to their destinations. As shown in <a class=\"autogenerated-content\" href=\"#fig-ch24_06_02\">(Figure 10.2)<\/a>, the hepatic artery delivers oxygenated blood from the heart to the liver. The hepatic portal vein delivers approximately 80% of&nbsp; total blood flow to the liver; portal vein blood is partially deoxygenated, but contains nutrients absorbed from the small intestine and actually supplies more oxygen to the liver than do the much smaller hepatic arteries. In addition to nutrients, drugs and toxins are also absorbed. After processing the bloodborne nutrients and toxins, the liver releases nutrients needed by other cells back into the blood, which drains into the <a class=\"glossary-term\" aria-haspopup=\"dialog\" aria-describedby=\"definition\" href=\"#term_445_1122\">central vein<\/a> and then through the <a class=\"glossary-term\" aria-haspopup=\"dialog\" aria-describedby=\"definition\" href=\"#term_445_1132\">hepatic vein<\/a> to the inferior vena cava. With this hepatic portal circulation, all blood from the alimentary canal passes through the liver. This largely explains why the liver is the most common site for the metastasis of cancers that originate in the alimentary canal.<\/p>\n<figure style=\"width: 420px\" class=\"wp-caption aligncenter\"><img loading=\"lazy\" decoding=\"async\" src=\"https:\/\/pressbooks.bccampus.ca\/dcbiol2200\/wp-content\/uploads\/sites\/2131\/2023\/12\/2423_Microscopic_Anatomy_of_Liver.jpg\" alt=\"This image shows the microscopic anatomy of the liver. The top panel shows the liver; the center panel shows a magnified view of the connective tissue and the lobules. The bottom panel shows a further magnified view of a lobule, identifying the veins, bile duct and the sinusoids.\" width=\"420\" height=\"824\" data-media-type=\"image\/jpg\" \/><figcaption class=\"wp-caption-text\"><strong>Figure 10.2<\/strong> <em>Microscopic Anatomy of the Liver &#8211; The liver receives oxygenated blood from the hepatic artery and nutrient-rich deoxygenated blood from the hepatic portal vein.<\/em><\/figcaption><\/figure>\n<h3>Histology<\/h3>\n<p>The liver has three main components: <a class=\"glossary-term\" aria-haspopup=\"dialog\" aria-describedby=\"definition\" href=\"#term_445_1133\">hepatocytes<\/a>, bile canaliculi, and <a class=\"glossary-term\" aria-haspopup=\"dialog\" aria-describedby=\"definition\" href=\"#term_445_1131\">hepatic sinusoids<\/a>. A <span data-type=\"term\">hepatocyte<\/span> is the liver\u2019s main cell type, accounting for around 80 percent of the liver&#8217;s volume. These cells play a role in a wide variety of secretory, metabolic, and endocrine functions. Plates of hepatocytes called hepatic laminae radiate outward from the central vein in each <span data-type=\"term\"><a class=\"glossary-term\" aria-haspopup=\"dialog\" aria-describedby=\"definition\" href=\"#term_445_1129\">hepatic lobule<\/a><\/span>.<\/p>\n<p>Between adjacent hepatocytes, grooves in the cell membranes provide room for each <span data-type=\"term\"><a class=\"glossary-term\" aria-haspopup=\"dialog\" aria-describedby=\"definition\" href=\"#term_445_1120\">bile canaliculus<\/a><\/span> (plural = canaliculi). These small ducts transport the bile that is produced and secreted by hepatocytes. From here, bile flows first into bile ductules and then into bile ducts. The bile ducts unite to form the larger right and left hepatic ducts, which themselves merge and exit the liver as the <span data-type=\"term\">common hepatic duct<\/span>. This duct then joins with the cystic duct from the gallbladder, forming the <span data-type=\"term\"><a class=\"glossary-term\" aria-haspopup=\"dialog\" aria-describedby=\"definition\" href=\"#term_445_1123\">common bile duct<\/a><\/span> through which bile flows into the duodenum of the small intestine.<\/p>\n<p><span data-type=\"term\">Hepatic sinusoids<\/span> are an open, porous blood space lined with simple squamous endothelial cells that takes the form of discontinuous fenestrated capillaries.&nbsp; Sinusoids are formed by the merging of nutrient-rich hepatic portal veins and oxygen-rich hepatic arteries and therefore carry mixed blood containing nutrients from the alimentary canal as well as oxygen.&nbsp; Sinusoids are instrumental in that they infiltrate each hepatic laminae delivering their contents to the hepatocytes.&nbsp; From their central position, hepatocytes absorb and process the nutrients, toxins, and waste materials carried by the blood. Materials such as <a class=\"glossary-term\" aria-haspopup=\"dialog\" aria-describedby=\"definition\" href=\"#term_445_1121\">bilirubin<\/a> are processed and excreted into the bile canaliculi. Other materials including proteins, lipids, and carbohydrates are processed and secreted into the sinusoids at levels that maintain specific levels within the blood.&nbsp; Hepatocytes have the ability to store excess lipid, carbohydrates and amino acids until the blood plasma levels become depleted.&nbsp; Maintaining blood plasma composition is very important as each of these blood plasma components are required by cells of the entire body.&nbsp; The liver therefore has an important role in ensuring maintenance, survival, and homeostasis of all of the tissues and organs.<\/p>\n<p>Once the hepatic sinusoids have passed by the hepatocytes within each laminae, the sinusoids merge and send blood through a <span data-type=\"term\">central vein<\/span>. Blood then flows through a <span data-type=\"term\">hepatic vein<\/span> into the inferior vena cava (IVC). This means that blood and bile flow in opposite directions. The hepatic sinusoids also contain star-shaped <span data-type=\"term\"><a class=\"glossary-term\" aria-haspopup=\"dialog\" aria-describedby=\"definition\" href=\"#term_445_1138\">reticuloendothelial cells<\/a><\/span> (Kupffer cells), phagocytes that remove dead red and white blood cells, bacteria, and other foreign material that enter the sinusoids. The <span data-type=\"term\"><a class=\"glossary-term\" aria-haspopup=\"dialog\" aria-describedby=\"definition\" href=\"#term_445_1137\">portal triad<\/a><\/span> is a distinctive arrangement around the perimeter of hepatic lobules, consisting of three basic structures: a bile duct, a hepatic artery branch, and a hepatic portal vein branch.<\/p>\n<h3>Bile<\/h3>\n<p>In order to underscore the importance of the bile that is produced by hepatocytes.&nbsp; It is important to remember that the food that is eaten does contain fat which is a valuable energy source and building block for the body.&nbsp; Recall that lipids are hydrophobic, that is, they do not dissolve in water. Thus, before they can be digested in the watery environment of the small intestine, large lipid globules must be broken down into smaller lipid globules, a process called emulsification. <span data-type=\"term\">Bile<\/span> is a mixture secreted by the liver to accomplish the emulsification of lipids in the small intestine.<\/p>\n<p>Hepatocytes secrete about one liter of bile each day. A yellow-brown or yellow-green alkaline solution (pH 7.6 to 8.6), bile is a mixture of water, bile salts, bile pigments, phospholipids (such as lecithin), electrolytes, cholesterol, and triglycerides. The components most critical to emulsification are bile salts and phospholipids, both of which have a nonpolar (hydrophobic) region as well as a polar (hydrophilic) region. The hydrophobic region interacts with the large lipid molecules, whereas the hydrophilic region interacts with the watery chyme in the intestine. This results in the large lipid globules being pulled apart into many tiny lipid fragments of about 1 <em data-effect=\"italics\">\u00b5<\/em>m in diameter. This change dramatically increases the surface area available for lipid-digesting enzyme activity.&nbsp; Emulsification is similar to way dish soap can disperse oil slicks or fats that can be seen on the top of dishwater.<\/p>\n<p>Bile salts act as emulsifying agents, so they are also important for the intestine&#8217;s ability to digest and then absorb lipids. While most constituents of bile are eliminated in feces, bile salts are reclaimed by the <span data-type=\"term\"><a class=\"glossary-term\" aria-haspopup=\"dialog\" aria-describedby=\"definition\" href=\"#term_445_1126\">enterohepatic circulation<\/a><\/span>. Once bile salts reach the ileum, they are absorbed and returned to the liver in the hepatic portal blood. The hepatocytes absorb and then excrete the bile salts as part of the newly formed bile. Thus, this precious resource is recycled.<\/p>\n<p><span data-type=\"term\">Bilirubin<\/span>, the main bile pigment, is a waste product produced when the spleen removes old or damaged red blood cells from the circulation. These breakdown products, including proteins, iron, and toxic bilirubin, are transported to the liver via the splenic vein of the hepatic portal system. In the liver, proteins and iron are recycled, whereas bilirubin is processed and then excreted in the bile. It accounts for the green color of bile. Bilirubin is eventually transformed by intestinal bacteria into stercobilin, a brown pigment that gives your stool its characteristic colour! In some disease states, bile does not enter the intestine, resulting in white (\u2018acholic\u2019) stool with a high fat content, since virtually no fats are able to be broken down or absorbed in the absence of bile.<\/p>\n<p>Hepatocytes work non-stop, but bile production increases when fatty chyme enters the duodenum and stimulates the secretion of the gut hormone secretin. Between meals, bile is produced but conserved. The valve-like hepatopancreatic ampulla closes, allowing bile to divert to the <a class=\"glossary-term\" aria-haspopup=\"dialog\" aria-describedby=\"definition\" href=\"#term_445_1127\">gallbladder<\/a>, where it is concentrated and stored until the next meal.<\/p>\n<div id=\"fs-id1708440\" class=\"anatomy interactive\" data-type=\"note\" data-has-label=\"true\" data-label=\"\">\n<p>Watch this <a href=\"http:\/\/openstax.org\/l\/liver\" target=\"_blank\" rel=\"noopener\">video on liver<\/a> to see the structure of the liver and how this structure supports the functions of the liver, including the processing of nutrients, toxins, and wastes. At rest, about 1500 mL of blood per minute flow through the liver. What percentage of this blood flow comes from the hepatic portal system?<\/p>\n<h2>The Gallbladder<\/h2>\n<p>The <span data-type=\"term\">gallbladder<\/span> is 8\u201310 cm (~3\u20134 in) long and is nested in a shallow area on the posterior aspect of the right lobe of the liver. This muscular sac stores, concentrates, and, when stimulated, propels the bile into the duodenum via the common bile duct. It is divided into three regions. The fundus is the widest portion and tapers medially into the body, which in turn narrows to become the neck. The neck angles slightly superiorly as it approaches the hepatic duct. The <a class=\"glossary-term\" aria-haspopup=\"dialog\" aria-describedby=\"definition\" href=\"#term_445_1125\">cystic duct<\/a> is 1\u20132 cm (less than 1 in) long and turns inferiorly as it bridges the neck and hepatic duct.<\/p>\n<p>The simple columnar epithelium of the gallbladder mucosa is organized in rugae, similar to those of the stomach. There is no submucosa in the gallbladder wall. The wall\u2019s middle, muscular coat is made of smooth muscle fibers. When these fibers contract, the gallbladder\u2019s contents are ejected through the <span data-type=\"term\">cystic duct<\/span> and into the bile duct (<a class=\"autogenerated-content\" href=\"#fig-ch24_06_04\">Figure 10.3<\/a>). Visceral peritoneum reflected from the liver capsule holds the gallbladder against the liver and forms the outer coat of the gallbladder. The gallbladder&#8217;s mucosa absorbs water and ions from bile, concentrating it by up to 10-fold.<\/p>\n<figure style=\"width: 380px\" class=\"wp-caption aligncenter\"><img loading=\"lazy\" decoding=\"async\" src=\"https:\/\/pressbooks.bccampus.ca\/dcbiol2200\/wp-content\/uploads\/sites\/2131\/2023\/12\/2425_Gallbladder.jpg\" alt=\"This figure shows the gallbladder and its major parts are labeled.\" width=\"380\" height=\"641\" data-media-type=\"image\/jpg\" \/><figcaption class=\"wp-caption-text\"><strong>Figure 10.3 Gallbladder<\/strong> &#8211; <em>The gallbladder stores and concentrates bile, and releases it into the two-way cystic duct when it is needed by the small intestine.<\/em><\/figcaption><\/figure>\n<\/div>\n<h1>Chapter Review<\/h1>\n<p>Chemical digestion in the small intestine cannot occur without the help of the liver and pancreas. The liver produces bile and delivers it to the common hepatic duct. Bile contains bile salts and phospholipids, which emulsify large lipid globules into tiny lipid droplets, a necessary step in lipid digestion and absorption. The gallbladder stores and concentrates bile, releasing it when it is needed by the small intestine.<\/p>\n<p>The pancreas produces the enzyme- and bicarbonate-rich <a class=\"glossary-term\" aria-haspopup=\"dialog\" aria-describedby=\"definition\" href=\"#term_445_1135\">pancreatic juice<\/a> and delivers it to the duodenum of the small intestine through ducts. Pancreatic juice buffers the acidic gastric juice in chyme, inactivates pepsin from the stomach, and enables the optimal functioning of digestive enzymes in the small intestine.<\/p>\n<h1>Review Questions<\/h1>\n<h1>Adaption<\/h1>\n<p style=\"text-align: start\">This chapter is adapted from the following text:<\/p>\n<p style=\"text-align: start\"><a href=\"https:\/\/openstax.org\/books\/anatomy-and-physiology\/pages\/23-6-accessory-organs-in-digestion-the-liver-pancreas-and-gallbladder\" target=\"_blank\" rel=\"noopener\">Accessory organs of the digestive<\/a>&nbsp;<strong>in&nbsp;<\/strong><a href=\"https:\/\/openstax.org\/books\/anatomy-and-physiology\/pages\/23-6-accessory-organs-in-digestion-the-liver-pancreas-and-gallbladder\" target=\"_blank\" rel=\"noopener\">Anatomy and Physiology<\/a>&nbsp;by&nbsp;OSCRiceUniversity&nbsp;is licensed under a&nbsp;<a href=\"https:\/\/creativecommons.org\/licenses\/by\/4.0\/\">Creative Commons Attribution 4.0 International License<\/a><\/p>\n<div class=\"glossary\"><span class=\"screen-reader-text\" id=\"definition\">definition<\/span><template id=\"term_445_1134\"><div class=\"glossary__definition\" role=\"dialog\" data-id=\"term_445_1134\"><div tabindex=\"-1\"><p>largest gland in the body whose main digestive function is the production of bile<\/p>\n<\/div><button><span aria-hidden=\"true\">&times;<\/span><span class=\"screen-reader-text\">Close definition<\/span><\/button><\/div><\/template><template id=\"term_445_1081\"><div class=\"glossary__definition\" role=\"dialog\" data-id=\"term_445_1081\"><div tabindex=\"-1\"><p>organ with both exocrine and endocrine functions located posterior to the stomach that is important for digestion and the regulation of blood glucose<\/p>\n<\/div><button><span aria-hidden=\"true\">&times;<\/span><span class=\"screen-reader-text\">Close definition<\/span><\/button><\/div><\/template><template id=\"term_445_1119\"><div class=\"glossary__definition\" role=\"dialog\" data-id=\"term_445_1119\"><div tabindex=\"-1\"><p>alkaline solution produced by the liver and important for the emulsification of lipids<\/p>\n<\/div><button><span aria-hidden=\"true\">&times;<\/span><span class=\"screen-reader-text\">Close definition<\/span><\/button><\/div><\/template><template id=\"term_445_1136\"><div class=\"glossary__definition\" role=\"dialog\" data-id=\"term_445_1136\"><div tabindex=\"-1\"><p>\u201cgateway to the liver\u201d where the hepatic artery and hepatic portal vein enter the liver<\/p>\n<\/div><button><span aria-hidden=\"true\">&times;<\/span><span class=\"screen-reader-text\">Close definition<\/span><\/button><\/div><\/template><template id=\"term_445_1128\"><div class=\"glossary__definition\" role=\"dialog\" data-id=\"term_445_1128\"><div tabindex=\"-1\"><p>artery that supplies oxygenated blood to the liver<\/p>\n<\/div><button><span aria-hidden=\"true\">&times;<\/span><span class=\"screen-reader-text\">Close definition<\/span><\/button><\/div><\/template><template id=\"term_445_1130\"><div class=\"glossary__definition\" role=\"dialog\" data-id=\"term_445_1130\"><div tabindex=\"-1\"><p>vein that supplies deoxygenated nutrient-rich blood to the liver<\/p>\n<\/div><button><span aria-hidden=\"true\">&times;<\/span><span class=\"screen-reader-text\">Close definition<\/span><\/button><\/div><\/template><template id=\"term_445_1124\"><div class=\"glossary__definition\" role=\"dialog\" data-id=\"term_445_1124\"><div tabindex=\"-1\"><p>duct formed by the merger of the two hepatic ducts<\/p>\n<\/div><button><span aria-hidden=\"true\">&times;<\/span><span class=\"screen-reader-text\">Close definition<\/span><\/button><\/div><\/template><template id=\"term_445_1122\"><div class=\"glossary__definition\" role=\"dialog\" data-id=\"term_445_1122\"><div tabindex=\"-1\"><p>vein that receives blood from hepatic sinusoids<\/p>\n<\/div><button><span aria-hidden=\"true\">&times;<\/span><span class=\"screen-reader-text\">Close definition<\/span><\/button><\/div><\/template><template id=\"term_445_1132\"><div class=\"glossary__definition\" role=\"dialog\" data-id=\"term_445_1132\"><div tabindex=\"-1\"><p>vein that drains into the inferior vena cava<\/p>\n<\/div><button><span aria-hidden=\"true\">&times;<\/span><span class=\"screen-reader-text\">Close definition<\/span><\/button><\/div><\/template><template id=\"term_445_1133\"><div class=\"glossary__definition\" role=\"dialog\" data-id=\"term_445_1133\"><div tabindex=\"-1\"><p>major functional cells of the liver<\/p>\n<\/div><button><span aria-hidden=\"true\">&times;<\/span><span class=\"screen-reader-text\">Close definition<\/span><\/button><\/div><\/template><template id=\"term_445_1131\"><div class=\"glossary__definition\" role=\"dialog\" data-id=\"term_445_1131\"><div tabindex=\"-1\"><p>blood capillaries between rows of hepatocytes that receive blood from the hepatic portal vein and the branches of the hepatic artery<\/p>\n<\/div><button><span aria-hidden=\"true\">&times;<\/span><span class=\"screen-reader-text\">Close definition<\/span><\/button><\/div><\/template><template id=\"term_445_1129\"><div class=\"glossary__definition\" role=\"dialog\" data-id=\"term_445_1129\"><div tabindex=\"-1\"><p>hexagonal-shaped structure composed of hepatocytes that radiate outward from a central vein<\/p>\n<\/div><button><span aria-hidden=\"true\">&times;<\/span><span class=\"screen-reader-text\">Close definition<\/span><\/button><\/div><\/template><template id=\"term_445_1120\"><div class=\"glossary__definition\" role=\"dialog\" data-id=\"term_445_1120\"><div tabindex=\"-1\"><p>small ducts between hepatocytes that collects bile<\/p>\n<\/div><button><span aria-hidden=\"true\">&times;<\/span><span class=\"screen-reader-text\">Close definition<\/span><\/button><\/div><\/template><template id=\"term_445_1123\"><div class=\"glossary__definition\" role=\"dialog\" data-id=\"term_445_1123\"><div tabindex=\"-1\"><p>structure formed by the union of the common hepatic duct and the gallbladder\u2019s cystic duct<\/p>\n<\/div><button><span aria-hidden=\"true\">&times;<\/span><span class=\"screen-reader-text\">Close definition<\/span><\/button><\/div><\/template><template id=\"term_445_1121\"><div class=\"glossary__definition\" role=\"dialog\" data-id=\"term_445_1121\"><div tabindex=\"-1\"><p>main bile pigment, which is responsible for the brown color of feces<\/p>\n<\/div><button><span aria-hidden=\"true\">&times;<\/span><span class=\"screen-reader-text\">Close definition<\/span><\/button><\/div><\/template><template id=\"term_445_1138\"><div class=\"glossary__definition\" role=\"dialog\" data-id=\"term_445_1138\"><div tabindex=\"-1\"><p>(also, Kupffer cell) phagocyte in hepatic sinusoids that filters out material from venous blood from the alimentary canal<\/p>\n<\/div><button><span aria-hidden=\"true\">&times;<\/span><span class=\"screen-reader-text\">Close definition<\/span><\/button><\/div><\/template><template id=\"term_445_1137\"><div class=\"glossary__definition\" role=\"dialog\" data-id=\"term_445_1137\"><div tabindex=\"-1\"><p>bile duct, hepatic artery branch, and hepatic portal vein branch<\/p>\n<\/div><button><span aria-hidden=\"true\">&times;<\/span><span class=\"screen-reader-text\">Close definition<\/span><\/button><\/div><\/template><template id=\"term_445_1126\"><div class=\"glossary__definition\" role=\"dialog\" data-id=\"term_445_1126\"><div tabindex=\"-1\"><p>recycling mechanism that conserves bile salts<\/p>\n<\/div><button><span aria-hidden=\"true\">&times;<\/span><span class=\"screen-reader-text\">Close definition<\/span><\/button><\/div><\/template><template id=\"term_445_1127\"><div class=\"glossary__definition\" role=\"dialog\" data-id=\"term_445_1127\"><div tabindex=\"-1\"><p>accessory digestive organ that stores and concentrates bile<\/p>\n<\/div><button><span aria-hidden=\"true\">&times;<\/span><span class=\"screen-reader-text\">Close definition<\/span><\/button><\/div><\/template><template id=\"term_445_1125\"><div class=\"glossary__definition\" role=\"dialog\" data-id=\"term_445_1125\"><div tabindex=\"-1\"><p>duct through which bile drains and enters the gallbladder<\/p>\n<\/div><button><span aria-hidden=\"true\">&times;<\/span><span class=\"screen-reader-text\">Close definition<\/span><\/button><\/div><\/template><template id=\"term_445_1135\"><div class=\"glossary__definition\" role=\"dialog\" data-id=\"term_445_1135\"><div tabindex=\"-1\"><p>secretion of the pancreas containing digestive enzymes and bicarbonate<\/p>\n<\/div><button><span aria-hidden=\"true\">&times;<\/span><span class=\"screen-reader-text\">Close definition<\/span><\/button><\/div><\/template><\/div>","protected":false},"author":103,"menu_order":4,"template":"","meta":{"pb_show_title":"on","pb_short_title":"","pb_subtitle":"","pb_authors":["j-gordon-betts-wmw0km2yc4","kelly-a-young-kvrvdtgd7l","james-a-wise-n3ettfdzbo","eddie-johnson-eooofqxsbt","brandon-poe-z4kjgbrtla","dean-h-kruse-zvxpwgxnv6","oksana-korol-jv27eblhm3","jody-e-johnson-rz4w6efp48","mark-womble-4haloxvxcz","peter-desaix-fikwt3tlhg"],"pb_section_license":"cc-by"},"chapter-type":[],"contributor":[163],"license":[53],"class_list":["post-445","chapter","type-chapter","status-web-only","hentry","contributor-peter-desaix-fikwt3tlhg","license-cc-by"],"part":438,"_links":{"self":[{"href":"https:\/\/pressbooks.bccampus.ca\/dcbiol2200\/wp-json\/pressbooks\/v2\/chapters\/445","targetHints":{"allow":["GET"]}}],"collection":[{"href":"https:\/\/pressbooks.bccampus.ca\/dcbiol2200\/wp-json\/pressbooks\/v2\/chapters"}],"about":[{"href":"https:\/\/pressbooks.bccampus.ca\/dcbiol2200\/wp-json\/wp\/v2\/types\/chapter"}],"author":[{"embeddable":true,"href":"https:\/\/pressbooks.bccampus.ca\/dcbiol2200\/wp-json\/wp\/v2\/users\/103"}],"version-history":[{"count":1,"href":"https:\/\/pressbooks.bccampus.ca\/dcbiol2200\/wp-json\/pressbooks\/v2\/chapters\/445\/revisions"}],"predecessor-version":[{"id":1298,"href":"https:\/\/pressbooks.bccampus.ca\/dcbiol2200\/wp-json\/pressbooks\/v2\/chapters\/445\/revisions\/1298"}],"part":[{"href":"https:\/\/pressbooks.bccampus.ca\/dcbiol2200\/wp-json\/pressbooks\/v2\/parts\/438"}],"metadata":[{"href":"https:\/\/pressbooks.bccampus.ca\/dcbiol2200\/wp-json\/pressbooks\/v2\/chapters\/445\/metadata\/"}],"wp:attachment":[{"href":"https:\/\/pressbooks.bccampus.ca\/dcbiol2200\/wp-json\/wp\/v2\/media?parent=445"}],"wp:term":[{"taxonomy":"chapter-type","embeddable":true,"href":"https:\/\/pressbooks.bccampus.ca\/dcbiol2200\/wp-json\/pressbooks\/v2\/chapter-type?post=445"},{"taxonomy":"contributor","embeddable":true,"href":"https:\/\/pressbooks.bccampus.ca\/dcbiol2200\/wp-json\/wp\/v2\/contributor?post=445"},{"taxonomy":"license","embeddable":true,"href":"https:\/\/pressbooks.bccampus.ca\/dcbiol2200\/wp-json\/wp\/v2\/license?post=445"}],"curies":[{"name":"wp","href":"https:\/\/api.w.org\/{rel}","templated":true}]}}