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Aswathi P

liver transplantation

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1 TERM PAPER ON LIVER TRANSPLANTATION Submitted by, Submitted to, Aswathi. P Mrs. Resmi. G 1st yr Msc Nursing Lecturer Al-shifa college of Nursing Al-shifa college of Nursing Perinthalmanna Perinthalmanna Submitted on: 17 -08-2015
2 INDEX Sl No Content Page No 1 Introduction 2 Anatomy and physiology of liver
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4 INTRODUCTION Liver transplantation or hepatic transplantation is the replacement of a diseased liver with some or all of a healthy liver from another person (allograft). The most commonly used technique is orthotopic transplantation, in which the native liver is removed and replaced by the donor organ in the same anatomic location as the original liver. Liver transplantation is a viable treatment option for end-stage liver disease and acute liver failure. Typically three surgeons and two anesthesiologists are involved, with up to four supporting nurses. The surgical procedure is very demanding and ranges from 4 to 18 hours depending on outcome. Numerous anastomoses and sutures, and many disconnections and reconnections of abdominal and hepatic tissue, must be made for the transplant to succeed, requiring an eligible recipient and a well-calibrated live or cadaveric donor match ANATOMY AND PHYSIOLOGY OF LIVER
5 The liver is the largest solid organ in the body. In adults, the liver can weigh up to 1.5 kilograms (kg). It is in the upper-right abdomen, just under the rib cage and below the diaphragm (the thin muscle below the lungs and heart that separates the chest cavity from the abdomen). The liver is part of the digestive system. Structure LOBES External Structure The liver is the largest gland in the body weighing about 1.4 kg in an adult. It is situated under the diaphragm in the upper abdominal cavity and is held in place by several ligaments. It is a reddish-brown colour and comprises of four anatomical lobes. When viewed from the front, the dominant left and right lobes can be seen which are separated by the falciform ligament. Situated in a depression on the posterior surface of the liver is the gall bladder, a pear-shaped sac which stores bile synthesised by the liver. The liver performs many vital metabolic functions. It has the ability to store and metabolise useful substances such as nutrients, but it breaks down or detoxifying harmful substances to render them inert and less harmful. The liver has 2 main lobes: the larger right lobe and the smaller left lobe. Each lobe is divided into segments.
6 The lobes are separated by a band of tissue called the falciform ligament (also called the broad ligament), which helps attach the liver to the diaphragm. A layer of connective tissue, called Glisson’s capsule or the capsule, covers the liver. Blood Supply The liver receives a blood supply from two sources. The first is the hepatic artery which delivers oxygenated blood from the general circulation. The second is the hepatic portal vein delivering deoxygenated blood from the small intestine containing nutrients. The blood flows through the liver tissue to the hepatic cells where many metabolic functions take place. The blood drains out of the liver via the hepatic vein. The liver tissue is not vascularised with a capillary network as with most other organs, but consists of blood filled sinusoids surrounding the hepatic cells. Unlike most other organs, the liver has 2 major sources of blood:  portal vein – carries blood from the digestive system to the liver o Approximately 75% of the liver’s blood supply comes from the portal vein.  hepatic artery – supplies the liver with oxygen-rich blood from the heart
7 Most of the blood is removed from the liver through 3 hepatic veins (the right, middle and left hepatic veins) found inside the liver. Hepatic portal vein . "Portal vein" redirects here. For a vein that connects two systems of capillary beds, see portal venous system. The hepatic portal vein is a blood vessel that conducts blood from the gastrointestinal tract and spleen to the liver. This blood is rich in nutrients that have been extracted from food, and the liver processes these nutrients; it also filters toxins that may have been ingested with the food. The liver receives about 75% of its blood through the hepatic portal vein, with the remainder coming from the hepatic artery proper. The blood leaves the liver to the heart in the hepatic veins.
8 The hepatic portal vein is not a true vein, because it conducts blood to capillary beds in the liver and not directly to the heart. It is a major component of the hepatic portal system, one of only two portal venous systems in the body – with the hypophyseal portal system being the other. The hepatic portal vein is usually formed by the confluence of the superior mesenteric and splenic veins and also receives blood from the inferior mesenteric, gastric, and cystic veins. Conditions involving the hepatic portal vein cause considerable illness and death. An important example of such a condition is elevated blood pressure in the hepatic portal vein. This condition, called portal hypertension, is a major complication of cirrhosis Structure Tributaries of the hepatic portal vein[1]  Splenic vein  Superior mesenteric vein  Inferior mesenteric vein  Gastric veins  Cystic vein Measuring approximately 8 cm (3 inches) in adults, the hepatic portal vein is located in the right upper quadrant of the abdomen, originating behind the neck of the pancreas. In most individuals, the hepatic portal vein is formed by the union of the superior mesenteric vein and the splenic vein. For this reason, the hepatic portal vein is occasionally called the splenic-mesenteric confluence. Occasionally, the hepatic portal vein also directly communicates with the inferior mesenteric vein, although this is highly variable. Other tributaries of the hepatic portal vein include the cystic and gastric veins. Immediately before reaching the liver, the portal vein divides into right and left. It ramifies further, forming smaller venous branches and ultimately portal venules. Each portal venule courses alongside a hepatic arteriole and the two
9 vessels form the vascular components of the portal triad. These vessels ultimately empty into the hepatic sinusoids to supply blood to the liver. Portacaval anastomoses The portal venous system has several anastomoses with the systemic venous system. In cases of portal hypertension these anastamoses may become engorged, dilated, or varicosed and subsequently rupture. new Accessory hepatic portal veins Accessory hepatic portal veins are those veins that drain directly into the liver without joining the hepatic portal vein. These include the paraumbilical veins as well as veins of the lesser omentum, falciform ligament, and those draining the gallbladder wall. Function The hepatic portal vein and hepatic arteries form the liver's dual blood supply. Approximately 75% of hepatic blood flow is derived from the hepatic portal vein, while the remainder is from the hepatic arteries. Unlike most veins, the hepatic portal vein does not drain into the heart. Rather, it is part of a portal venous system that delivers venous blood into another capillary system, namely the hepatic sinusoids of the liver. In carrying venous blood from the gastrointestinal tract to the liver, the hepatic portal vein accomplishes two tasks; namely, it supplies the liver with metabolic substrates and it ensures that substances ingested are first processed by the liver before reaching the systemic circulation. This accomplishes two things. First, possible toxins that may be ingested can be detoxified by the hepatocytes before they are released into the systemic circulation. Second, the liver is the first organ to absorb nutrients just taken in by the intestines. After draining into the liver sinusoids, blood from the liver is drained by the hepatic vein. Common hepatic artery The common hepatic artery (CHA) is a terminal branch of the coeliac artery.
10 The CHA is a terminal branch of the coeliac artery, it passes to the right in the lesser sac, and enters the lesser omentum to pass slightly upwards towards the porta hepatis. It gives off the right gastric artery that runs along the lesser curvature of the stomach to anastomose with the left gastric artery. The common hepatic artery then bifurcates into the gastroduodenal artery and proper hepatic artery. Branches  right gastric artery  proper hepatic artery  gastroduodenal artery Variation in hepatic arterial anatomy is seen in 40-45% of people. Classic branching of the common hepatic artery from the coeliac artery, and the proper hepatic artery into right and left hepatic arteries to supply the entire liver, is seen in only 55-60%. Variation in hepatic arterial anatomy is seen in 40-45% of people. Classic branching of the common hepatic artery from the coeliac artery, and the proper hepatic artery into right and left hepatic arteries to supply the entire liver, is seen in 55-60% of the population. In general, the common hepatic artery may arise from the abdominal aorta or superior mesenteric artery (SMA) and all or part of the right and left hepatic arteries may arise from (be replaced to) other vessels. The two most common variants are:  right hepatic artery replaced to the SMA  left hepatic artery replaced to the left gastric artery Another common finding, though not considered a variant by many authors, is trifurcation of the common hepatic artery into right hepatic artery, left hepatic artery and gastroduodenal artery (GDA). With this branching pattern there is no proper hepatic artery.
11 Variant anatomy Common hepatic artery  from aorta: 2%  from SMA: 2%  trifurcation into RHA, LHA and GDA: ~6% (range 4-8%) Right hepatic artery (RHA)  from coeliac artery: ~2.5% (range 1-4%)  from SMA: ~12.5% (range 9-15%)  accessory RHA from SMA: ~4% (range 1-7%) Left hepatic artery (LHA)  from left gastric artery (LGA): ~7.5% (range 4-11%)  accessory LHA from LGA: ~7.5% (range 4-11%) Right and left hepatic arteries  RHA from SMA and LHA from LGA: ~1% (range 0.5-2%)  accessory RHA and LHA: 1% Classification Another classification method is the one described by Michel et al in 1955 6  I: standard anatomy ~60% (range 55-61%)  II: replaced LHA ~7.5% (range 3-10%)  III: replaced RHA ~10% (range 8-11 %)  IV: replaced RHA and LHA ~1%  V: accessory LHA from LGA ~10% (range 8-11%)  VI: accessory RHA from SMA ~5% (range 1.5-7%)  VII: accessory RHA and LHA ~1%
12  VIII: accessory RHA and LHA and replaced LHA or RHA ~2.5%  IX: CHA replaced to SMA ~3% (range 2-4.5%)  X: CHA replaced to LGA ~0.5%  unclassified: o CHA separate origin from aorta ~2% o double hepatic artery ~4% o PHA replaced to SMA; GDA origin from aorta <0.5% Internal Structure The liver lobes are made up of microscopic units called lobules which are roughly hexagonal in shape. These lobules comprise of rows of liver cells (hepatocytes) which radiate out from a central point. The hepatic cells are in close contact with blood-filled sinusoids and also lie adjacent to canaliculi into which bile is secreted. Situated around the perimeter of the lobule are branches of the hepatic artery, hepatic portal vein and bile duct. These cluster together at the "corners" of the lobule forming what is called the portal triad. At the mid-point of the lobule is the central vein. Blood flows out of the sinusoids into the central vein and is transported out of the liver. HEPATOCYTES
13 Hepatocytes are the predominant cell type in the liver. An estimated 80% of the liver mass is made of these cells. The hepatocytes are round in shape containing a nucleus and an abundance of cellular organelles associated with metabolic and secretory functions. Organelles include endoplasmic reticulum (smooth and rough) and Golgi apparatus for secretory functions. Also there are high numbers of mitochondria to provide energy to support the many metabolic functions on the liver. Some of the hepatocytes lie adjacent to endothelial cells which form the walls of the sinusoids. These two cell types are separated by small space called the space of Disse. A hepatocyte is a cell of the main parenchymal tissue of the liver. Hepatocytes make up 70-85% of the liver's mass. These cells are involved in:  Protein synthesis  Protein storage  Transformation of carbohydrates  Synthesis of cholesterol, bile salts and phospholipids  Detoxification, modification, and excretion of exogenous and endogenous substances  Initiation of formation and secretion of bile Structure The typical hepatocyte is cubical with sides of 20-30 µm, (in comparison, a human hair has a diameter of 17 to 180 µm).[1]The typical volume of a hepatocyte is 3.4 x 10−9 cm3.[2] Smooth endoplasmic reticulum is abundant in hepatocytes, whereas most cells in the body have only small amounts.[3] Histology Hepatocytes display an eosinophilic cytoplasm, reflecting numerous mitochondria, and basophilic stippling due to large amounts of rough endoplasmic reticulum and free ribosomes. Brown lipofuscin granules are also observed (with increasing age) together with irregular
14 unstained areas of cytoplasm; these correspond to cytoplasmic glycogen and lipid stores removed during histological preparation. The average life span of the hepatocyte is 5 months; they are able to regenerate. Hepatocyte nuclei are round with dispersed chromatin and prominent nucleoli. Anisokaryosis (or variation in the size of the nuclei) is common and often reflects tetraploidy and other degrees of polyploidy, a normal feature of 30-40% of hepatocytes in the adult human liver.[4] Binucleate cells are also common. Hepatocytes are organised into plates separated by vascular channels (sinusoids), an arrangement supported by a reticulin (collagen type III) network. The hepatocyte plates are one cell thick in mammals and two cells thick in the chicken. Sinusoids display a discontinuous, fenestrated endothelial cell lining. The endothelial cells have no basement membrane and are separated from the hepatocytes by the space of Disse, which drains lymph into the portal tract lymphatics. Kupffer cells are scattered between endothelial cells; they are part of the reticuloendothelial system and phagocytose spent erythrocytes. Stellate (Ito) cells store vitamin A and produce extracellular matrix and collagen; they are also distributed amongst endothelial cells but are difficult to visualise by light microscopy. Protein synthesis The hepatocyte is a cell in the body that manufactures serum albumin, fibrinogen, and the prothrombin group of clotting factors (except for Factors 3 and 4). It is the main site for the synthesis of lipoproteins, ceruloplasmin, transferrin, complement, and glycoproteins. Hepatocytes manufacture their own structural proteins and intracellular enzymes. Synthesis of proteins is by the rough endoplasmic reticulum (RER), and both the rough and smooth endoplasmic reticulum (SER) are involved in secretion of the proteins formed. The endoplasmic reticulum (ER) is involved in conjugation of proteins to lipid and carbohydrate moieties synthesized by, or modified within, the hepatocytes.
15 Carbohydrate metabolism The liver forms fatty acids from carbohydrates and synthesizes triglycerides from fatty acids and glycerol. Hepatocytes also synthesize apoproteins with which they then assemble and export lipoproteins (VLDL, HDL). The liver is also the main site in the body for gluconeogenesis, the formation of carbohydrates from precursors such as alanine, glycerol, and oxaloacetate. Lipid metabolism The liver receives many lipids from the systemic circulation and metabolizes chylomicron remnants. It also synthesizes cholesterol from acetate and further synthesizes bile salts. The liver is the sole site of bile salts formation. Detoxification Hepatocytes have the ability to metabolize, detoxify, and inactivate exogenous compounds such as drugs, (drug metabolism), and insecticides, and endogenous compounds such as steroids. The drainage of the intestinal venous blood into the liver requires efficient detoxification of miscellaneous absorbed substances to maintain homeostasis and protect the body against ingested toxins. One of the detoxifying functions of hepatocytes is to modify ammonia into urea for excretion. The most abundant organelle in liver cell is the smooth endoplasmic reticulum. Hepatocyte isolation and culture Primary hepatocytes are commonly used in cell biological and biopharmaceutical research. In vitro model systems based on hepatocytes have been of great help to better understand the role of hepatocytes in (patho)physiological processes of the liver. In addition, pharmaceutical industry has heavily relied on the use of hepatocytes in suspension or culture to explore mechanisms of drug metabolism and even predict in vivo drug metabolism. For these purposes, hepatocytes are
16 usually isolated from animal or human whole liver or liver tissue by collagenase digestion, which is a two-step process. In the first step, the liver is placed in an isotonic solution, in which calcium is removed to disrupt cell-cell tight junctions by the use of a calcium chelating agent. Next, a solution containing collagenase is added to separate the hepatocytes from the liver stroma. This process creates a suspension of hepatocytes, which can be seeded in multi-well plates and cultured for many days or even weeks. For optimal results, culture plates should first be coated with an extracellular matrix (e.g. collagen, Matrigel) to promote hepatocyte attachment (typically within 1-3 hr after seeding) and maintenance of the hepatic phenotype. In addition, and overlay with an additional layer of extracellular matrix is often performed to establish a sandwich culture of hepatocytes. The application of a sandwich configuration supports prolonged maintenance of hepatocytes in culture. Freshly-isolated hepatocytes that are not used immediately can be cryopreserved and stored They do not proliferate in culture. Hepatocytes are intensely sensitive to damage during the cycles of cryopreservation including freezing and thawing. Even after the addition of classical cryoprotectants there is still damage done while being cryopreserved. Nevertheless, recent cryopreservation and resuscitation protocols support application of cryopreserved hepatocytes for most biopharmaceutical application Lobule Activity The hepatic portal vein and hepatic artery deliver oxygen and nutrients into to the blood sinusoids. This close relationship between the hepatocytes and surrounding blood enables many metabolic processes to take place. Blood flows out of the sinusoids into the central vein, removing detoxified substances and metabolic end products. The central vein ultimately reunites with the hepatic vein transporting these substances out of the liver. Bile that is produced by the hepatocytes drains into tiny canals called bile canaliculi (singular canaliculus). These drain into bile ducts located around the lobule perimeter.
17 Understanding First Pass Metabolism Drugs may be given in a number of ways. Oral administration is the most common and the easiest way to give a drug. The amount of drug reaching the general circulation will depend on a number of factors. Drug Absorption The drug is absorbed from the GI tract and passes via the portal vein into the liver where some drugs are metabolised. Sometimes the result of first pass metabolism means that only a proportion of the drug reaches the circulation. First pass metabolism can occur in the gut and the liver. For example, first pass metabolism occurs in the gut for benzylpenicillin and insulin and in the liver for propranolol, lignocane, chloromethiasole and GTN. Bypassing First Pass Metabolism Two ways to bypass first pass metabolism involve giving the drug by sublingual and buccal routes. The drugs are absorbed by the oral mucosa in both methods. In sublingual administration the drug is put under the tongue where it dissolves in salivary secretions. Nitroglycerine is administered in this way. In buccal administration the drug is placed between the teeth and the mucous membrane of the cheek. Sublingual and buccal methods both avoid destruction by the GI fluids and first pass effect of the liver Activity In this exercise you need to drag each drug name to the organ where it undergoes first pass metabolism.
18 Bile ducts The liver, gallbladder and small intestine are connected by a series of thin tubes called ducts. One function of the liver cells (hepatocytes) is to produce bile. Bile is a yellow-green fluid that helps digest fat. Bile travels through a series of ducts in the liver to the small intestine or to the gallbladder for storage.  Bile is collected from the liver in hepatic ducts.  Two hepatic ducts leave the liver and join to form the common hepatic duct.  The cystic bile duct leaves the gallbladder and joins the common hepatic duct to form the common bile duct.  The common bile duct empties bile into the duodenum (the first part of the small intestine). o If there is food in the small intestine, the bile will flow directly from the liver, through the common hepatic duct and common bile duct into the duodenum to help with digestion. o If the small intestine is empty, the bile will collect in the common bile duct until it backs up the cystic duct and into the gallbladder, where it is stored until it is needed.
19 FUNCTIONS OF LIVER The liver performs many important functions in the body. The liver:  produces bile o Bile is made up of bile salts, cholesterol, bilirubin, electrolytes and water. o Bile helps the small intestine digest fat and absorb fats, cholesterol and some vitamins.  absorbs and uses (metabolizes) bilirubin o Bilirubin is a yellow-red substance formed from hemoglobin when red blood cells (RBCs) break down. (Hemoglobin is a protein found in RBCs that carries oxygen and gives blood its red colour.) o The iron from the hemoglobin is stored in the liver or used by the bone marrow to produce new RBCs.  helps the body make blood-clotting (coagulation) factors o The body needs bile, which is produced by the liver, to absorb vitamin K. The body uses vitamin K to produce blood-clotting factors. o If the liver does not produce enough bile, the body will absorb less vitamin K and produce less blood-clotting factors.
20  helps the body metabolize fat o Bile breaks down fat from food to make it easier to digest.  metabolizes protein o Liver enzymes break down proteins from food so they can be digested and used by the body.  metabolizes carbohydrates o The body breaks down carbohydrates from food into glycogen, which is stored in the liver. The liver breaks down glycogen into glucose and releases it into the blood to maintain normal blood sugar levels.  stores vitamins and minerals o Vitamins A, D, E, K and B12 are stored in the liver. o The liver stores iron in the form of ferritin, which it releases so the body can make new RBCs. o The liver stores and releases copper as needed.  filters the blood o The liver filters certain substances from the blood so that they don’t build up and cause damage. These substances can come from within or outside the body.  Substances that come from within the body include hormones, such as estrogen, aldosterone and diuretic hormone.  Substances that come from outside the body include alcohol and other drugs, such as amphetamines, barbiturates and steroids. Regeneration The liver has the unique ability to regrow parts that have been removed so that it can continue to function in the body.  Up to 80% of liver function can be maintained even after a large part of the liver has been removed.  The regeneration process continues over several months until the missing liver tissue is replaced.
21  The length of time for this process depends on the person’s age, nutrition, if there is any liver damage and how much liver was removed. Transplant surgeons, hepatologists and other researchers are developing liver cell-based regenerative therapies for patients who'd otherwise need whole-liver transplants. The liver has the greatest regenerative capacity of any organ in the body. Liver regeneration has been recognized for many years, dating all the way back to Prometheus in ancient Greek mythology. When the liver is injured beyond its ability to regenerate itself, a liver transplant is the treatment of choice. Transplants are used to treat a wide range of liver conditions, including liver cancer, cirrhotic liver disease, acute liver failure and genetic liver disorders. But as is true for most donor organs, livers are in short supply — the number of people awaiting new livers far exceeds the number of donor livers available. Focus areas Mayo Clinic transplant surgeons, hepatologists and other researchers in the Center for Regenerative Medicine are developing and refining a number of regenerative liver therapies for patients who today must wait for whole-liver transplants.  Living-donor transplants. Liver cancer and advanced cases of cirrhotic liver disease may require liver transplants. Given the shortage of whole livers for transplant, Mayo Clinic's campuses in Minnesota and Arizona have been performing living-donor liver transplants for more than a decade — together, they represent one of the largest such programs in the country. In a living-donor transplant, a portion of a donor's liver is removed and used to replace a patient's diseased liver. After surgery, the donor's liver regenerates back to full size, while the patient's new liver also grows to a normal size.
22 As the safety of living donors is paramount to the success of this program, Mayo Clinic researchers have conducted a long-term assessment of donor outcomes, such as liver regeneration and mental and physical well-being. The study's results were very reassuring, as they showed that Mayo living liver donors do well after donation.  Liver assist devices. Several types of bioartificial livers — devices that perform liver functions for patients with liver failure — have been developed in recent years. These devices support patients as their livers recover from disease or as they await liver transplants. Center for Regenerative Medicine researchers are refining their own version of a bioartificial liver, known as the Spheroid Reservoir Bioartificial Liver. This device contains pig liver cell (hepatocyte) spheroids, which replace a patient's liver function. Research into using human hepatocytes in the device is underway. Read more about Mayo Clinic's bioartificial liver in Discovery's Edge, Mayo's research magazine.  Patient-specific liver cell transplantation. Existing liver cell transplantation procedures used to treat genetic liver diseases do not use patient-specific cells and require immunosuppression. Center for Regenerative Medicine researchers are developing an individualized approach to liver cell transplantation that uses the patient's own cells. With this approach, cells from the patient would be collected, converted to induced pluripotent stem cells in the laboratory and subsequently transformed into hepatocyte-like cells. During this process, gene therapy would be used to correct the genetic defect responsible for the patient's disease. The hepatocyte-like cells would then be transplanted into the liver of a bioengineered pig, where they'd grow into fully functioning, patient-specific human adult hepatocytes that could be transplanted into the patient to regenerate the liver. As the new hepatocytes were originally derived from the patient's own cells, no immunosuppressive drugs would be needed.
23 Processing nutrients absorbed from digestive tract The liver converts glucose into glycogen, its storage form. This glycogen can then be transformed back into glucose if the body needs energy. The fatty acids produced by the digestion of lipids are used to synthesize cholesterol and other substances. The liver also has the ability to convert certain amino acids into others. Despite the wide variety of functions performed by the liver, there is very little specialization among hepatocytes (liver cells). Aside from the macrophages called Kupffer cells in the liver, hepatocytes all seem to be able to perform the same wide variety of tasks. One of the liver's most interesting abilities is self-repair and the regeneration of damaged tissues. In clearing the body of toxins, the liver is damaged by exposure to harmful substances, demonstrating why this capability is important. It also gives hope that if a failing liver can be supported for a certain period of time, it might regenerate and allow the patient to survive and regain a normal life. Hemostasis Glucose Proteins fat and cholesterol Hormones vitamins, in particular fat-soluble ones (A, D, E, K) Synthesis proteins including the clotting factors (~50g/day) bile acids (important in fat digestion) heparin (anti-coagulant) somatomedins (homones that promote growth in bone, soft tissues) Estrogen angiotensinogen Cholesterol acute phase proteins Storage vitamins Glycogen Cholesterol
24 iron, copper Fats Excretion cholesterol, bile acids, phospholipids Bilirubin Drugs poisons including heavy metals Hormones Filtering Poisons nutrients including amino acids, sugars, and fats bilirubin, bile acids IgA Drugs dead or damaged cells in circulatory system Immune excretes IgA into digestive tract Kupffer cells (macrophages) filter out antigens
25 HISTORY OF LIVER TRANSPLANTATION The first human liver transplant was performed in 1963 by a surgical team led by Dr. Thomas Starzl of Denver, Colorado, United States. Dr. Starzl performed several additional transplants over the next few years before the first short-term success was achieved in 1967 with the first one-year survival post transplantation. Despite the development of viable surgical techniques, liver transplantation remained experimental through the 1970s, with one year patient survival in the vicinity of 25%. The introduction of cyclosporin by Sir Roy Calne, Professor of Surgery Cambridge, markedly improved patient outcomes, and the 1980s saw recognition of liver transplantation as a standard clinical treatment for both adult and pediatric patients with appropriate indications. Liver transplantation is now performed at over one hundred centers in the US, as well as numerous centres in Europe and elsewhere. One-year patient survival is 80– 85%, and outcomes continue to improve, although liver transplantation remains a formidable procedure with frequent complications. The supply of liver allografts from non-living donors is far short of the number of potential recipients, a reality that has spurred the development of living donor liver transplantation. The first altruistic living liver donation in Britain was performed in December 2012 in St James University Hospital Leeds. DEFINITION A liver transplant is a surgical procedure to remove a diseased liver and replace it with a healthy liver from a donor. Most liver transplant operations use livers from deceased donors, though a liver may also come from a living donor. PURPOSE A liver transplant is needed when the liver's function is reduced to the point that the life of the patient is threatened
26 DEMOGRAPHICS Compared to whites, those with African-American, Asian, Pacific Islander, or Hispanic descent are three times more likely to suffer from end-stage renal disease (ESRD). Both children and adults can suffer from liver failure and require a transplant. Patients with advanced heart and lung disease, who are human immunodeficiency virus (HIV) positive, and who abuse drugs and alcohol are poor candidates for liver transplantation. Their ability to survive the surgery and the difficult recovery period, as well as their long-term prognosis, is hindered by their conditions. INDICATIONS Liver transplantation is potentially applicable to any acute or chronic condition resulting in irreversible liver dysfunction, provided that the recipient does not have other conditions that will preclude a successful transplant. Uncontrolled metastatic cancer outside liver, active drug or alcohol abuse and active septic infections are absolute contraindications. While infection with HIV was once considered an absolute contraindication, this has been changing recently. Advanced age and serious heart, pulmonary or other disease may also prevent transplantation (relative contraindications). Most liver transplants are performed for chronic liver diseases that lead to irreversible scarring of the liver, or cirrhosis of the liver. Some centers use the Milan criteria to select patients with liver cancers for liver transplantation Cholestatic Diseases: primary biliary cirrhosis, sclerosing cholangitis, secondary biliary cirrhosis, biliary atresia, cystic fibrosis Chronic Hepatitis: hepatitis B, hepatitis C, hepatitis D, autoimmune chronic active hepatitis, cryptogenic cirrhosis, chronic drug toxicity or toxin exposure Alcoholic Cirrhosis: Patients with alcoholic cirrhosis are considered for transplant if they meet current criteria for abstinence and rehabilitation.  Abstinence of alcohol for six months.  Ongoing participation in formal alcohol treatment program.
27  Presence of adequate psychosocial supports as determined by social service and psychiatry consultants. Patients who do not meet the above criteria at the time of referral will be given the opportunity to fulfill these criteria and undergo re-evaluation. Formal input from the psychiatry staff is required to assess the risk of return to alcohol use following liver transplantation.  Metabolic Diseases: hemochromatosis, Wilson's disease, Alpha-1-antitrypsin deficiency, glycogen storage disease, tyrosinemia, familial amyloidotic polyneuropathy, other metabolic disorders treatable by liver replacement.  Fulminant Acute Hepatic Necrosis: viral hepatitis, drug toxicity, toxin, Wilson's disease.  Primary Hepatic Tumors: selected patients with hepatocellular carcinoma. Milan criteria In transplantation medicine, the Milan criteria are applied as a basis for selecting patients with cirrhosis and hepatocellular carcinoma for liver transplantation. The Milan criteria state that a patient is selected for transplantation when he or she has:  one lesion smaller than 5 cm  up to 3 lesions smaller than 3 cm  no extrahepatic manifestations  no vascular invasion CONTRAINDICATIONS While each patient is evaluated on an individual basis, the presence of one or more of the following will frequently preclude acceptance as a candidate for liver transplantation:  HIV infection  Active alcohol or substance abuse  Systemic infections
28  Life-limiting co-existing medical conditions: advanced heart, lung or neurologic conditions.  Uncontrolled psychiatric disorder  Inability to comply with pre- and post-transplant regimens TYPES OF LIVER TRANSPLANTATION METHODS Liver transplant is performed in people who have severely damaged livers or have developed liver failure. These people are usually put on waiting lists for the donor livers to be available for transplant. As soon as a suitable liver is available the next person on the waiting list is contacted. The new liver has to match the recipient’s blood group, tissue type and size. 1-6 From the time the transplant center contacts a potential recipient he or she is advised not to take anything by mouth (not even water) so as to be ready for the operation as early as possible. A liver transplant may be undertaken as soon as the general health check-up of the patient including heart and lung functions are assessed. This surgery is a major one and requires general anesthesia. For general anesthesia to be administered the person needs to remain on an empty stomach and heart and lung functions need to be assessed. TYPES OF LIVER TRANSPLANT There are three different types of liver transplant that may be offered to a person:  Orthotopic transplant or transplant of a liver from a recently deceased donor  A living donor transplant  A split type of liver transplant Orthotopic transplant An orthotopic transplant is the most common type of liver transplant. The whole liver is taken from a recently deceased donor. This is usually from a donor who has pledged his or her organs
29 for donation prior to death and has not transmissible illness or cancers that may be transmitted to the recipient. For the surgery the surgeon makes an incision over the abdomen and removes the diseased liver. The donor liver will then be put in position and all the blood vessels and bile ducts would be connected. The incision is then closed with dissolvable stitches or surgical staples. Drainage tubes are attached to drain away extra fluids. These are left for several days after surgery. Patient is then shifted to the intensive care unit for recovery. Living donor transplant Living donor transplant means the donor is a willing living person. The donor has the operation first in which the surgeon removes either the left or right side (lobe) of their liver. Right lobe transplants are usually recommended for adults while left lobes are used in children. This is because the right lobe is bigger and better suited for adults, while the left lobe is smaller and better suited for children. The recipient is then opened up and the diseased liver is removed. Then the part of the liver taken from the donor is replaced making the connections with blood vessels and bile ducts as in an orthotopic transplant. Following transplantation, the transplanted lobe will quickly regenerate itself. Even for the donor the removed portion of the liver grows back. In the recipient the new lobe usually grows to 85% of the original liver size within a week. Split type of liver transplant Split donation involves transplantation of a liver from a recently deceased individual to two recipients. This is possible if the next suitable recipients are an adult and a child. The donated liver will be split into the left and right lobes. The adult normally receives the larger right lobe and the child will receive the smaller left lobe.
30 As with living donor transplants, the transplanted portions of the liver grow back to the original size by regeneration. This method benefits two persons at a time. Auxiliary liver transplantation Auxiliary liver transplantation is a variety of liver transplantation where the recipient’s own liver is not completely removed. Its purpose is to retain the native liver in case of spontaneous recovery or if there is a potential for future gene therapy in cases of hereditary or metabolic liver diseases (except primary oxalosis, Wilson’s disease or tyrosinaemia in which there is a risk of cancer in the residual liver). Living donor liver transplantation (ldlt) has emerged in recent decades as a critical surgical option for patients with end stage liver disease, such as cirrhosis and/or hepatocellular carcinoma often attributable to one or more of the following: long-term alcohol abuse, long-term untreated hepatitis c infection, long-term untreated hepatitis b infection. The concept of ldlt is based on (1) the remarkable regenerative capacities of the human liver and (2) the widespread shortage of cadaveric livers for patients awaiting transplant. In ldlt, a piece of healthy liver is surgically removed from a living person and transplanted into a recipient, immediately after the recipient’s diseased liver has been entirely removed. Historically, ldlt began as a means for parents of children with severe liver disease to donate a portion of their healthy liver to replace their child's entire damaged liver. The first report of successful ldlt was by dr. Christoph broelsch at the university of chicago medical center in november 1989, when two-year-old alyssa smith received a portion of her mother's liver.[5] surgeons eventually realized that adult-to-adult ldlt was also possible, and now the practice is common in a few reputable medical institutes. It is considered more technically demanding than even standard, cadaveric donor liver transplantation, and also poses the ethical problems underlying the indication of a major surgical operation (hemihepatectomy or related procedure) on a healthy human being. In various case series, the risk of complications in the donor is around 10%, and very occasionally a second operation is needed. Common problems are biliary fistula, gastric stasis and infections; they are more common after removal of the right lobe of the liver. Death after ldlt has been reported at 0% (japan), 0.3% (usa) and <1% (europe), with risks likely
31 to decrease further as surgeons gain more experience in this procedure.[6] since the law was changed to permit altruistic non-directed living organ donations in the uk in 2006, the first altruistic living liver donation took place in britain in december 2012.[7] In a typical adult recipient ldlt, 55 to 70% of the liver (the right lobe) is removed from a healthy living donor. The donor's liver will regenerate approaching 100% function within 4–6 weeks, and will almost reach full volumetric size with recapitulation of the normal structure soon thereafter. It may be possible to remove up to 70% of the liver from a healthy living donor without harm in most cases. The transplanted portion will reach full function and the appropriate size in the recipient as well, although it will take longer than for the donor.[8] Living donors are faced with risks and/or complications after the surgery. Blood clots and biliary problems have the possibility of arising in the donor post-op, but these issues are remedied fairly easily. Although death is a risk that a living donor must be willing to accept prior to the surgery, the mortality rate of living donors in the united states is low. The ldlt donor's immune system does diminish as a result of the liver regenerating, so certain foods which would normally cause an upset stomach could cause serious illness. DIAGNOSIS/PREPARATION The liver starts to fail only when more than half of it is damaged. Thus, once a person demonstrates symptoms of liver failure, there is not much liver function left. Signs and symptoms of liver failure include:  jaundice  muscle wasting (loss of muscle)  forgetfulness, confusion, or coma  fatigue  itching  poor blood clotting  build-up of fluid in the stomach (ascites)  infections  bleeding in the stomach
32 A doctor will diagnose liver disease; a liver specialist, a transplant surgeon, and other doctors will have to be consulted, as well, before a patient can be considered for a liver transplant. Before transplantation takes place, the patient is first determined to be a good candidate for transplantation by going through a rigorous medical examination. Blood tests, consultations, and x rays will be needed to determine if the patient is a good candidate. Other tests that may be conducted are: computed tomography (CAT or CT) scan, magnetic resonance image (MRI), ultrasound, routine chest x ray , endoscopy, sclerotherapy and rubber-band ligation, transjugular intrahepatic portosystemic shunt (TIPS), creatinine clearance, cardiac testing (echocardiogram [ECHO]) and/or electrocardiogram [EKG or ECG]), and pulmonary function test [PFTs]), liver biopsy , and nutritional evaluation. A dietitian will evaluate the patient's nutritional needs and design an eating plan. Since a patient's emotional state is as important as their physical state, a psychosocial evaluation will be administered. Once test results are reviewed and given to the liver transplant selection committee, the patient will be assessed for whether he or she is an appropriate candidate. Some patients are deemed too healthy for a transplant and will be followed and retested at a later date if their liver gets worse. Other patients are determined to be too sick to survive a transplant. The committee will not approve a transplant for these patients. Once a patient is approved, they will be placed on a waiting list for a donor liver. When placed on the waiting list, a patient will be given a score based on the results of the blood tests. The higher a patient's score, the sicker the patient is. This results in the patient earning a higher place on the waiting list. Suitable candidates boost their nutritional intakes to ensure that they are as healthy as possible before surgery. Drugs are administered that will decrease organ rejection after surgery. The medical committee consults with the patient and family, if available, to explain the surgery and any potential complications. Many problems can arise during the waiting period. Medicines should be changed as needed, and blood tests should be done to assure a patient is in the best possible health for the transplant surgery. Psychological counseling during this period is recommended, as well. When a donor is found, it is important that the transplant team be able to contact the patient. The patient awaiting the organ must not eat or drink anything from the moment the hospital calls. On
33 the other hand, the liver may not be good enough for transplantation. Then, the operation will be cancelled, although this does not happen often. Liver donor requirements CT scan performed for evaluation of a potential donor. The image shows an unusual variation of hepatic artery. The left hepatic artery supplies not only left lobe but also segment 8. The anatomy makes right lobe donation impossible. Even used as left lobe or lateral segment donation, it would be very technically challenging in anastomosing the small arteries. Any member of the family, parent, sibling, child, spouse or a volunteer can donate their liver. The criteria for a liver donation include:  Being in good health  Having a blood type that matches or is compatible with the recipient's, although some centres now perform blood group incompatible transplants with special immuno suppression protocols  Having a charitable desire of donation without financial motivation  Being between 18 and 60 years old  Being of similar or bigger size than the recipient  Before one becomes a living donor, the donor must undergo testing to ensure that the individual is physically fit. Sometimes ct scans or mris are done to image the liver. In most cases, the work up is done in 2–3 weeks. Benefits There are several advantages of living liver donor transplantation over cadaveric donor transplantation, including:  Transplant can be done on an elective basis because the donor is readily available  There are fewer possibilities for complications and death than there would be while waiting for a cadaveric organ donor  Because of donor shortages, UNOS has placed limits on cadaveric organ allocation to foreigners who seek medical help in the USA. With the availability of living donor
34 transplantation, this will now allow foreigners a new opportunity to seek medical care in the USA. Controversy over eligibility for alcoholics The high incidence of liver transplants given to those with alcoholic cirrhosis has led to a recurring controversy regarding the eligibility of such patients for liver transplant. The controversy stems from the view of alcoholism as a self-inflicted disease and the perception that those with alcohol-induced damage are depriving other patients who could be considered more deserving.[14] It is an important part of the selection process to differentiate transplant candidates who suffer from alcoholism as opposed to those who were susceptible to moderate non- dependent alcohol use. The latter who retain control of alcohol use have a good prognosis following transplantation. Once a diagnosis of alcoholism has been established, however, it is necessary to assess the likelihood of future sobriety Preservation of the liver before transplantation The OrganOx Metra device is capable of maintaining the liver outside of the body for longer periods than traditional preservation of the organ on ice (which usually can only be done for about 12 hours- 20 at most- before it is damaged unfit for transplantation). The device, which was invented and tested (in two liver transplantations at the hospital) by a team from Oxford University and King's College Hospital, could be ready for use in 2014 after a pilot trial of 20 more transplantations. However this device has not shown that it is superior to cold static storage or hypothermic machine perfusion that has been used successfully at Columbia University and should be commercially available in 2015. DONOR PREPARATION Laboratory Studies These are oriented toward determining the etiology of the disease, excluding HIV and other infections that may compromise a successful LT, and screening for the presence of tumors. The following laboratory tests are those most commonly ordered during a LT evaluation:
35  Liver function tests, total protein, albumin  Hepatitis screen (A, B, C)  Serologies - Cytomegalovirus (CMV), herpes simplex virus (HSV), Epstein-Barr virus (EBV), HIV  Tumor markers  Alpha-fetoprotein, cholinesterase  Arterial blood gases  Others (selective) - Carbohydrate antigen 19-9, cancer antigen 125 Evaluation and workup of prospective liver transplant recipients is as follows: The first step in the process of evaluating a potential candidate for LT is to determine the severity of the liver disease by clinical evaluation. In addition, an objective assessment, to include a comprehensive laboratory and radiological evaluation, is undertaken. The goal of this evaluation is 3-fold. First, it must establish a diagnosis of ESLD; second, it must exclude any absolute or relative contraindication to the proposed procedure; finally, it must assess the suitability and degree of illness of each patient to better allocate resources and optimize survival. The specific tests are outlined below. Once the results are received, specific consultations are sought to clear the patient for LT. Mandatory consultations and clearances are as follows:  Cardiopulmonary clearance  Psychiatrist and social worker consultations  Financial clearance  Nephrologist, infectious diseases specialist, or dentist, as needed One of the most important tools in this scheme is the Child-Turcotte-Pugh (CTP) scoring system, which is the system most widely used to grade the severity of liver disease. A patient is considered to be Child class A if he or she has fewer than 7 points, Child class B if he or she has 7-9 points, and Child class C if he or she has more than 10 points. For listing purposes, a patient must have at least 7 points (ie, be at least a Child class B), according to the minimal listing criteria consensus initially developed when the CTP score was the basis for organ allocation.
36 Today, the CTP score is no longer the basis for organ allocation because this is now based on the Model for End-Stage Liver Disease (MELD) scoring system (see below; also see the MELD Score calculator). Table. CTP Scoring System for Assessment of Severity of Disease (with respect to listing) (Open Table in a new window) Parameter 1 Point 2 Points 3 Points Encephalopathy None Grade 1-2 Grade 3-4 Ascites None Medically controlled Uncontrolled Albumin, g/dL >3.5 2.8-3.5 < 2.8 Bilirubin, mg/dL < 2 2-3 > 3 International normalized ratio < 1.7 1.7-2.3 >2.3 Although a good effort to grade severity of disease, this classification does not reflect the severity of disease in persons with cholestatic diseases, such as primary biliary cirrhosis or primary sclerosing cholangitis (PSC), because the bilirubin limits are significantly higher for these conditions and the other manifestations are not present until very late in the disease. Thus, recent developments in the allocation system are investigating the MELD scoring system as the new basis for organ allocation. Because of the many factors (ie, increasing number of deaths while on liver waiting list, inability to accurately categorize liver patients according to severity of liver disease using the partially subjective CTP classification, reports suggesting that waiting time correlates poorly with death while on the waiting list), a consensus opinion emerged that a revised allocation scheme was needed. The new liver allocation system implemented by the Organ Procurement Transplantation Network in February 2002 is based primarily on the severity of liver disease as assessed by the MELD and Pediatric End-Stage Liver Disease (PELD) survival models for all patients with chronic liver disease.
37 The MELD score is based on 3 biochemical variables, (1) serum bilirubin, (2) serum creatinine, and (3) international normalized ratio, and has been shown in retrospective and prospective studies to be highly predictive of 3-month mortality in patients with chronic liver disease. Similarly, the PELD model for pediatric patients (see below; also see the PELD Score calculator) was developed based on analyses of data from the Study of Pediatric Liver Transplantation database and has been shown retrospectively to be predictive of waiting list mortality in pediatric patients. Model for End-Stage Liver Disease (MELD) scoring system:  Serum creatinine (Log e value) 0.957 o The maximum serum creatinine considered within the MELD score equation is 4.0 mg/dL (ie, for candidates with a serum creatinine >4.0 mg/dL, the serum creatinine level is set to 4.0 mg/dL). o For candidates on dialysis, defined as having 2 or more dialysis treatments within the prior week, or candidates who have received 24 hours of continuous venovenous hemodialysis (CVVHD) within the prior week, the serum creatinine level is automatically be set to 4.0 mg/dL.  Serum bilirubin (Log e value) 0.378  International normalized ratio (INR) (Log e value) 1.120  Using these prognostic factors and regression coefficients, the UNetSM computerized system assigns a MELD score for each candidate based on the following calculation: MELD score = 0.957 x Log e (creatinine mg/dL) + 0. 378 x Log e (bilirubin mg/dL) + 1.120 x Log e (INR) + 0.643. Laboratory values < 1.0 are set to 1.0 for the purposes of the MELD score calculation. [2]  As an example, for a hypothetical candidate with cirrhosis caused by hepatitis C virus who has a serum creatinine concentration of 1.9 mg/dL, a serum bilirubin concentration of 4.2 mg/dL and an INR value of 1.2, the risk score would be calculated as follows: MELD score = (0.957 x Log e 1.9) + (0.378 x Log e 4.2) + (1.120 x Log e 1.2) + 0.643 = 2.0039.  The MELD score for each liver transplant candidate derived from this calculation is rounded to the tenth decimal place and then multiplied by 10. The hypothetical candidate
38 in the example described above, therefore, would be assigned a risk score of 20. The MELD score is limited to a total of 40 points maximum.  Pediatric End-Stage Liver Disease (PELD) scoring system: o Albumin (Loge value) -0.687 o Total bilirubin (Loge value) 0.480 o INR (Loge value) 1.857 o Growth failure (<-2 standard deviations [SD]) 0.667 o Age (< 1 y) 0.436 (Scores for candidates listed for liver transplantation before the candidate’s first birthday continue to include the value assigned for age (< 1 y) until the candidate reaches 24 months of age.) o UNetSM assigns a PELD score for each candidate based on the following calculation: PELD score = 0.436 (age [< 1 y]) – 0.687 x Loge (albumin g/dL) + 0.480 x Loge (total bilirubin mg/dL) + 1.857 x Loge (INR) + 0.667 (growth failure [<-2 SD present]). Laboratory values < 1.0 are set to 1.0 for the purposes of the PELD score calculation.[2] Growth failure is calculated based on age and gender using the current CDC growth chart. o This is a much more precise method of ranking patients; therefore, patients most in need will be given the highest priority for donated livers, rather than simply allocating them to patients who have waited longer but who may be much more stable. The MELD policy replaced status 2A, 2B, and 3 with a continuous scale in February 2002 and is the current basis for liver allocation. Neither of these 2 scoring systems favors all patients, specifically patients with HCCs or exceptional cases. Listing of candidates  Once the workup is complete, the patient and all workup results are presented to the candidate selection committee for a decision about the suitability for transplantation. This committee consists of transplantation surgeons, hepatologists, psychiatrists, social work representatives, cardiologists, pulmonologists, anesthesiologists, and, occasionally, the patient's primary care physician.
39  The following questions are posed to the committee before listing the patient for transplantation: o Does the patient need LT as therapy for his or her disease? o Have the indications and contraindications been properly assessed? o What is the surgical risk? o Is the patient's medical condition such that he or she will be able to tolerate the procedure and postoperative course? o What are the chances of recurrent disease affecting graft and patient survival? Volk et al found that the structure of committee meetings varies by center; however, the process is uniform and primarily involves inductive reasoning to review suitability for transplantation. In their observations, patients were excluded if they were too well, too sick, or too old or had nonhepatic comorbid conditions, substance abuse problems, or other psychosocial barriers. Imaging Studies  Radiography (including chest radiography)  Duplex ultrasonography  Angiogram/magnetic resonance angiography (selective)  Abdominal CT scanning  Cardiopulmonary evaluation  Stress thallium scanning, coronary angiography (as indicated)  Echocardiography In a study comparing the performance of imaging techniques for the detection of hepatocellular carcinoma in pre-liver transplant patients with cirrhosis, contrast-enhanced T1-weighted imaging (CE T1WI) outperformed diffusion-weighted MRI (DWI) with regard to per-patient sensitivity, negative predictive value and per-lesion sensitivity. The latter difference, however, was significant only for lesions between 1 and 2 cm, suggesting that DWI is a reasonable alternative to CE T1WI for detection of hepatocellular lesions above 2 cm.
40 Other Tests  Electrocardiography  Pulmonary function testing Diagnostic Procedures  During the workup of these patients, many tests may be ordered. Specific testing is performed on a case-by-case basis.  In the author's experience, most patients undergo both upper and lower GI endoscopies to evaluate for the presence of esophageal or gastric varices or to exclude GI malignancy.  Other common procedures may include paracentesis in patients with ascites, both for diagnostic purposes (eg, to exclude SBP) and for therapeutic intent (eg, alleviation of distention and hepatohydrothorax).  Many patients undergo a TIPS procedure while awaiting LT because of complications that warrant this approach. These conditions include esophageal or gastric variceal bleeding, refractory ascites, and hepatorenal syndrome (HRS). Histologic Findings  Discussion of all the histopathological findings of the various diseases that lead to ESLD is beyond the scope of this article. In general, they can be classified into 3 broad categories: cirrhosis and fibroticlike states, acute hepatic necrosis, and malignancies. How long is the wait?  The length of time a person may wait for a liver transplant varies, depending on the availability of a compatible donor. The time may be as short as several months to a year or as long as four years. As of September 2003, there were 17,327 candidates on the national waiting list, waiting for a liver transplant.
41 LIVER TRANSPLANT PHYSICIANS AND TEAMS The multidisciplinary liver transplant team at Penn Medicine is comprised of specialists who manage patient care at every stage: from the evaluation visit through the transplant procedure and postoperative care. The program's goal is to provide the best care and restore each patient to a full and productive life. While primarily committed to patient care, the liver transplant team is also actively engaged in clinical and laboratory research designed to improve survival and quality of life for transplant recipients. The following members of the liver transplant team are involved in our patients' care throughout the transplant process: Liver Transplant Surgeons Liver Transplant Hepatologists Transplant Coordinators Procurement Coordinators Living Donor Team Living Donor Advocate Social Workers Financial Coordinator Transplant Nutritionist Transplant Pharmacist Transplant Psychiatrist New Patient Referral Intake Coordinator Transplant Outreach & Communication
42 Clinical Director, Abdominal Organ Transplant. TECHNIQUES OF LIVER TRANSPLANT SURGERY The techniques involved in LDLT and DDLT are in principal the same. In an adult to adult LDLT, a segment of liver equivalent to 60% of the total liver mass is removed from the donor. In an adult to child LDLT, only 25% of the liver suffices. In DDLT, the entire liver is removed and usually the whole organ is transplanted into the recipient. However, in certain ideal cases, the deceased donor liver can be “split” and transplanted into two recipients (the smaller piece going to a child and the larger piece going to another child or small adult). During the LDLT donor “hepatectomy” (surgical removal of the liver), extreme care must be taken to minimize blood loss or injury to critical structures such as bile ducts and blood vessels, and the exact anatomy of these structures should be studied as best as possible prior to even starting the operation. A “total hepatectomy” is performed in the case of DDLT and care must be taken not to injure any critical structures and to properly preserve the organ prior to transplant. The organ recovery surgery (previously referred to as “harvesting” but this term has fallen out of favor: “organ retrieval”, “organ recovery” or “organ procurement” are all acceptable alternatives) often involves recovery of multiple organs including heart, lungs, liver, kidneys, pancreas and intestines, depending on the availability of transplant center expertise, so many different surgical recovery teams might be present. The deceased donor is declared brain dead (two independent
43 clinical exams and confirmatory “apnea tests”) and consent from the family is obtained prior to proceeding with multiorgan recovery. The brain dead patient’s heart and lungs are maintained with mechanical and pharmacologic assistance so even though the patient is legally and medically dead (brain death is irreversible because there is no longer blood flow to the brain and all brain stem functioning has ceased), the heart is still beating at the time of recovery surgery. All of the recovery teams start their organ dissections simultaneously and when it is time to remove the organs from the body, the heart is recovered first, then lungs, then liver, pancreas and kidneys. The heart and lungs can only be outside of the body for 4-6 hours prior to transplant, whereas the liver should be transplanted within 12 hours and the kidneys in less than 24 hours (less than 12 hours is ideal). Special organ preservation solution is used to flush the organs so that they do not become too injured while on ice without their blood supply. The liver transplant procedure itself lasts anywhere between 4-10 hours and involves five major steps. The recipient’s diseased liver is first removed in its entirety. The recipient total hepatectomy, is in fact, the most dangerous part of the surgery because the liver is not functioning properly so the blood does not coagulate well and very large blood vessels such as the inferior vena cava and portal vein must be carefully attended to in order to avoid excessive bleeding. “Hemostasis”, or control of bleeding, is critical during the recipient hepatectomy and requires excellent surgical technique and skilled anesthesia support to rapidly replace blood products (if needed) and maintain “hemodynamic stability” (i.e., normal pulse and blood pressure). Anhepatic Stage - The second phase, the “anhepatic” phase commences after the old liver is removed and before the new liver is reconnected to its blood supply. Many metabolic and bleeding issues need to be managed by the anesthesiologists at this point. The surgeon must quickly connect the veins draining blood from the liver and reestablish portal vein flow into the liver.
44 Reperfusion Stage - The “reperfusion” phase occurs when portal blood inflow and hepatic venous outflow is re-established. This third phase can be accompanied by hemodynamic instability (low blood pressure), high potassium levels (leading to irritation of the heart) and excessive bleeding (depending on the quality of surgical technique). Sometimes it can take several minutes to hours for the new liver to begin functioning properly to synthesize blood clotting factors and to clear acid out of the bloodstream. Arterial Reperfusion Stage – The fourth phase, when the hepatic artery is “anastomosed” (surgically connected) and opened up for more blood to flow into the liver. Fifth phase - When the bile duct is anastomosed. The fourth and fifth phase are usually relatively calm moments during the transplant, but care must be taken to perform these connections properly to avoid complications such as hepatic artery thrombosis or biliary leak or stricture. As a result of improved surgical and anesthetic techniques, effective immunosuppression and anti-infection medicines and practice of true multidisciplinary care, liver transplantation in well selected recipients and donors is extremely successful in the modern transplant era. Both LDLT and DDLT are accepted standards of care in the treatment of end stage liver disease. Postoperative Care First 24 to 48 hrs - Once the surgical operation is over the patient is usually kept in a special intensive care unit where well trained specialist team of intensive care doctors and nurses takes care of the patient to ensure that they are kept stable hemodynamically (blood pressure, oxygenation, fluids and urine output are balanced and maintained. Function of the new liver is monitored closely by blood tests and ultrasound examinations. The liver function tests should demonstrate a trend towards normal during this time. On rare occasions (<2% of the time), the new liver does not start working at all (“primary nonfiction”) or there might be a surgical complication such as hepatic artery thrombosis that requires immediate retransplant.
45 Normally for the first 24 to 48 hours the patient is kept on ventilator (a special machine that keeps the lung expanded and the body well oxygenated) and the patients are kept deeply sedated until it is time to remove the ventilator. Once the ventilator is removed, the patient is fully conscious and can start eating and moving around slowly. During this period a limited number of relatives maybe allowed to see the patient. Postoperative Days (PODs) 3-10 days – Once the patient is extubated (ventilator removed) and stable, he or she can be transferred out of the ICU to the regular liver transplant ward. Here, nurses and doctors ensure adequate pain control and a normal recovery path, regularly monitoring liver function tests and immunosuppression drug levels. The bladder catheter is removed on Postoperative Day #3 and usually the surgical drains are all removed prior to discharge home. The sutures closing the skin incision are not removed until 2-3 weeks after the operation and this is done in the outpatient clinic. When the patient’s liver function tests (and all other labs) normalized and they are ambulating and tolerating a regular diet, the Transplant Pharmacist and/or Transplant Social Worker have teaching sessions with the patient and family to ensure that everyone understands the many different drugs that must be taken, their purpose, their doses and their potential side effects. Also, general discharge advice about avoiding infection and when to return to the outpatient clinic are imparted.
46 POST OPERATIVE CARE Following surgery, the patient will wake up in the surgical intensive care unit (SICU). During this time, a tube will be inserted into the windpipe to facilitate breathing. It is removed when the patient is fully awake and strong enough to breathe on his or her own. There may be other tubes that are removed as the patient recovers. When safe to leave the SICU, the patient is moved to the transplant floor. Walking and eating will become the primary focus. Physical therapy may be started to help the patient become active, as it is an important part of recovery. When the patient begins to feel hungry and the bowels are working, regular food that is low in salt will be given. A patient should expect to spend about 10 to 14 days in the hospital, although some stays may be shorter or longer. Before leaving the hospital, a patient will be advised of: signs of infection or rejection, how to take medications and change dressings, and how to understand general health problems. Infection can be a real danger, because the medications taken compromise the body's defense systems. The doctors will conduct blood tests, ultrasounds, and x rays to ensure that the patient is doing well. The first three months after transplant are the most risky for getting such infections as the flu, so patients should follow these precautions:  Avoid people who are ill.  Wash hands frequently.  Tell the doctor if you are exposed to any disease.  Tell the doctor if a cold sore, rash, or water blister appears on the body or spots appear in the throat or on the tongue.  Stay out of crowds and rooms with poor circulation.  Do not swim in lakes or community pools during the three months following transplant.  Eat meats that are well-cooked.  Stay away from soil, including those in which house-plants are grown, and gardens, during the three months following transplant.  Take all medications as directed.  Learn to report the early symptoms of infection.
47 To ensure that the transplant is successful and that the patient has a long and healthy life, a patient must get good medical care, prevent and treat complications, keep in touch with doctors and nurses, and follow their advice. Nutrition plays a big part in the success of a liver transplant, so what a patient eats after the transplant is very important. MEDICATIONS NEEDED FOLLOWING LIVER TRANSPLANTATION Immunosuppressant drugs Successfully receiving a transplanted liver is only the beginning of a lifelong process. Patients with transplanted livers have to stay on immunosuppressant drugs for the rest of their lives to prevent organ rejection. Like most other allografts, a liver transplant will be rejected by the recipient unless immunosuppressive drugs are used. The immunosuppressive regimens for all solid organ transplants are fairly similar, and a variety of agents are now available .Although many patients can reduce the dosage after the initial few months, virtually none can discontinue drugs altogether. For adolescent transplant recipients, post transplantation is a particularly difficult time, as they must learn to take responsibility for their own behavior and medication, as well as balance their developing sexuality in a body that has been transformed by the adverse effects of immuno-suppression. Long-term outcome and tailoring of immunosuppression is of great importance. Cyclosporine has long been the drug of experimentation in the immunosuppression regimen, and has been well-tolerated and effective. Hypertension, nephrotoxicity, and posttransplant lymphoproliferative disease (PTLD) are some of the long-term adverse effects. Tacrolimus has been developed more recently, and has improved the cosmetic adverse effects of cyclosporine, but has similar rates of hypertension and nephrotoxicity, and possibly a higher rate of PTLD. Prednisone, azathioprine, and tacrolimus are often combined with cyclosporine for better results. Newer immunosuppressive agents promise even better results. There has been a recent, welcome development in renal sparing drugs, such as mycophenolate mofetil, which has no cosmetic adverse effects, does not require drug level monitoring, and is thus particularly attractive to teenagers. If started prior to irreversible renal dysfunction, recent research demonstrates recovery of renal function with mycophenolate mofetil. There is little
48 published data on the use of sirolimus (rapamycin) in the pediatric population, but preliminary studies suggest that the future use of interleukin-2 receptor antibodies may be beneficial for immediate post-transplant induction of immunosuppression. When planning immunosuppression for adolescents, it is important to consider the effects of drug therapy on both males and females in order to maintain fertility and to ensure safety in pregnancy. Adequate practical measures and support should reduce noncompliance in this age group, and allow good, long-term function of the transplanted liver, . Most liver transplant recipients receive corticosteroids plus a calcineurin inhibitor such as tacrolimus or cyclosporin plus a purine antagonist such as mycophenolate mofetil. Clinical outcome is better with tacrolimus than with cyclosporin during the first year of liver transplantation. If the patient has a co-morbidity such as active hepatitis B, high doses of hepatitis B immunoglubins are administrated in liver transplant patients. Liver transplantation is unique in that the risk of chronic rejection also decreases over time, although the great majority of recipients need to take immunosuppressive medication for the rest of their lives. It is possible to be slowly taken off anti rejection medication but only in certain cases. It is theorized that the liver may play a yet-unknown role in the maturation of certain cells pertaining to the immune system. There is at least one study by Thomas E. Starzl's team at the University of Pittsburgh which consisted of bone marrow biopsies taken from such patients which demonstrate genotypic chimerism in the bone marrow of liver transplant recipients. Risks Early failure of the transplant occurs in every one in four surgeries and has to be repeated. Some transplants never work, some patients succumb to infection, and some suffer immune rejection. Primary failure is apparent within one or two days. Rejection usually starts at the end of the first week. There may be problems like bleeding of the bile duct after surgery, or blood vessels of the liver may become too narrow. The surgery itself may need revision because of narrowing, leaking, or blood clots at the connections. These issues may be solved with or without more surgery depending on the severity.
49 Infections are a constant risk while on immunosuppressive agents, because the immune system is supposed to prevent them. A method has not yet been devised to control rejection without hampering immune defenses against infections. Not only do ordinary infections pose a threat, but because of the impaired immunity, transplant patients are susceptible to the same opportunistic infections (OIs) that threaten acquired immune deficiency syndrome (AIDS) patients— pneumocystis pneumonia, herpes and cytomegalovirus (CMV) infections, fungi, and a host of bacteria. Drug reactions are also a continuing threat. Every drug used to suppress the immune system has potential problems. As previously stated, hypertension, nephrotoxicity, and PTLD are some of the long-term adverse effects with immunosupressive drugs like cyclosporine. Immunosuppressants also hinder the body's ability to resist cancer. All drugs used to prevent rejection increase the risk of leukemias and lymphomas. There is also a risk of the original disease returning. In the case of hepatitis C, reoccurrence is a risk factor for orthotropic liver transplants. Newer antiviral drugs hold out promise for dealing with hepatitis. In alcoholics, the urge to drink alcohol will still be a problem. Alcoholics Anonymous (AA) is the most effective treatment known for alcoholism. Transplant recipients can get high blood pressure, diabetes, high cholesterol, thinning of the bones, and can become obese. Close medical care is needed to prevent these conditions. COMPLICATIONS Given the complexity of liver transplantation, it is surprising that complication rates are so low and overall success is so high. The one year survival is 85-90% and at five years it is 70%. Death during the procedure is a rare event, occurring less than 1% of the time. Infections: The most common cause of death after a liver transplant is infection, either a hospital acquired sepsis or an opportunistic infection resulting from the necessity of immunosuppressive drug use. Patients with liver failure tend to be naturally immunosuppressed, mostly as a result of malnutrition, so it is important not to give anti-rejection medicines in too high doses. Simple
50 urinary tract infections or pneumonias can rapidly transform into life threatening infections in the liver transplant recipient. Bleeding: Bleeding is not uncommon in liver transplantation because the liver is a very vascular organ and when the liver is not functioning properly, the blood becomes thin. Surgical bleeding is almost always a controllable situation, even if it means returning the patient to the Operation Theater to correct after the initial transplant. The newly transplanted liver usually starts synthesizing appropriate amounts of coagulation factors within minutes to hours, so postoperative bleeding is often surgical in nature. Biliary leak or Strictures: Biliary leak or strictures occur 30% of the time with Living Donor Liver Transplant (LDLT) and 15% of the time with Deceased Donor Transplant (DDLT). Often, biliary complications can be managed non-surgically with the assistance of Hepatologists using endoscopy or Interventional Radiologists using catheter based approaches. Chronic biliary strictures can cause significant long term morbidity, including bile duct infections (cholangitis) and liver abscesses. Primary Non Function of the Transplanted Liver: Primary Non Function, when the newly transplanted liver does not work at all, is fortunately a rare event (<1%) but requires immediate re-transplant to save the patient. Another complication that may require immediate re-transplant is hepatic artery thrombosis (“HAT”). Hepatic Artery Thrombosis (HAT): occurs in 2-5% of cases and is more common when smaller vessels are being anastomosed (such as with Living Donor Liver Transplant or in pediatric liver transplant). Even if re-transplant is not required, there is significant morbidity associated with long term HAT, including repeated infections of the bile ducts and liver.
51 Venous Complications – of liver transplant include portal vein thrombosis and hepatic venous outflow obstruction. If portal vein thrombosis occurs early after transplant, it must be recognized and treated quickly, usually surgically but sometimes with catheter infusion based treatments by the Interventional Radiologists. Chronic portal vein thrombosis is usually well tolerated but can make re-transplant (if ever required) difficult to impossible. Hepatic venous outflow obstruction occurs when the veins draining blood from the liver into the inferior vena cava are too narrow (usually as a result of surgery), leading to congestion of the liver. If severe and longstanding, this can lead to ascites and renal failure. Incisional Hernia: is quite common after liver transplant because patients with chronic liver failure often have very weak connective tissue as a result of malnutrition. The weak section of the abdomen leads to protrusion of the abdominal contents in the hernia. Incisional hernia rarely causes life threatening complications such as trapped (or “incarcerated”) bowel contents, but chronic discomfort can be easily alleviated with a simple hernia repair surgery. Medical Complications Rejection – After a liver transplantation, there are three types of graft rejection that may occur. They include hyperacute rejection, acute rejection and chronic rejection. Hyperacute rejection is caused by preformed anti-donor antibodies. It is characterized by the binding of these antibodies to antigens on vascular endothelial cells. Complement activation is involved and the effect is usually profound. Hyperacute rejection happens within minutes to hours after the transplant procedure. Unlike hyperacute rejection, which is B cell mediated, acute rejection is mediated by T cells. It involves direct cytotoxicity and cytokine mediated pathways. Acute rejection is the most common and the primary target of immunosuppressive agents. Acute rejection is usually seen within days or weeks of the transplant. Chronic rejection is the presence of any sign and symptom of rejection after 1 year. The cause of chronic rejection is still unknown but an acute rejection is a strong predictor of chronic rejections. Liver rejection may happen anytime after the
52 transplant. Lab findings of a liver rejection include abnormal AST, ALT, GGT and liver function values such as prothrombin time, ammonia level, bilirubin level, albumin concentration, and blood glucose. Physical findings include encephalopathy, jaundice, bruising and bleeding tendency. Other nonspecific presentation are malaise, anorexia, muscle ache, low fever, slight increase in white blood count and graft-site tenderness,when the grafted liver gets rejected by the body and this requires treatment. Usually it requires a biopsy to ascertain that there is rejection, Opportunistic Infections – an immunosuppressed patient is prone to infections and this can result in infections by bacteria or viruses that normally cause no problems to a person. Hospital acquired Vascular Complications: Like Deep Venous Thrombosis or pulmonary embolism. Cardiac complications – like myocardial infarction Neurologic complications – like stroke or due to adverse drug reaction A fine balance of immunosuppression must be maintained: too little and the liver will reject, too much and the patient can easily suffer a life threatening infection. Opportunistic infections are rarer in the current era of transplantation due to excellent prophylaxis regimens, sensitive surveillance tests and effective treatments for diagnosed infections. Other medical complications occur at similar rates as other major surgery patients, but they are poorly tolerated. Attention to detail and vigilance are paramount in the postoperative care of the liver transplant patient. PROGNOSIS Prognosis is quite good, but those with certain illnesses may differ.[3] There is no exact model to predict survival rates; those with transplant have a 58% chance of surviving 15 years.[4] Failure of the new liver occurs in 10% to 15% of all cases. These percentages are contributed to by many complications. Early graft failure is probably due to preexisting disease of the donated organ.
53 Others include technical flaws during surgery such as revascularization that may lead to a nonfunctioning graft. Twenty-five million or one in 10 Americans are or have been afflicted with liver or biliary diseases. As of June 2003, there were 17,239 patients on the UNOS National Transplant Waiting List who were waiting for a liver transplantation. For the previous year (July 1, 2001 to June 30, 2002), there were a total of 5,261 liver transplants performed. Of those, 4,785 were cadaver donors (already deceased) and 476 living donors. For liver transplants performed from July 1, 1999 to June 30, 2001, the one-year survival rate was 86% for adults; 1,861 patients died while on the UNOS waiting list for the year ending June 30, 2002. More than 80% of children survive transplantation to adolescence and adulthood. Since the introduction of cyclosporine and tacrolimus (drugs that suppress the immune response and keep it from attacking and damaging the new liver), success rates for liver transplantation have reached 80–90%. Infections occur in about half of transplant patients and often appear during the first week. Biliary complications are apparent in about 22% of recipient patients (and 6% of donors), and vascular complications occur in 9.8% of recipient patients. Other complications in donors include re-operation (4.5%) and death (0.2%). There are potential social, economic, and psychological problems, and a vast array of possible medical and surgical complications. Close medical surveillance must continue for the rest of the patient's life. PEDIATRIC TRANSPLANTATION In children, living liver donor transplantations have become very accepted. The accessibility of adult parents who want to donate a piece of the liver for their children/infants has reduced the number of children who would have otherwise died waiting for a transplant. Having a parent as a donor also has made it a lot easier for children - because both patients are in the same hospital and can help boost each other's morale.
54 ADVANTAGES OF LIVER TRANSPLANTATION  Liver transplants provide patients a chance for a longer, more active life in the final stages of liver disease or end-stage liver disease.  There’s no question that transplant is a major operation. The recovery can sometimes be the most taxing but anti-rejection medications are making the process easier.  If the transplant is performed before the recipient's health deteriorates, he or she is better able to tolerate the surgery and recovers more quickly.  The donors and recipients recovered quickly, the donors were discharged in about a week and the recipients in 2 to 3 weeks. PATIENT EDUCATION AFTER LIVER TRANSPLANT DIET AND NUTRITION After your liver transplant, you may need to adjust your diet to keep your liver healthy and functioning well and to prevent excessive weight gain. You should maintain a healthy weight, which can help prevent infections, high blood pressure and other complications. Your nutrition specialist (dietitian) and other members of your treatment team will work with you to create a healthy-eating plan that meets your needs and complements your lifestyle. Your dietitian will provide you with several healthy-food options and ideas to use in your eating plan. Your dietitian's recommendations may include:  Eating at least five servings of fruits and vegetables each day  Eating lean meats, poultry and fish  Eating whole-grain breads and cereals and other grains  Having enough fiber in your daily diet  Drinking low-fat milk or eating other low-fat dairy products, to help maintain enough calcium  Maintaining a low-salt and low-fat diet  Following food safety guidelines
55  Avoiding alcohol  Staying hydrated by drinking adequate water and other fluids each day  Avoiding grapefruit and grapefruit juice due to its effect on a group of immunosuppression medications (calcineurin inhibitors) Follow-Up Care to be taken Post Liver Transplantation  After liver transplantation, the patient must frequently visit the transplant surgeon, about 1-2 times a week over about 3 months.  The transplant surgeon and hepatologist monitor the patient's progress through blood tests. After a year of Liver transplantation, follow-up care becomes individualized.  Post transplant, patient will be on several different medications especially Immunosuppression medications which keep the body from fighting off the new organ. You may be on other medications to control blood pressure, Insulin, antibiotics and antivirals, diuretics, and vitamins.  Typically, patients are seen every week for the first month post transplant, and then the frequency is reduced over time.  Additional testing to monitor your health and liver function may vary from patient to patient. Tests may include abdominal scans, ultrasounds, and liver biopsies.  There are few dietary restrictions. The patient is often advised to restrict salt (sodium) intake. A well-balanced diet with adequate protein is necessary. For reasons that are not clear, obesity frequently becomes a problem with liver transplant patients. To avoid this problem, patients should take control of their calorie intake early on.
56 WELCOME TO LIVER TRANSPLANT INDIA
57 LIVER TRANSPLANTATION IN INDIA Dr AS Soin is recognized the world over for pioneering and establishing liver transplantation in India from 1998, when he did the country’s first successful transplant to now, when he leads the country’s largest, and one of the world’s largest and most successful liver transplant programs at Medanta. With over 2500 liver transplants under his belt, he and his team have performed more than 2000 transplants in India. They currently perform 30 liver transplants a month with 95% success - results which are at par with the world's best elsewhere. No wonder, he gets referrals from all over South Asia, Middle East, Far East and Africa, and has transplanted nearly 500 patients from these countries. In addition, he has performed more than 12000 other complex liver, gall bladder and bile duct surgeries in a career spanning 27 years. List of ApprovedHospitals for Liver Transplantation as on 10.07.2015 S.No Name of the Hospital Registration Valid Upto 1 Director of Medical Services, Apollo Hospitals Enterprises Ltd., No.21, Greams Lane, Off.Greams Road, Chennai. 31/08/2016 2 Medical Superintendent, Christian Medial College and Hospital, Vellore 632 004 24.09.2019 3 Chief Operating Officer, Global Hospitals, Global Health City, 439 Cheran Nagar, Perumbakkam, Chennai 600 100 13.05.2019 4 The Dean, Government Stanley Hospital, 27.01.2019
58 Chennai 600 003 5 Medical Director, Sri Ramachandra Medical College and Research Institute, Porur, Chennai-116. 30.09.2014 6 The Chairman, D.D. Hospital and D.D. Medical College, No 66 DD Nagar, Kunavalam Post, Thiruvallur District PIN 631 210 21.03.2015 7 The Madras Medical Mission, 4 A Dr. J. Jayalalitha Nagar, Mogappair, Chennai 600 037 27.12.2015 8 Sri Ramakrishna Hospital 395 Sarojinin Naidu StÏ Siddapudur, Coimbatore 18.05.2016 9 Cethar Hospitals C-108, Fort Station Road, 5th Cross, Thillai Nagar, Trichy 620 018 30.06.2018 10 Kovai Medical Centre and Hospital Ltd Post Box No.3209, Avanashi Road Coimbatore 641 014 16.09.2018 11 Kamakshi Memorial Hospital No.1 Radial Road, Pallikarnai Chennai 600 100 30.09.2018 12 Director of Medical Education and Medical Superintendant, MIOT Hospitals, 4/112, Mount Poonamallee, Manappakkam, Chennai 600 089 16.02.2017 13 Chettinad Hospital and Research Institute IT Highway Kelambakkam 23.04.2018
59 Kanchipuram District 603 103 14 PSG Hospitals Avinashi Road Peelamedu, Coimbatore 641004 01.06.2019 15 Apollo Speciality Hospitals Lake View Road, K.K.Nagar Madurai 625 020 16.12.2019 16 Gem Hospitals 45, Pankaja Mill Road Ramanathapuram, Coimbatore 45 30.11.2019 17 SRM Institute for Medical sciences, No.1, Jawaharlal Nehru Salai, 100 Feet road, Vadapalani, Chennai 600026 05.02.2020 18 SRM Medical College Hosp & Research Centre SRM Nagar, Potheri, Kattankulathur 603203 12.02.2020 Why choose India for Liver Transplantation Liver transplantation in India is performed through cutting- edge clinical solutions, research, extraordinary patient care and infrastructure of world-class standards. This has addressed concerns of many patients and has helped them get rid of complex and most end stage liver diseases.Liver Transplant is a complex surgical exercise and need highly skilled consultants, ingenious technical staff and advanced technology working with perfect harmony, enormous dedication and team work. India offers a one stop solution for all those seeking critical procedures such as Liver transplantation. Cities in India that offers Liver Transplantation at some of the best multi specialty hospitals are as follows; Mumbai Hyderabad Kerala Delhi Pune Goa
60 Bangalore Nagpur Jaipur Chennai Gurgaon Chandigarh What is the Cost of Liver Transplantation in India? Liver transplant cost in India allows people of every class and from every part of the world to avail the best medical care suited to their pocket. Everything from finding a donor and performing the surgery to the prolonged recovery period and lifelong medication, each factor adds to the cost, making liver transplant difficult to afford for some people. Hospitals in India are a perfect destination for medical tourism that combines health treatment with visits to some of the most alluring and awe-inspiring places of the world at an attractively low cost. Other costs associated with transplantation include:  recovery and in-hospital stay  extensive lab tests  anesthesia  fees for transplant surgeons and operating room personnel  organ recovery  transportation to hospital  lodging, transportation and food for family members while the patient is hospitalized  physical therapy and rehabilitation  patient lodging following discharge  anti-rejection drugs and other medications
61 IN KERALA List of Approved Hospitals for Liver Transplantationin Kerala S.No Name of Hospital Address/Contact Details License Valid Until 1 Amrita Institute of Medical Sciences and Research Centre Amrita Lane AIMS Ponekkara Post, Kochi 682 041 Phone: 0484 2801234, 2804321, 4001234 Email: aimsinternational@aims.amrita.edu Website: www.aimshospital.org 02/07/2015 2 Kerala Institute of Medical Sciences P.B.No.1, Anayara P.O, Trivandrum 695 029 Phone: 0471 3041000, 2447575 Email: relations@kimskerala.com Website: www.kimskerala.com 03/01/2018 3 Lakeshore Hospital NH 47 Bypass, Maradu, Nettoor P.O, Kochi 682 040 Phone: 0484-2701032/2701033 Email: info@lakeshorehospital.com Website: www.lakeshorehospital.com 19/05/2015 4 Malabar Institute of Medical Sciences Ltd. Mini By-pass Road, Govindapuram P.O, Calicut 673 016 Phone: 0495 - 2744000 Email: mimsclt@mimsindia.com Website: www.mimsindia.com 19/12/2017 5 Medical Trust Hospital MG Road, Kochi 682 016 Phone: 0484 2358001 09/05/2017
62 S.No Name of Hospital Address/Contact Details License Valid Until Email: medtrust@vsnl.com Website: www.medicaltrusthospital.com COST OF A LIVER TRANSPLANTATION As of 1997, the cost of a liver transplant in the United States was $314,500, including the evaluation, procurement of the liver, hospitalization, physician fees and follow-up care and medications for the first year. As of 2002, the cost of a liver transplant in the United States averaged about $250,000 for immediate hospital and doctor expenses. Necessary pre- and post- operative expenses brought the total to about $314,500. In some cases Medicare provides coverage for liver transplants for some causes of liver failure. Talk to your transplant center to see if they are Medicare approved and you meet the criteria for a Medicare covered transplant. If you have private insurance, you should check with your insurance representative about whether your policy covers liver transplants. This may help to pay some of the costs.
63 REVIEW OF LITERATURE
64 REVIEW OF LITERATURE Partial liver transplantation-living donor liver transplantation and split liver transplantation Sascha A. Müller ,Arianeb Mehrabi , Bruno M. Schmied Abstract In the last two decades, liver transplantation (LTx) has become the treatment of choice for several liver diseases including hepatocellular carcinoma in selected cases. Improvements in surgical and anesthesiological procedures have increased patient survival after LTx, resulting in excellent 1-year survival rates. The rate-limiting factor to further increase the number of LTx is the extreme shortage of suitable organs with the consequence that pediatric and adult patients are dying on the waiting list. At present, mortality reported for pediatric and adult patients on the waiting list is 10 to 20%. Living-donor liver transplantation and split liver transplantation are measurements to reduce the severe lack of cadaveric grafts by expanding the donor pool. Major centers around the world now routinely perform partial LTx in infants and adults with survival success equivalent to that after full-size liver transplantation. Frequency and Outcomes of Liver Transplantation for Nonalcoholic Steatohepatitis in the United States Michael R. Charlton,Justin M. Burns,Rachel A. Pedersen,Kymberly D. Watt,Julie K. Heimbach,Ross A. Dierkhising Background & Aims The relative frequency of nonalcoholic steatohepatitis (NASH) as an indication for liver transplantation and comparative outcomes following transplantation are poorly understood.
65 Methods We analyzed the Scientific Registry of Transplant Recipients for primary adult liver transplant recipients from 2001 to 2009. Results From 2001 to 2009, 35,781 patients underwent a primary liver transplant, including 1959 for who NASH was the primary or secondary indication. The percentage of patients undergoing a liver transplant for NASH increased from 1.2% in 2001 to 9.7% in 2009. NASH is now the third most common indication for liver transplantation in the United States. No other indication for liver transplantation increased in frequency during the study period. Compared with other indications for liver transplantation, recipients with NASH are older (58.5 ± 8.0 vs 53.0 ± 8.9 years; P < .001), have a larger body mass index (>30 kg/m2) (63% vs 32%; P < .001), are more likely to be female (47% vs 29%; P < .001), and have a lower frequency of hepatocellular carcinoma (12% vs 19%; P < .001). Survival at 1 and 3 years after liver transplantation for NASH was 84% and 78%, respectively, compared with 87% and 78% for other indications (P = .67). Patient and graft survival for liver recipients with NASH were similar to values for other indications after adjusting for level of creatinine, sex, age, and body mass index. Conclusions NASH is the third most common indication for liver transplantation in the United States and is on a trajectory to become the most common. Outcomes for patients undergoing a liver transplant for NASH are similar to those for other indications. Living Donor Liver Transplantation for High MELD Score Patients H. Chou, C. Lee, R. Soong, T. Wu, T. Wu, K. Chan, W. Lee Background: Liver transplantation is the only effective treatment for the very sick liver failure patients. For the success of liver transplantation, it is better to have good donors for very sick patients. However, liver donation is very short in Asian countries. Liver donor liver transplantation is the only way to rescue the very sick patients. The aim of this study is to
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Term paper

  • 1. 1 TERM PAPER ON LIVER TRANSPLANTATION Submitted by, Submitted to, Aswathi. P Mrs. Resmi. G 1st yr Msc Nursing Lecturer Al-shifa college of Nursing Al-shifa college of Nursing Perinthalmanna Perinthalmanna Submitted on: 17 -08-2015
  • 2. 2 INDEX Sl No Content Page No 1 Introduction 2 Anatomy and physiology of liver
  • 3. 3
  • 4. 4 INTRODUCTION Liver transplantation or hepatic transplantation is the replacement of a diseased liver with some or all of a healthy liver from another person (allograft). The most commonly used technique is orthotopic transplantation, in which the native liver is removed and replaced by the donor organ in the same anatomic location as the original liver. Liver transplantation is a viable treatment option for end-stage liver disease and acute liver failure. Typically three surgeons and two anesthesiologists are involved, with up to four supporting nurses. The surgical procedure is very demanding and ranges from 4 to 18 hours depending on outcome. Numerous anastomoses and sutures, and many disconnections and reconnections of abdominal and hepatic tissue, must be made for the transplant to succeed, requiring an eligible recipient and a well-calibrated live or cadaveric donor match ANATOMY AND PHYSIOLOGY OF LIVER
  • 5. 5 The liver is the largest solid organ in the body. In adults, the liver can weigh up to 1.5 kilograms (kg). It is in the upper-right abdomen, just under the rib cage and below the diaphragm (the thin muscle below the lungs and heart that separates the chest cavity from the abdomen). The liver is part of the digestive system. Structure LOBES External Structure The liver is the largest gland in the body weighing about 1.4 kg in an adult. It is situated under the diaphragm in the upper abdominal cavity and is held in place by several ligaments. It is a reddish-brown colour and comprises of four anatomical lobes. When viewed from the front, the dominant left and right lobes can be seen which are separated by the falciform ligament. Situated in a depression on the posterior surface of the liver is the gall bladder, a pear-shaped sac which stores bile synthesised by the liver. The liver performs many vital metabolic functions. It has the ability to store and metabolise useful substances such as nutrients, but it breaks down or detoxifying harmful substances to render them inert and less harmful. The liver has 2 main lobes: the larger right lobe and the smaller left lobe. Each lobe is divided into segments.
  • 6. 6 The lobes are separated by a band of tissue called the falciform ligament (also called the broad ligament), which helps attach the liver to the diaphragm. A layer of connective tissue, called Glisson’s capsule or the capsule, covers the liver. Blood Supply The liver receives a blood supply from two sources. The first is the hepatic artery which delivers oxygenated blood from the general circulation. The second is the hepatic portal vein delivering deoxygenated blood from the small intestine containing nutrients. The blood flows through the liver tissue to the hepatic cells where many metabolic functions take place. The blood drains out of the liver via the hepatic vein. The liver tissue is not vascularised with a capillary network as with most other organs, but consists of blood filled sinusoids surrounding the hepatic cells. Unlike most other organs, the liver has 2 major sources of blood:  portal vein – carries blood from the digestive system to the liver o Approximately 75% of the liver’s blood supply comes from the portal vein.  hepatic artery – supplies the liver with oxygen-rich blood from the heart
  • 7. 7 Most of the blood is removed from the liver through 3 hepatic veins (the right, middle and left hepatic veins) found inside the liver. Hepatic portal vein . "Portal vein" redirects here. For a vein that connects two systems of capillary beds, see portal venous system. The hepatic portal vein is a blood vessel that conducts blood from the gastrointestinal tract and spleen to the liver. This blood is rich in nutrients that have been extracted from food, and the liver processes these nutrients; it also filters toxins that may have been ingested with the food. The liver receives about 75% of its blood through the hepatic portal vein, with the remainder coming from the hepatic artery proper. The blood leaves the liver to the heart in the hepatic veins.
  • 8. 8 The hepatic portal vein is not a true vein, because it conducts blood to capillary beds in the liver and not directly to the heart. It is a major component of the hepatic portal system, one of only two portal venous systems in the body – with the hypophyseal portal system being the other. The hepatic portal vein is usually formed by the confluence of the superior mesenteric and splenic veins and also receives blood from the inferior mesenteric, gastric, and cystic veins. Conditions involving the hepatic portal vein cause considerable illness and death. An important example of such a condition is elevated blood pressure in the hepatic portal vein. This condition, called portal hypertension, is a major complication of cirrhosis Structure Tributaries of the hepatic portal vein[1]  Splenic vein  Superior mesenteric vein  Inferior mesenteric vein  Gastric veins  Cystic vein Measuring approximately 8 cm (3 inches) in adults, the hepatic portal vein is located in the right upper quadrant of the abdomen, originating behind the neck of the pancreas. In most individuals, the hepatic portal vein is formed by the union of the superior mesenteric vein and the splenic vein. For this reason, the hepatic portal vein is occasionally called the splenic-mesenteric confluence. Occasionally, the hepatic portal vein also directly communicates with the inferior mesenteric vein, although this is highly variable. Other tributaries of the hepatic portal vein include the cystic and gastric veins. Immediately before reaching the liver, the portal vein divides into right and left. It ramifies further, forming smaller venous branches and ultimately portal venules. Each portal venule courses alongside a hepatic arteriole and the two
  • 9. 9 vessels form the vascular components of the portal triad. These vessels ultimately empty into the hepatic sinusoids to supply blood to the liver. Portacaval anastomoses The portal venous system has several anastomoses with the systemic venous system. In cases of portal hypertension these anastamoses may become engorged, dilated, or varicosed and subsequently rupture. new Accessory hepatic portal veins Accessory hepatic portal veins are those veins that drain directly into the liver without joining the hepatic portal vein. These include the paraumbilical veins as well as veins of the lesser omentum, falciform ligament, and those draining the gallbladder wall. Function The hepatic portal vein and hepatic arteries form the liver's dual blood supply. Approximately 75% of hepatic blood flow is derived from the hepatic portal vein, while the remainder is from the hepatic arteries. Unlike most veins, the hepatic portal vein does not drain into the heart. Rather, it is part of a portal venous system that delivers venous blood into another capillary system, namely the hepatic sinusoids of the liver. In carrying venous blood from the gastrointestinal tract to the liver, the hepatic portal vein accomplishes two tasks; namely, it supplies the liver with metabolic substrates and it ensures that substances ingested are first processed by the liver before reaching the systemic circulation. This accomplishes two things. First, possible toxins that may be ingested can be detoxified by the hepatocytes before they are released into the systemic circulation. Second, the liver is the first organ to absorb nutrients just taken in by the intestines. After draining into the liver sinusoids, blood from the liver is drained by the hepatic vein. Common hepatic artery The common hepatic artery (CHA) is a terminal branch of the coeliac artery.
  • 10. 10 The CHA is a terminal branch of the coeliac artery, it passes to the right in the lesser sac, and enters the lesser omentum to pass slightly upwards towards the porta hepatis. It gives off the right gastric artery that runs along the lesser curvature of the stomach to anastomose with the left gastric artery. The common hepatic artery then bifurcates into the gastroduodenal artery and proper hepatic artery. Branches  right gastric artery  proper hepatic artery  gastroduodenal artery Variation in hepatic arterial anatomy is seen in 40-45% of people. Classic branching of the common hepatic artery from the coeliac artery, and the proper hepatic artery into right and left hepatic arteries to supply the entire liver, is seen in only 55-60%. Variation in hepatic arterial anatomy is seen in 40-45% of people. Classic branching of the common hepatic artery from the coeliac artery, and the proper hepatic artery into right and left hepatic arteries to supply the entire liver, is seen in 55-60% of the population. In general, the common hepatic artery may arise from the abdominal aorta or superior mesenteric artery (SMA) and all or part of the right and left hepatic arteries may arise from (be replaced to) other vessels. The two most common variants are:  right hepatic artery replaced to the SMA  left hepatic artery replaced to the left gastric artery Another common finding, though not considered a variant by many authors, is trifurcation of the common hepatic artery into right hepatic artery, left hepatic artery and gastroduodenal artery (GDA). With this branching pattern there is no proper hepatic artery.
  • 11. 11 Variant anatomy Common hepatic artery  from aorta: 2%  from SMA: 2%  trifurcation into RHA, LHA and GDA: ~6% (range 4-8%) Right hepatic artery (RHA)  from coeliac artery: ~2.5% (range 1-4%)  from SMA: ~12.5% (range 9-15%)  accessory RHA from SMA: ~4% (range 1-7%) Left hepatic artery (LHA)  from left gastric artery (LGA): ~7.5% (range 4-11%)  accessory LHA from LGA: ~7.5% (range 4-11%) Right and left hepatic arteries  RHA from SMA and LHA from LGA: ~1% (range 0.5-2%)  accessory RHA and LHA: 1% Classification Another classification method is the one described by Michel et al in 1955 6  I: standard anatomy ~60% (range 55-61%)  II: replaced LHA ~7.5% (range 3-10%)  III: replaced RHA ~10% (range 8-11 %)  IV: replaced RHA and LHA ~1%  V: accessory LHA from LGA ~10% (range 8-11%)  VI: accessory RHA from SMA ~5% (range 1.5-7%)  VII: accessory RHA and LHA ~1%
  • 12. 12  VIII: accessory RHA and LHA and replaced LHA or RHA ~2.5%  IX: CHA replaced to SMA ~3% (range 2-4.5%)  X: CHA replaced to LGA ~0.5%  unclassified: o CHA separate origin from aorta ~2% o double hepatic artery ~4% o PHA replaced to SMA; GDA origin from aorta <0.5% Internal Structure The liver lobes are made up of microscopic units called lobules which are roughly hexagonal in shape. These lobules comprise of rows of liver cells (hepatocytes) which radiate out from a central point. The hepatic cells are in close contact with blood-filled sinusoids and also lie adjacent to canaliculi into which bile is secreted. Situated around the perimeter of the lobule are branches of the hepatic artery, hepatic portal vein and bile duct. These cluster together at the "corners" of the lobule forming what is called the portal triad. At the mid-point of the lobule is the central vein. Blood flows out of the sinusoids into the central vein and is transported out of the liver. HEPATOCYTES
  • 13. 13 Hepatocytes are the predominant cell type in the liver. An estimated 80% of the liver mass is made of these cells. The hepatocytes are round in shape containing a nucleus and an abundance of cellular organelles associated with metabolic and secretory functions. Organelles include endoplasmic reticulum (smooth and rough) and Golgi apparatus for secretory functions. Also there are high numbers of mitochondria to provide energy to support the many metabolic functions on the liver. Some of the hepatocytes lie adjacent to endothelial cells which form the walls of the sinusoids. These two cell types are separated by small space called the space of Disse. A hepatocyte is a cell of the main parenchymal tissue of the liver. Hepatocytes make up 70-85% of the liver's mass. These cells are involved in:  Protein synthesis  Protein storage  Transformation of carbohydrates  Synthesis of cholesterol, bile salts and phospholipids  Detoxification, modification, and excretion of exogenous and endogenous substances  Initiation of formation and secretion of bile Structure The typical hepatocyte is cubical with sides of 20-30 µm, (in comparison, a human hair has a diameter of 17 to 180 µm).[1]The typical volume of a hepatocyte is 3.4 x 10−9 cm3.[2] Smooth endoplasmic reticulum is abundant in hepatocytes, whereas most cells in the body have only small amounts.[3] Histology Hepatocytes display an eosinophilic cytoplasm, reflecting numerous mitochondria, and basophilic stippling due to large amounts of rough endoplasmic reticulum and free ribosomes. Brown lipofuscin granules are also observed (with increasing age) together with irregular
  • 14. 14 unstained areas of cytoplasm; these correspond to cytoplasmic glycogen and lipid stores removed during histological preparation. The average life span of the hepatocyte is 5 months; they are able to regenerate. Hepatocyte nuclei are round with dispersed chromatin and prominent nucleoli. Anisokaryosis (or variation in the size of the nuclei) is common and often reflects tetraploidy and other degrees of polyploidy, a normal feature of 30-40% of hepatocytes in the adult human liver.[4] Binucleate cells are also common. Hepatocytes are organised into plates separated by vascular channels (sinusoids), an arrangement supported by a reticulin (collagen type III) network. The hepatocyte plates are one cell thick in mammals and two cells thick in the chicken. Sinusoids display a discontinuous, fenestrated endothelial cell lining. The endothelial cells have no basement membrane and are separated from the hepatocytes by the space of Disse, which drains lymph into the portal tract lymphatics. Kupffer cells are scattered between endothelial cells; they are part of the reticuloendothelial system and phagocytose spent erythrocytes. Stellate (Ito) cells store vitamin A and produce extracellular matrix and collagen; they are also distributed amongst endothelial cells but are difficult to visualise by light microscopy. Protein synthesis The hepatocyte is a cell in the body that manufactures serum albumin, fibrinogen, and the prothrombin group of clotting factors (except for Factors 3 and 4). It is the main site for the synthesis of lipoproteins, ceruloplasmin, transferrin, complement, and glycoproteins. Hepatocytes manufacture their own structural proteins and intracellular enzymes. Synthesis of proteins is by the rough endoplasmic reticulum (RER), and both the rough and smooth endoplasmic reticulum (SER) are involved in secretion of the proteins formed. The endoplasmic reticulum (ER) is involved in conjugation of proteins to lipid and carbohydrate moieties synthesized by, or modified within, the hepatocytes.
  • 15. 15 Carbohydrate metabolism The liver forms fatty acids from carbohydrates and synthesizes triglycerides from fatty acids and glycerol. Hepatocytes also synthesize apoproteins with which they then assemble and export lipoproteins (VLDL, HDL). The liver is also the main site in the body for gluconeogenesis, the formation of carbohydrates from precursors such as alanine, glycerol, and oxaloacetate. Lipid metabolism The liver receives many lipids from the systemic circulation and metabolizes chylomicron remnants. It also synthesizes cholesterol from acetate and further synthesizes bile salts. The liver is the sole site of bile salts formation. Detoxification Hepatocytes have the ability to metabolize, detoxify, and inactivate exogenous compounds such as drugs, (drug metabolism), and insecticides, and endogenous compounds such as steroids. The drainage of the intestinal venous blood into the liver requires efficient detoxification of miscellaneous absorbed substances to maintain homeostasis and protect the body against ingested toxins. One of the detoxifying functions of hepatocytes is to modify ammonia into urea for excretion. The most abundant organelle in liver cell is the smooth endoplasmic reticulum. Hepatocyte isolation and culture Primary hepatocytes are commonly used in cell biological and biopharmaceutical research. In vitro model systems based on hepatocytes have been of great help to better understand the role of hepatocytes in (patho)physiological processes of the liver. In addition, pharmaceutical industry has heavily relied on the use of hepatocytes in suspension or culture to explore mechanisms of drug metabolism and even predict in vivo drug metabolism. For these purposes, hepatocytes are
  • 16. 16 usually isolated from animal or human whole liver or liver tissue by collagenase digestion, which is a two-step process. In the first step, the liver is placed in an isotonic solution, in which calcium is removed to disrupt cell-cell tight junctions by the use of a calcium chelating agent. Next, a solution containing collagenase is added to separate the hepatocytes from the liver stroma. This process creates a suspension of hepatocytes, which can be seeded in multi-well plates and cultured for many days or even weeks. For optimal results, culture plates should first be coated with an extracellular matrix (e.g. collagen, Matrigel) to promote hepatocyte attachment (typically within 1-3 hr after seeding) and maintenance of the hepatic phenotype. In addition, and overlay with an additional layer of extracellular matrix is often performed to establish a sandwich culture of hepatocytes. The application of a sandwich configuration supports prolonged maintenance of hepatocytes in culture. Freshly-isolated hepatocytes that are not used immediately can be cryopreserved and stored They do not proliferate in culture. Hepatocytes are intensely sensitive to damage during the cycles of cryopreservation including freezing and thawing. Even after the addition of classical cryoprotectants there is still damage done while being cryopreserved. Nevertheless, recent cryopreservation and resuscitation protocols support application of cryopreserved hepatocytes for most biopharmaceutical application Lobule Activity The hepatic portal vein and hepatic artery deliver oxygen and nutrients into to the blood sinusoids. This close relationship between the hepatocytes and surrounding blood enables many metabolic processes to take place. Blood flows out of the sinusoids into the central vein, removing detoxified substances and metabolic end products. The central vein ultimately reunites with the hepatic vein transporting these substances out of the liver. Bile that is produced by the hepatocytes drains into tiny canals called bile canaliculi (singular canaliculus). These drain into bile ducts located around the lobule perimeter.
  • 17. 17 Understanding First Pass Metabolism Drugs may be given in a number of ways. Oral administration is the most common and the easiest way to give a drug. The amount of drug reaching the general circulation will depend on a number of factors. Drug Absorption The drug is absorbed from the GI tract and passes via the portal vein into the liver where some drugs are metabolised. Sometimes the result of first pass metabolism means that only a proportion of the drug reaches the circulation. First pass metabolism can occur in the gut and the liver. For example, first pass metabolism occurs in the gut for benzylpenicillin and insulin and in the liver for propranolol, lignocane, chloromethiasole and GTN. Bypassing First Pass Metabolism Two ways to bypass first pass metabolism involve giving the drug by sublingual and buccal routes. The drugs are absorbed by the oral mucosa in both methods. In sublingual administration the drug is put under the tongue where it dissolves in salivary secretions. Nitroglycerine is administered in this way. In buccal administration the drug is placed between the teeth and the mucous membrane of the cheek. Sublingual and buccal methods both avoid destruction by the GI fluids and first pass effect of the liver Activity In this exercise you need to drag each drug name to the organ where it undergoes first pass metabolism.
  • 18. 18 Bile ducts The liver, gallbladder and small intestine are connected by a series of thin tubes called ducts. One function of the liver cells (hepatocytes) is to produce bile. Bile is a yellow-green fluid that helps digest fat. Bile travels through a series of ducts in the liver to the small intestine or to the gallbladder for storage.  Bile is collected from the liver in hepatic ducts.  Two hepatic ducts leave the liver and join to form the common hepatic duct.  The cystic bile duct leaves the gallbladder and joins the common hepatic duct to form the common bile duct.  The common bile duct empties bile into the duodenum (the first part of the small intestine). o If there is food in the small intestine, the bile will flow directly from the liver, through the common hepatic duct and common bile duct into the duodenum to help with digestion. o If the small intestine is empty, the bile will collect in the common bile duct until it backs up the cystic duct and into the gallbladder, where it is stored until it is needed.
  • 19. 19 FUNCTIONS OF LIVER The liver performs many important functions in the body. The liver:  produces bile o Bile is made up of bile salts, cholesterol, bilirubin, electrolytes and water. o Bile helps the small intestine digest fat and absorb fats, cholesterol and some vitamins.  absorbs and uses (metabolizes) bilirubin o Bilirubin is a yellow-red substance formed from hemoglobin when red blood cells (RBCs) break down. (Hemoglobin is a protein found in RBCs that carries oxygen and gives blood its red colour.) o The iron from the hemoglobin is stored in the liver or used by the bone marrow to produce new RBCs.  helps the body make blood-clotting (coagulation) factors o The body needs bile, which is produced by the liver, to absorb vitamin K. The body uses vitamin K to produce blood-clotting factors. o If the liver does not produce enough bile, the body will absorb less vitamin K and produce less blood-clotting factors.
  • 20. 20  helps the body metabolize fat o Bile breaks down fat from food to make it easier to digest.  metabolizes protein o Liver enzymes break down proteins from food so they can be digested and used by the body.  metabolizes carbohydrates o The body breaks down carbohydrates from food into glycogen, which is stored in the liver. The liver breaks down glycogen into glucose and releases it into the blood to maintain normal blood sugar levels.  stores vitamins and minerals o Vitamins A, D, E, K and B12 are stored in the liver. o The liver stores iron in the form of ferritin, which it releases so the body can make new RBCs. o The liver stores and releases copper as needed.  filters the blood o The liver filters certain substances from the blood so that they don’t build up and cause damage. These substances can come from within or outside the body.  Substances that come from within the body include hormones, such as estrogen, aldosterone and diuretic hormone.  Substances that come from outside the body include alcohol and other drugs, such as amphetamines, barbiturates and steroids. Regeneration The liver has the unique ability to regrow parts that have been removed so that it can continue to function in the body.  Up to 80% of liver function can be maintained even after a large part of the liver has been removed.  The regeneration process continues over several months until the missing liver tissue is replaced.
  • 21. 21  The length of time for this process depends on the person’s age, nutrition, if there is any liver damage and how much liver was removed. Transplant surgeons, hepatologists and other researchers are developing liver cell-based regenerative therapies for patients who'd otherwise need whole-liver transplants. The liver has the greatest regenerative capacity of any organ in the body. Liver regeneration has been recognized for many years, dating all the way back to Prometheus in ancient Greek mythology. When the liver is injured beyond its ability to regenerate itself, a liver transplant is the treatment of choice. Transplants are used to treat a wide range of liver conditions, including liver cancer, cirrhotic liver disease, acute liver failure and genetic liver disorders. But as is true for most donor organs, livers are in short supply — the number of people awaiting new livers far exceeds the number of donor livers available. Focus areas Mayo Clinic transplant surgeons, hepatologists and other researchers in the Center for Regenerative Medicine are developing and refining a number of regenerative liver therapies for patients who today must wait for whole-liver transplants.  Living-donor transplants. Liver cancer and advanced cases of cirrhotic liver disease may require liver transplants. Given the shortage of whole livers for transplant, Mayo Clinic's campuses in Minnesota and Arizona have been performing living-donor liver transplants for more than a decade — together, they represent one of the largest such programs in the country. In a living-donor transplant, a portion of a donor's liver is removed and used to replace a patient's diseased liver. After surgery, the donor's liver regenerates back to full size, while the patient's new liver also grows to a normal size.
  • 22. 22 As the safety of living donors is paramount to the success of this program, Mayo Clinic researchers have conducted a long-term assessment of donor outcomes, such as liver regeneration and mental and physical well-being. The study's results were very reassuring, as they showed that Mayo living liver donors do well after donation.  Liver assist devices. Several types of bioartificial livers — devices that perform liver functions for patients with liver failure — have been developed in recent years. These devices support patients as their livers recover from disease or as they await liver transplants. Center for Regenerative Medicine researchers are refining their own version of a bioartificial liver, known as the Spheroid Reservoir Bioartificial Liver. This device contains pig liver cell (hepatocyte) spheroids, which replace a patient's liver function. Research into using human hepatocytes in the device is underway. Read more about Mayo Clinic's bioartificial liver in Discovery's Edge, Mayo's research magazine.  Patient-specific liver cell transplantation. Existing liver cell transplantation procedures used to treat genetic liver diseases do not use patient-specific cells and require immunosuppression. Center for Regenerative Medicine researchers are developing an individualized approach to liver cell transplantation that uses the patient's own cells. With this approach, cells from the patient would be collected, converted to induced pluripotent stem cells in the laboratory and subsequently transformed into hepatocyte-like cells. During this process, gene therapy would be used to correct the genetic defect responsible for the patient's disease. The hepatocyte-like cells would then be transplanted into the liver of a bioengineered pig, where they'd grow into fully functioning, patient-specific human adult hepatocytes that could be transplanted into the patient to regenerate the liver. As the new hepatocytes were originally derived from the patient's own cells, no immunosuppressive drugs would be needed.
  • 23. 23 Processing nutrients absorbed from digestive tract The liver converts glucose into glycogen, its storage form. This glycogen can then be transformed back into glucose if the body needs energy. The fatty acids produced by the digestion of lipids are used to synthesize cholesterol and other substances. The liver also has the ability to convert certain amino acids into others. Despite the wide variety of functions performed by the liver, there is very little specialization among hepatocytes (liver cells). Aside from the macrophages called Kupffer cells in the liver, hepatocytes all seem to be able to perform the same wide variety of tasks. One of the liver's most interesting abilities is self-repair and the regeneration of damaged tissues. In clearing the body of toxins, the liver is damaged by exposure to harmful substances, demonstrating why this capability is important. It also gives hope that if a failing liver can be supported for a certain period of time, it might regenerate and allow the patient to survive and regain a normal life. Hemostasis Glucose Proteins fat and cholesterol Hormones vitamins, in particular fat-soluble ones (A, D, E, K) Synthesis proteins including the clotting factors (~50g/day) bile acids (important in fat digestion) heparin (anti-coagulant) somatomedins (homones that promote growth in bone, soft tissues) Estrogen angiotensinogen Cholesterol acute phase proteins Storage vitamins Glycogen Cholesterol
  • 24. 24 iron, copper Fats Excretion cholesterol, bile acids, phospholipids Bilirubin Drugs poisons including heavy metals Hormones Filtering Poisons nutrients including amino acids, sugars, and fats bilirubin, bile acids IgA Drugs dead or damaged cells in circulatory system Immune excretes IgA into digestive tract Kupffer cells (macrophages) filter out antigens
  • 25. 25 HISTORY OF LIVER TRANSPLANTATION The first human liver transplant was performed in 1963 by a surgical team led by Dr. Thomas Starzl of Denver, Colorado, United States. Dr. Starzl performed several additional transplants over the next few years before the first short-term success was achieved in 1967 with the first one-year survival post transplantation. Despite the development of viable surgical techniques, liver transplantation remained experimental through the 1970s, with one year patient survival in the vicinity of 25%. The introduction of cyclosporin by Sir Roy Calne, Professor of Surgery Cambridge, markedly improved patient outcomes, and the 1980s saw recognition of liver transplantation as a standard clinical treatment for both adult and pediatric patients with appropriate indications. Liver transplantation is now performed at over one hundred centers in the US, as well as numerous centres in Europe and elsewhere. One-year patient survival is 80– 85%, and outcomes continue to improve, although liver transplantation remains a formidable procedure with frequent complications. The supply of liver allografts from non-living donors is far short of the number of potential recipients, a reality that has spurred the development of living donor liver transplantation. The first altruistic living liver donation in Britain was performed in December 2012 in St James University Hospital Leeds. DEFINITION A liver transplant is a surgical procedure to remove a diseased liver and replace it with a healthy liver from a donor. Most liver transplant operations use livers from deceased donors, though a liver may also come from a living donor. PURPOSE A liver transplant is needed when the liver's function is reduced to the point that the life of the patient is threatened
  • 26. 26 DEMOGRAPHICS Compared to whites, those with African-American, Asian, Pacific Islander, or Hispanic descent are three times more likely to suffer from end-stage renal disease (ESRD). Both children and adults can suffer from liver failure and require a transplant. Patients with advanced heart and lung disease, who are human immunodeficiency virus (HIV) positive, and who abuse drugs and alcohol are poor candidates for liver transplantation. Their ability to survive the surgery and the difficult recovery period, as well as their long-term prognosis, is hindered by their conditions. INDICATIONS Liver transplantation is potentially applicable to any acute or chronic condition resulting in irreversible liver dysfunction, provided that the recipient does not have other conditions that will preclude a successful transplant. Uncontrolled metastatic cancer outside liver, active drug or alcohol abuse and active septic infections are absolute contraindications. While infection with HIV was once considered an absolute contraindication, this has been changing recently. Advanced age and serious heart, pulmonary or other disease may also prevent transplantation (relative contraindications). Most liver transplants are performed for chronic liver diseases that lead to irreversible scarring of the liver, or cirrhosis of the liver. Some centers use the Milan criteria to select patients with liver cancers for liver transplantation Cholestatic Diseases: primary biliary cirrhosis, sclerosing cholangitis, secondary biliary cirrhosis, biliary atresia, cystic fibrosis Chronic Hepatitis: hepatitis B, hepatitis C, hepatitis D, autoimmune chronic active hepatitis, cryptogenic cirrhosis, chronic drug toxicity or toxin exposure Alcoholic Cirrhosis: Patients with alcoholic cirrhosis are considered for transplant if they meet current criteria for abstinence and rehabilitation.  Abstinence of alcohol for six months.  Ongoing participation in formal alcohol treatment program.
  • 27. 27  Presence of adequate psychosocial supports as determined by social service and psychiatry consultants. Patients who do not meet the above criteria at the time of referral will be given the opportunity to fulfill these criteria and undergo re-evaluation. Formal input from the psychiatry staff is required to assess the risk of return to alcohol use following liver transplantation.  Metabolic Diseases: hemochromatosis, Wilson's disease, Alpha-1-antitrypsin deficiency, glycogen storage disease, tyrosinemia, familial amyloidotic polyneuropathy, other metabolic disorders treatable by liver replacement.  Fulminant Acute Hepatic Necrosis: viral hepatitis, drug toxicity, toxin, Wilson's disease.  Primary Hepatic Tumors: selected patients with hepatocellular carcinoma. Milan criteria In transplantation medicine, the Milan criteria are applied as a basis for selecting patients with cirrhosis and hepatocellular carcinoma for liver transplantation. The Milan criteria state that a patient is selected for transplantation when he or she has:  one lesion smaller than 5 cm  up to 3 lesions smaller than 3 cm  no extrahepatic manifestations  no vascular invasion CONTRAINDICATIONS While each patient is evaluated on an individual basis, the presence of one or more of the following will frequently preclude acceptance as a candidate for liver transplantation:  HIV infection  Active alcohol or substance abuse  Systemic infections
  • 28. 28  Life-limiting co-existing medical conditions: advanced heart, lung or neurologic conditions.  Uncontrolled psychiatric disorder  Inability to comply with pre- and post-transplant regimens TYPES OF LIVER TRANSPLANTATION METHODS Liver transplant is performed in people who have severely damaged livers or have developed liver failure. These people are usually put on waiting lists for the donor livers to be available for transplant. As soon as a suitable liver is available the next person on the waiting list is contacted. The new liver has to match the recipient’s blood group, tissue type and size. 1-6 From the time the transplant center contacts a potential recipient he or she is advised not to take anything by mouth (not even water) so as to be ready for the operation as early as possible. A liver transplant may be undertaken as soon as the general health check-up of the patient including heart and lung functions are assessed. This surgery is a major one and requires general anesthesia. For general anesthesia to be administered the person needs to remain on an empty stomach and heart and lung functions need to be assessed. TYPES OF LIVER TRANSPLANT There are three different types of liver transplant that may be offered to a person:  Orthotopic transplant or transplant of a liver from a recently deceased donor  A living donor transplant  A split type of liver transplant Orthotopic transplant An orthotopic transplant is the most common type of liver transplant. The whole liver is taken from a recently deceased donor. This is usually from a donor who has pledged his or her organs
  • 29. 29 for donation prior to death and has not transmissible illness or cancers that may be transmitted to the recipient. For the surgery the surgeon makes an incision over the abdomen and removes the diseased liver. The donor liver will then be put in position and all the blood vessels and bile ducts would be connected. The incision is then closed with dissolvable stitches or surgical staples. Drainage tubes are attached to drain away extra fluids. These are left for several days after surgery. Patient is then shifted to the intensive care unit for recovery. Living donor transplant Living donor transplant means the donor is a willing living person. The donor has the operation first in which the surgeon removes either the left or right side (lobe) of their liver. Right lobe transplants are usually recommended for adults while left lobes are used in children. This is because the right lobe is bigger and better suited for adults, while the left lobe is smaller and better suited for children. The recipient is then opened up and the diseased liver is removed. Then the part of the liver taken from the donor is replaced making the connections with blood vessels and bile ducts as in an orthotopic transplant. Following transplantation, the transplanted lobe will quickly regenerate itself. Even for the donor the removed portion of the liver grows back. In the recipient the new lobe usually grows to 85% of the original liver size within a week. Split type of liver transplant Split donation involves transplantation of a liver from a recently deceased individual to two recipients. This is possible if the next suitable recipients are an adult and a child. The donated liver will be split into the left and right lobes. The adult normally receives the larger right lobe and the child will receive the smaller left lobe.
  • 30. 30 As with living donor transplants, the transplanted portions of the liver grow back to the original size by regeneration. This method benefits two persons at a time. Auxiliary liver transplantation Auxiliary liver transplantation is a variety of liver transplantation where the recipient’s own liver is not completely removed. Its purpose is to retain the native liver in case of spontaneous recovery or if there is a potential for future gene therapy in cases of hereditary or metabolic liver diseases (except primary oxalosis, Wilson’s disease or tyrosinaemia in which there is a risk of cancer in the residual liver). Living donor liver transplantation (ldlt) has emerged in recent decades as a critical surgical option for patients with end stage liver disease, such as cirrhosis and/or hepatocellular carcinoma often attributable to one or more of the following: long-term alcohol abuse, long-term untreated hepatitis c infection, long-term untreated hepatitis b infection. The concept of ldlt is based on (1) the remarkable regenerative capacities of the human liver and (2) the widespread shortage of cadaveric livers for patients awaiting transplant. In ldlt, a piece of healthy liver is surgically removed from a living person and transplanted into a recipient, immediately after the recipient’s diseased liver has been entirely removed. Historically, ldlt began as a means for parents of children with severe liver disease to donate a portion of their healthy liver to replace their child's entire damaged liver. The first report of successful ldlt was by dr. Christoph broelsch at the university of chicago medical center in november 1989, when two-year-old alyssa smith received a portion of her mother's liver.[5] surgeons eventually realized that adult-to-adult ldlt was also possible, and now the practice is common in a few reputable medical institutes. It is considered more technically demanding than even standard, cadaveric donor liver transplantation, and also poses the ethical problems underlying the indication of a major surgical operation (hemihepatectomy or related procedure) on a healthy human being. In various case series, the risk of complications in the donor is around 10%, and very occasionally a second operation is needed. Common problems are biliary fistula, gastric stasis and infections; they are more common after removal of the right lobe of the liver. Death after ldlt has been reported at 0% (japan), 0.3% (usa) and <1% (europe), with risks likely
  • 31. 31 to decrease further as surgeons gain more experience in this procedure.[6] since the law was changed to permit altruistic non-directed living organ donations in the uk in 2006, the first altruistic living liver donation took place in britain in december 2012.[7] In a typical adult recipient ldlt, 55 to 70% of the liver (the right lobe) is removed from a healthy living donor. The donor's liver will regenerate approaching 100% function within 4–6 weeks, and will almost reach full volumetric size with recapitulation of the normal structure soon thereafter. It may be possible to remove up to 70% of the liver from a healthy living donor without harm in most cases. The transplanted portion will reach full function and the appropriate size in the recipient as well, although it will take longer than for the donor.[8] Living donors are faced with risks and/or complications after the surgery. Blood clots and biliary problems have the possibility of arising in the donor post-op, but these issues are remedied fairly easily. Although death is a risk that a living donor must be willing to accept prior to the surgery, the mortality rate of living donors in the united states is low. The ldlt donor's immune system does diminish as a result of the liver regenerating, so certain foods which would normally cause an upset stomach could cause serious illness. DIAGNOSIS/PREPARATION The liver starts to fail only when more than half of it is damaged. Thus, once a person demonstrates symptoms of liver failure, there is not much liver function left. Signs and symptoms of liver failure include:  jaundice  muscle wasting (loss of muscle)  forgetfulness, confusion, or coma  fatigue  itching  poor blood clotting  build-up of fluid in the stomach (ascites)  infections  bleeding in the stomach
  • 32. 32 A doctor will diagnose liver disease; a liver specialist, a transplant surgeon, and other doctors will have to be consulted, as well, before a patient can be considered for a liver transplant. Before transplantation takes place, the patient is first determined to be a good candidate for transplantation by going through a rigorous medical examination. Blood tests, consultations, and x rays will be needed to determine if the patient is a good candidate. Other tests that may be conducted are: computed tomography (CAT or CT) scan, magnetic resonance image (MRI), ultrasound, routine chest x ray , endoscopy, sclerotherapy and rubber-band ligation, transjugular intrahepatic portosystemic shunt (TIPS), creatinine clearance, cardiac testing (echocardiogram [ECHO]) and/or electrocardiogram [EKG or ECG]), and pulmonary function test [PFTs]), liver biopsy , and nutritional evaluation. A dietitian will evaluate the patient's nutritional needs and design an eating plan. Since a patient's emotional state is as important as their physical state, a psychosocial evaluation will be administered. Once test results are reviewed and given to the liver transplant selection committee, the patient will be assessed for whether he or she is an appropriate candidate. Some patients are deemed too healthy for a transplant and will be followed and retested at a later date if their liver gets worse. Other patients are determined to be too sick to survive a transplant. The committee will not approve a transplant for these patients. Once a patient is approved, they will be placed on a waiting list for a donor liver. When placed on the waiting list, a patient will be given a score based on the results of the blood tests. The higher a patient's score, the sicker the patient is. This results in the patient earning a higher place on the waiting list. Suitable candidates boost their nutritional intakes to ensure that they are as healthy as possible before surgery. Drugs are administered that will decrease organ rejection after surgery. The medical committee consults with the patient and family, if available, to explain the surgery and any potential complications. Many problems can arise during the waiting period. Medicines should be changed as needed, and blood tests should be done to assure a patient is in the best possible health for the transplant surgery. Psychological counseling during this period is recommended, as well. When a donor is found, it is important that the transplant team be able to contact the patient. The patient awaiting the organ must not eat or drink anything from the moment the hospital calls. On
  • 33. 33 the other hand, the liver may not be good enough for transplantation. Then, the operation will be cancelled, although this does not happen often. Liver donor requirements CT scan performed for evaluation of a potential donor. The image shows an unusual variation of hepatic artery. The left hepatic artery supplies not only left lobe but also segment 8. The anatomy makes right lobe donation impossible. Even used as left lobe or lateral segment donation, it would be very technically challenging in anastomosing the small arteries. Any member of the family, parent, sibling, child, spouse or a volunteer can donate their liver. The criteria for a liver donation include:  Being in good health  Having a blood type that matches or is compatible with the recipient's, although some centres now perform blood group incompatible transplants with special immuno suppression protocols  Having a charitable desire of donation without financial motivation  Being between 18 and 60 years old  Being of similar or bigger size than the recipient  Before one becomes a living donor, the donor must undergo testing to ensure that the individual is physically fit. Sometimes ct scans or mris are done to image the liver. In most cases, the work up is done in 2–3 weeks. Benefits There are several advantages of living liver donor transplantation over cadaveric donor transplantation, including:  Transplant can be done on an elective basis because the donor is readily available  There are fewer possibilities for complications and death than there would be while waiting for a cadaveric organ donor  Because of donor shortages, UNOS has placed limits on cadaveric organ allocation to foreigners who seek medical help in the USA. With the availability of living donor
  • 34. 34 transplantation, this will now allow foreigners a new opportunity to seek medical care in the USA. Controversy over eligibility for alcoholics The high incidence of liver transplants given to those with alcoholic cirrhosis has led to a recurring controversy regarding the eligibility of such patients for liver transplant. The controversy stems from the view of alcoholism as a self-inflicted disease and the perception that those with alcohol-induced damage are depriving other patients who could be considered more deserving.[14] It is an important part of the selection process to differentiate transplant candidates who suffer from alcoholism as opposed to those who were susceptible to moderate non- dependent alcohol use. The latter who retain control of alcohol use have a good prognosis following transplantation. Once a diagnosis of alcoholism has been established, however, it is necessary to assess the likelihood of future sobriety Preservation of the liver before transplantation The OrganOx Metra device is capable of maintaining the liver outside of the body for longer periods than traditional preservation of the organ on ice (which usually can only be done for about 12 hours- 20 at most- before it is damaged unfit for transplantation). The device, which was invented and tested (in two liver transplantations at the hospital) by a team from Oxford University and King's College Hospital, could be ready for use in 2014 after a pilot trial of 20 more transplantations. However this device has not shown that it is superior to cold static storage or hypothermic machine perfusion that has been used successfully at Columbia University and should be commercially available in 2015. DONOR PREPARATION Laboratory Studies These are oriented toward determining the etiology of the disease, excluding HIV and other infections that may compromise a successful LT, and screening for the presence of tumors. The following laboratory tests are those most commonly ordered during a LT evaluation:
  • 35. 35  Liver function tests, total protein, albumin  Hepatitis screen (A, B, C)  Serologies - Cytomegalovirus (CMV), herpes simplex virus (HSV), Epstein-Barr virus (EBV), HIV  Tumor markers  Alpha-fetoprotein, cholinesterase  Arterial blood gases  Others (selective) - Carbohydrate antigen 19-9, cancer antigen 125 Evaluation and workup of prospective liver transplant recipients is as follows: The first step in the process of evaluating a potential candidate for LT is to determine the severity of the liver disease by clinical evaluation. In addition, an objective assessment, to include a comprehensive laboratory and radiological evaluation, is undertaken. The goal of this evaluation is 3-fold. First, it must establish a diagnosis of ESLD; second, it must exclude any absolute or relative contraindication to the proposed procedure; finally, it must assess the suitability and degree of illness of each patient to better allocate resources and optimize survival. The specific tests are outlined below. Once the results are received, specific consultations are sought to clear the patient for LT. Mandatory consultations and clearances are as follows:  Cardiopulmonary clearance  Psychiatrist and social worker consultations  Financial clearance  Nephrologist, infectious diseases specialist, or dentist, as needed One of the most important tools in this scheme is the Child-Turcotte-Pugh (CTP) scoring system, which is the system most widely used to grade the severity of liver disease. A patient is considered to be Child class A if he or she has fewer than 7 points, Child class B if he or she has 7-9 points, and Child class C if he or she has more than 10 points. For listing purposes, a patient must have at least 7 points (ie, be at least a Child class B), according to the minimal listing criteria consensus initially developed when the CTP score was the basis for organ allocation.
  • 36. 36 Today, the CTP score is no longer the basis for organ allocation because this is now based on the Model for End-Stage Liver Disease (MELD) scoring system (see below; also see the MELD Score calculator). Table. CTP Scoring System for Assessment of Severity of Disease (with respect to listing) (Open Table in a new window) Parameter 1 Point 2 Points 3 Points Encephalopathy None Grade 1-2 Grade 3-4 Ascites None Medically controlled Uncontrolled Albumin, g/dL >3.5 2.8-3.5 < 2.8 Bilirubin, mg/dL < 2 2-3 > 3 International normalized ratio < 1.7 1.7-2.3 >2.3 Although a good effort to grade severity of disease, this classification does not reflect the severity of disease in persons with cholestatic diseases, such as primary biliary cirrhosis or primary sclerosing cholangitis (PSC), because the bilirubin limits are significantly higher for these conditions and the other manifestations are not present until very late in the disease. Thus, recent developments in the allocation system are investigating the MELD scoring system as the new basis for organ allocation. Because of the many factors (ie, increasing number of deaths while on liver waiting list, inability to accurately categorize liver patients according to severity of liver disease using the partially subjective CTP classification, reports suggesting that waiting time correlates poorly with death while on the waiting list), a consensus opinion emerged that a revised allocation scheme was needed. The new liver allocation system implemented by the Organ Procurement Transplantation Network in February 2002 is based primarily on the severity of liver disease as assessed by the MELD and Pediatric End-Stage Liver Disease (PELD) survival models for all patients with chronic liver disease.
  • 37. 37 The MELD score is based on 3 biochemical variables, (1) serum bilirubin, (2) serum creatinine, and (3) international normalized ratio, and has been shown in retrospective and prospective studies to be highly predictive of 3-month mortality in patients with chronic liver disease. Similarly, the PELD model for pediatric patients (see below; also see the PELD Score calculator) was developed based on analyses of data from the Study of Pediatric Liver Transplantation database and has been shown retrospectively to be predictive of waiting list mortality in pediatric patients. Model for End-Stage Liver Disease (MELD) scoring system:  Serum creatinine (Log e value) 0.957 o The maximum serum creatinine considered within the MELD score equation is 4.0 mg/dL (ie, for candidates with a serum creatinine >4.0 mg/dL, the serum creatinine level is set to 4.0 mg/dL). o For candidates on dialysis, defined as having 2 or more dialysis treatments within the prior week, or candidates who have received 24 hours of continuous venovenous hemodialysis (CVVHD) within the prior week, the serum creatinine level is automatically be set to 4.0 mg/dL.  Serum bilirubin (Log e value) 0.378  International normalized ratio (INR) (Log e value) 1.120  Using these prognostic factors and regression coefficients, the UNetSM computerized system assigns a MELD score for each candidate based on the following calculation: MELD score = 0.957 x Log e (creatinine mg/dL) + 0. 378 x Log e (bilirubin mg/dL) + 1.120 x Log e (INR) + 0.643. Laboratory values < 1.0 are set to 1.0 for the purposes of the MELD score calculation. [2]  As an example, for a hypothetical candidate with cirrhosis caused by hepatitis C virus who has a serum creatinine concentration of 1.9 mg/dL, a serum bilirubin concentration of 4.2 mg/dL and an INR value of 1.2, the risk score would be calculated as follows: MELD score = (0.957 x Log e 1.9) + (0.378 x Log e 4.2) + (1.120 x Log e 1.2) + 0.643 = 2.0039.  The MELD score for each liver transplant candidate derived from this calculation is rounded to the tenth decimal place and then multiplied by 10. The hypothetical candidate
  • 38. 38 in the example described above, therefore, would be assigned a risk score of 20. The MELD score is limited to a total of 40 points maximum.  Pediatric End-Stage Liver Disease (PELD) scoring system: o Albumin (Loge value) -0.687 o Total bilirubin (Loge value) 0.480 o INR (Loge value) 1.857 o Growth failure (<-2 standard deviations [SD]) 0.667 o Age (< 1 y) 0.436 (Scores for candidates listed for liver transplantation before the candidate’s first birthday continue to include the value assigned for age (< 1 y) until the candidate reaches 24 months of age.) o UNetSM assigns a PELD score for each candidate based on the following calculation: PELD score = 0.436 (age [< 1 y]) – 0.687 x Loge (albumin g/dL) + 0.480 x Loge (total bilirubin mg/dL) + 1.857 x Loge (INR) + 0.667 (growth failure [<-2 SD present]). Laboratory values < 1.0 are set to 1.0 for the purposes of the PELD score calculation.[2] Growth failure is calculated based on age and gender using the current CDC growth chart. o This is a much more precise method of ranking patients; therefore, patients most in need will be given the highest priority for donated livers, rather than simply allocating them to patients who have waited longer but who may be much more stable. The MELD policy replaced status 2A, 2B, and 3 with a continuous scale in February 2002 and is the current basis for liver allocation. Neither of these 2 scoring systems favors all patients, specifically patients with HCCs or exceptional cases. Listing of candidates  Once the workup is complete, the patient and all workup results are presented to the candidate selection committee for a decision about the suitability for transplantation. This committee consists of transplantation surgeons, hepatologists, psychiatrists, social work representatives, cardiologists, pulmonologists, anesthesiologists, and, occasionally, the patient's primary care physician.
  • 39. 39  The following questions are posed to the committee before listing the patient for transplantation: o Does the patient need LT as therapy for his or her disease? o Have the indications and contraindications been properly assessed? o What is the surgical risk? o Is the patient's medical condition such that he or she will be able to tolerate the procedure and postoperative course? o What are the chances of recurrent disease affecting graft and patient survival? Volk et al found that the structure of committee meetings varies by center; however, the process is uniform and primarily involves inductive reasoning to review suitability for transplantation. In their observations, patients were excluded if they were too well, too sick, or too old or had nonhepatic comorbid conditions, substance abuse problems, or other psychosocial barriers. Imaging Studies  Radiography (including chest radiography)  Duplex ultrasonography  Angiogram/magnetic resonance angiography (selective)  Abdominal CT scanning  Cardiopulmonary evaluation  Stress thallium scanning, coronary angiography (as indicated)  Echocardiography In a study comparing the performance of imaging techniques for the detection of hepatocellular carcinoma in pre-liver transplant patients with cirrhosis, contrast-enhanced T1-weighted imaging (CE T1WI) outperformed diffusion-weighted MRI (DWI) with regard to per-patient sensitivity, negative predictive value and per-lesion sensitivity. The latter difference, however, was significant only for lesions between 1 and 2 cm, suggesting that DWI is a reasonable alternative to CE T1WI for detection of hepatocellular lesions above 2 cm.
  • 40. 40 Other Tests  Electrocardiography  Pulmonary function testing Diagnostic Procedures  During the workup of these patients, many tests may be ordered. Specific testing is performed on a case-by-case basis.  In the author's experience, most patients undergo both upper and lower GI endoscopies to evaluate for the presence of esophageal or gastric varices or to exclude GI malignancy.  Other common procedures may include paracentesis in patients with ascites, both for diagnostic purposes (eg, to exclude SBP) and for therapeutic intent (eg, alleviation of distention and hepatohydrothorax).  Many patients undergo a TIPS procedure while awaiting LT because of complications that warrant this approach. These conditions include esophageal or gastric variceal bleeding, refractory ascites, and hepatorenal syndrome (HRS). Histologic Findings  Discussion of all the histopathological findings of the various diseases that lead to ESLD is beyond the scope of this article. In general, they can be classified into 3 broad categories: cirrhosis and fibroticlike states, acute hepatic necrosis, and malignancies. How long is the wait?  The length of time a person may wait for a liver transplant varies, depending on the availability of a compatible donor. The time may be as short as several months to a year or as long as four years. As of September 2003, there were 17,327 candidates on the national waiting list, waiting for a liver transplant.
  • 41. 41 LIVER TRANSPLANT PHYSICIANS AND TEAMS The multidisciplinary liver transplant team at Penn Medicine is comprised of specialists who manage patient care at every stage: from the evaluation visit through the transplant procedure and postoperative care. The program's goal is to provide the best care and restore each patient to a full and productive life. While primarily committed to patient care, the liver transplant team is also actively engaged in clinical and laboratory research designed to improve survival and quality of life for transplant recipients. The following members of the liver transplant team are involved in our patients' care throughout the transplant process: Liver Transplant Surgeons Liver Transplant Hepatologists Transplant Coordinators Procurement Coordinators Living Donor Team Living Donor Advocate Social Workers Financial Coordinator Transplant Nutritionist Transplant Pharmacist Transplant Psychiatrist New Patient Referral Intake Coordinator Transplant Outreach & Communication
  • 42. 42 Clinical Director, Abdominal Organ Transplant. TECHNIQUES OF LIVER TRANSPLANT SURGERY The techniques involved in LDLT and DDLT are in principal the same. In an adult to adult LDLT, a segment of liver equivalent to 60% of the total liver mass is removed from the donor. In an adult to child LDLT, only 25% of the liver suffices. In DDLT, the entire liver is removed and usually the whole organ is transplanted into the recipient. However, in certain ideal cases, the deceased donor liver can be “split” and transplanted into two recipients (the smaller piece going to a child and the larger piece going to another child or small adult). During the LDLT donor “hepatectomy” (surgical removal of the liver), extreme care must be taken to minimize blood loss or injury to critical structures such as bile ducts and blood vessels, and the exact anatomy of these structures should be studied as best as possible prior to even starting the operation. A “total hepatectomy” is performed in the case of DDLT and care must be taken not to injure any critical structures and to properly preserve the organ prior to transplant. The organ recovery surgery (previously referred to as “harvesting” but this term has fallen out of favor: “organ retrieval”, “organ recovery” or “organ procurement” are all acceptable alternatives) often involves recovery of multiple organs including heart, lungs, liver, kidneys, pancreas and intestines, depending on the availability of transplant center expertise, so many different surgical recovery teams might be present. The deceased donor is declared brain dead (two independent
  • 43. 43 clinical exams and confirmatory “apnea tests”) and consent from the family is obtained prior to proceeding with multiorgan recovery. The brain dead patient’s heart and lungs are maintained with mechanical and pharmacologic assistance so even though the patient is legally and medically dead (brain death is irreversible because there is no longer blood flow to the brain and all brain stem functioning has ceased), the heart is still beating at the time of recovery surgery. All of the recovery teams start their organ dissections simultaneously and when it is time to remove the organs from the body, the heart is recovered first, then lungs, then liver, pancreas and kidneys. The heart and lungs can only be outside of the body for 4-6 hours prior to transplant, whereas the liver should be transplanted within 12 hours and the kidneys in less than 24 hours (less than 12 hours is ideal). Special organ preservation solution is used to flush the organs so that they do not become too injured while on ice without their blood supply. The liver transplant procedure itself lasts anywhere between 4-10 hours and involves five major steps. The recipient’s diseased liver is first removed in its entirety. The recipient total hepatectomy, is in fact, the most dangerous part of the surgery because the liver is not functioning properly so the blood does not coagulate well and very large blood vessels such as the inferior vena cava and portal vein must be carefully attended to in order to avoid excessive bleeding. “Hemostasis”, or control of bleeding, is critical during the recipient hepatectomy and requires excellent surgical technique and skilled anesthesia support to rapidly replace blood products (if needed) and maintain “hemodynamic stability” (i.e., normal pulse and blood pressure). Anhepatic Stage - The second phase, the “anhepatic” phase commences after the old liver is removed and before the new liver is reconnected to its blood supply. Many metabolic and bleeding issues need to be managed by the anesthesiologists at this point. The surgeon must quickly connect the veins draining blood from the liver and reestablish portal vein flow into the liver.
  • 44. 44 Reperfusion Stage - The “reperfusion” phase occurs when portal blood inflow and hepatic venous outflow is re-established. This third phase can be accompanied by hemodynamic instability (low blood pressure), high potassium levels (leading to irritation of the heart) and excessive bleeding (depending on the quality of surgical technique). Sometimes it can take several minutes to hours for the new liver to begin functioning properly to synthesize blood clotting factors and to clear acid out of the bloodstream. Arterial Reperfusion Stage – The fourth phase, when the hepatic artery is “anastomosed” (surgically connected) and opened up for more blood to flow into the liver. Fifth phase - When the bile duct is anastomosed. The fourth and fifth phase are usually relatively calm moments during the transplant, but care must be taken to perform these connections properly to avoid complications such as hepatic artery thrombosis or biliary leak or stricture. As a result of improved surgical and anesthetic techniques, effective immunosuppression and anti-infection medicines and practice of true multidisciplinary care, liver transplantation in well selected recipients and donors is extremely successful in the modern transplant era. Both LDLT and DDLT are accepted standards of care in the treatment of end stage liver disease. Postoperative Care First 24 to 48 hrs - Once the surgical operation is over the patient is usually kept in a special intensive care unit where well trained specialist team of intensive care doctors and nurses takes care of the patient to ensure that they are kept stable hemodynamically (blood pressure, oxygenation, fluids and urine output are balanced and maintained. Function of the new liver is monitored closely by blood tests and ultrasound examinations. The liver function tests should demonstrate a trend towards normal during this time. On rare occasions (<2% of the time), the new liver does not start working at all (“primary nonfiction”) or there might be a surgical complication such as hepatic artery thrombosis that requires immediate retransplant.
  • 45. 45 Normally for the first 24 to 48 hours the patient is kept on ventilator (a special machine that keeps the lung expanded and the body well oxygenated) and the patients are kept deeply sedated until it is time to remove the ventilator. Once the ventilator is removed, the patient is fully conscious and can start eating and moving around slowly. During this period a limited number of relatives maybe allowed to see the patient. Postoperative Days (PODs) 3-10 days – Once the patient is extubated (ventilator removed) and stable, he or she can be transferred out of the ICU to the regular liver transplant ward. Here, nurses and doctors ensure adequate pain control and a normal recovery path, regularly monitoring liver function tests and immunosuppression drug levels. The bladder catheter is removed on Postoperative Day #3 and usually the surgical drains are all removed prior to discharge home. The sutures closing the skin incision are not removed until 2-3 weeks after the operation and this is done in the outpatient clinic. When the patient’s liver function tests (and all other labs) normalized and they are ambulating and tolerating a regular diet, the Transplant Pharmacist and/or Transplant Social Worker have teaching sessions with the patient and family to ensure that everyone understands the many different drugs that must be taken, their purpose, their doses and their potential side effects. Also, general discharge advice about avoiding infection and when to return to the outpatient clinic are imparted.
  • 46. 46 POST OPERATIVE CARE Following surgery, the patient will wake up in the surgical intensive care unit (SICU). During this time, a tube will be inserted into the windpipe to facilitate breathing. It is removed when the patient is fully awake and strong enough to breathe on his or her own. There may be other tubes that are removed as the patient recovers. When safe to leave the SICU, the patient is moved to the transplant floor. Walking and eating will become the primary focus. Physical therapy may be started to help the patient become active, as it is an important part of recovery. When the patient begins to feel hungry and the bowels are working, regular food that is low in salt will be given. A patient should expect to spend about 10 to 14 days in the hospital, although some stays may be shorter or longer. Before leaving the hospital, a patient will be advised of: signs of infection or rejection, how to take medications and change dressings, and how to understand general health problems. Infection can be a real danger, because the medications taken compromise the body's defense systems. The doctors will conduct blood tests, ultrasounds, and x rays to ensure that the patient is doing well. The first three months after transplant are the most risky for getting such infections as the flu, so patients should follow these precautions:  Avoid people who are ill.  Wash hands frequently.  Tell the doctor if you are exposed to any disease.  Tell the doctor if a cold sore, rash, or water blister appears on the body or spots appear in the throat or on the tongue.  Stay out of crowds and rooms with poor circulation.  Do not swim in lakes or community pools during the three months following transplant.  Eat meats that are well-cooked.  Stay away from soil, including those in which house-plants are grown, and gardens, during the three months following transplant.  Take all medications as directed.  Learn to report the early symptoms of infection.
  • 47. 47 To ensure that the transplant is successful and that the patient has a long and healthy life, a patient must get good medical care, prevent and treat complications, keep in touch with doctors and nurses, and follow their advice. Nutrition plays a big part in the success of a liver transplant, so what a patient eats after the transplant is very important. MEDICATIONS NEEDED FOLLOWING LIVER TRANSPLANTATION Immunosuppressant drugs Successfully receiving a transplanted liver is only the beginning of a lifelong process. Patients with transplanted livers have to stay on immunosuppressant drugs for the rest of their lives to prevent organ rejection. Like most other allografts, a liver transplant will be rejected by the recipient unless immunosuppressive drugs are used. The immunosuppressive regimens for all solid organ transplants are fairly similar, and a variety of agents are now available .Although many patients can reduce the dosage after the initial few months, virtually none can discontinue drugs altogether. For adolescent transplant recipients, post transplantation is a particularly difficult time, as they must learn to take responsibility for their own behavior and medication, as well as balance their developing sexuality in a body that has been transformed by the adverse effects of immuno-suppression. Long-term outcome and tailoring of immunosuppression is of great importance. Cyclosporine has long been the drug of experimentation in the immunosuppression regimen, and has been well-tolerated and effective. Hypertension, nephrotoxicity, and posttransplant lymphoproliferative disease (PTLD) are some of the long-term adverse effects. Tacrolimus has been developed more recently, and has improved the cosmetic adverse effects of cyclosporine, but has similar rates of hypertension and nephrotoxicity, and possibly a higher rate of PTLD. Prednisone, azathioprine, and tacrolimus are often combined with cyclosporine for better results. Newer immunosuppressive agents promise even better results. There has been a recent, welcome development in renal sparing drugs, such as mycophenolate mofetil, which has no cosmetic adverse effects, does not require drug level monitoring, and is thus particularly attractive to teenagers. If started prior to irreversible renal dysfunction, recent research demonstrates recovery of renal function with mycophenolate mofetil. There is little
  • 48. 48 published data on the use of sirolimus (rapamycin) in the pediatric population, but preliminary studies suggest that the future use of interleukin-2 receptor antibodies may be beneficial for immediate post-transplant induction of immunosuppression. When planning immunosuppression for adolescents, it is important to consider the effects of drug therapy on both males and females in order to maintain fertility and to ensure safety in pregnancy. Adequate practical measures and support should reduce noncompliance in this age group, and allow good, long-term function of the transplanted liver, . Most liver transplant recipients receive corticosteroids plus a calcineurin inhibitor such as tacrolimus or cyclosporin plus a purine antagonist such as mycophenolate mofetil. Clinical outcome is better with tacrolimus than with cyclosporin during the first year of liver transplantation. If the patient has a co-morbidity such as active hepatitis B, high doses of hepatitis B immunoglubins are administrated in liver transplant patients. Liver transplantation is unique in that the risk of chronic rejection also decreases over time, although the great majority of recipients need to take immunosuppressive medication for the rest of their lives. It is possible to be slowly taken off anti rejection medication but only in certain cases. It is theorized that the liver may play a yet-unknown role in the maturation of certain cells pertaining to the immune system. There is at least one study by Thomas E. Starzl's team at the University of Pittsburgh which consisted of bone marrow biopsies taken from such patients which demonstrate genotypic chimerism in the bone marrow of liver transplant recipients. Risks Early failure of the transplant occurs in every one in four surgeries and has to be repeated. Some transplants never work, some patients succumb to infection, and some suffer immune rejection. Primary failure is apparent within one or two days. Rejection usually starts at the end of the first week. There may be problems like bleeding of the bile duct after surgery, or blood vessels of the liver may become too narrow. The surgery itself may need revision because of narrowing, leaking, or blood clots at the connections. These issues may be solved with or without more surgery depending on the severity.
  • 49. 49 Infections are a constant risk while on immunosuppressive agents, because the immune system is supposed to prevent them. A method has not yet been devised to control rejection without hampering immune defenses against infections. Not only do ordinary infections pose a threat, but because of the impaired immunity, transplant patients are susceptible to the same opportunistic infections (OIs) that threaten acquired immune deficiency syndrome (AIDS) patients— pneumocystis pneumonia, herpes and cytomegalovirus (CMV) infections, fungi, and a host of bacteria. Drug reactions are also a continuing threat. Every drug used to suppress the immune system has potential problems. As previously stated, hypertension, nephrotoxicity, and PTLD are some of the long-term adverse effects with immunosupressive drugs like cyclosporine. Immunosuppressants also hinder the body's ability to resist cancer. All drugs used to prevent rejection increase the risk of leukemias and lymphomas. There is also a risk of the original disease returning. In the case of hepatitis C, reoccurrence is a risk factor for orthotropic liver transplants. Newer antiviral drugs hold out promise for dealing with hepatitis. In alcoholics, the urge to drink alcohol will still be a problem. Alcoholics Anonymous (AA) is the most effective treatment known for alcoholism. Transplant recipients can get high blood pressure, diabetes, high cholesterol, thinning of the bones, and can become obese. Close medical care is needed to prevent these conditions. COMPLICATIONS Given the complexity of liver transplantation, it is surprising that complication rates are so low and overall success is so high. The one year survival is 85-90% and at five years it is 70%. Death during the procedure is a rare event, occurring less than 1% of the time. Infections: The most common cause of death after a liver transplant is infection, either a hospital acquired sepsis or an opportunistic infection resulting from the necessity of immunosuppressive drug use. Patients with liver failure tend to be naturally immunosuppressed, mostly as a result of malnutrition, so it is important not to give anti-rejection medicines in too high doses. Simple
  • 50. 50 urinary tract infections or pneumonias can rapidly transform into life threatening infections in the liver transplant recipient. Bleeding: Bleeding is not uncommon in liver transplantation because the liver is a very vascular organ and when the liver is not functioning properly, the blood becomes thin. Surgical bleeding is almost always a controllable situation, even if it means returning the patient to the Operation Theater to correct after the initial transplant. The newly transplanted liver usually starts synthesizing appropriate amounts of coagulation factors within minutes to hours, so postoperative bleeding is often surgical in nature. Biliary leak or Strictures: Biliary leak or strictures occur 30% of the time with Living Donor Liver Transplant (LDLT) and 15% of the time with Deceased Donor Transplant (DDLT). Often, biliary complications can be managed non-surgically with the assistance of Hepatologists using endoscopy or Interventional Radiologists using catheter based approaches. Chronic biliary strictures can cause significant long term morbidity, including bile duct infections (cholangitis) and liver abscesses. Primary Non Function of the Transplanted Liver: Primary Non Function, when the newly transplanted liver does not work at all, is fortunately a rare event (<1%) but requires immediate re-transplant to save the patient. Another complication that may require immediate re-transplant is hepatic artery thrombosis (“HAT”). Hepatic Artery Thrombosis (HAT): occurs in 2-5% of cases and is more common when smaller vessels are being anastomosed (such as with Living Donor Liver Transplant or in pediatric liver transplant). Even if re-transplant is not required, there is significant morbidity associated with long term HAT, including repeated infections of the bile ducts and liver.
  • 51. 51 Venous Complications – of liver transplant include portal vein thrombosis and hepatic venous outflow obstruction. If portal vein thrombosis occurs early after transplant, it must be recognized and treated quickly, usually surgically but sometimes with catheter infusion based treatments by the Interventional Radiologists. Chronic portal vein thrombosis is usually well tolerated but can make re-transplant (if ever required) difficult to impossible. Hepatic venous outflow obstruction occurs when the veins draining blood from the liver into the inferior vena cava are too narrow (usually as a result of surgery), leading to congestion of the liver. If severe and longstanding, this can lead to ascites and renal failure. Incisional Hernia: is quite common after liver transplant because patients with chronic liver failure often have very weak connective tissue as a result of malnutrition. The weak section of the abdomen leads to protrusion of the abdominal contents in the hernia. Incisional hernia rarely causes life threatening complications such as trapped (or “incarcerated”) bowel contents, but chronic discomfort can be easily alleviated with a simple hernia repair surgery. Medical Complications Rejection – After a liver transplantation, there are three types of graft rejection that may occur. They include hyperacute rejection, acute rejection and chronic rejection. Hyperacute rejection is caused by preformed anti-donor antibodies. It is characterized by the binding of these antibodies to antigens on vascular endothelial cells. Complement activation is involved and the effect is usually profound. Hyperacute rejection happens within minutes to hours after the transplant procedure. Unlike hyperacute rejection, which is B cell mediated, acute rejection is mediated by T cells. It involves direct cytotoxicity and cytokine mediated pathways. Acute rejection is the most common and the primary target of immunosuppressive agents. Acute rejection is usually seen within days or weeks of the transplant. Chronic rejection is the presence of any sign and symptom of rejection after 1 year. The cause of chronic rejection is still unknown but an acute rejection is a strong predictor of chronic rejections. Liver rejection may happen anytime after the
  • 52. 52 transplant. Lab findings of a liver rejection include abnormal AST, ALT, GGT and liver function values such as prothrombin time, ammonia level, bilirubin level, albumin concentration, and blood glucose. Physical findings include encephalopathy, jaundice, bruising and bleeding tendency. Other nonspecific presentation are malaise, anorexia, muscle ache, low fever, slight increase in white blood count and graft-site tenderness,when the grafted liver gets rejected by the body and this requires treatment. Usually it requires a biopsy to ascertain that there is rejection, Opportunistic Infections – an immunosuppressed patient is prone to infections and this can result in infections by bacteria or viruses that normally cause no problems to a person. Hospital acquired Vascular Complications: Like Deep Venous Thrombosis or pulmonary embolism. Cardiac complications – like myocardial infarction Neurologic complications – like stroke or due to adverse drug reaction A fine balance of immunosuppression must be maintained: too little and the liver will reject, too much and the patient can easily suffer a life threatening infection. Opportunistic infections are rarer in the current era of transplantation due to excellent prophylaxis regimens, sensitive surveillance tests and effective treatments for diagnosed infections. Other medical complications occur at similar rates as other major surgery patients, but they are poorly tolerated. Attention to detail and vigilance are paramount in the postoperative care of the liver transplant patient. PROGNOSIS Prognosis is quite good, but those with certain illnesses may differ.[3] There is no exact model to predict survival rates; those with transplant have a 58% chance of surviving 15 years.[4] Failure of the new liver occurs in 10% to 15% of all cases. These percentages are contributed to by many complications. Early graft failure is probably due to preexisting disease of the donated organ.
  • 53. 53 Others include technical flaws during surgery such as revascularization that may lead to a nonfunctioning graft. Twenty-five million or one in 10 Americans are or have been afflicted with liver or biliary diseases. As of June 2003, there were 17,239 patients on the UNOS National Transplant Waiting List who were waiting for a liver transplantation. For the previous year (July 1, 2001 to June 30, 2002), there were a total of 5,261 liver transplants performed. Of those, 4,785 were cadaver donors (already deceased) and 476 living donors. For liver transplants performed from July 1, 1999 to June 30, 2001, the one-year survival rate was 86% for adults; 1,861 patients died while on the UNOS waiting list for the year ending June 30, 2002. More than 80% of children survive transplantation to adolescence and adulthood. Since the introduction of cyclosporine and tacrolimus (drugs that suppress the immune response and keep it from attacking and damaging the new liver), success rates for liver transplantation have reached 80–90%. Infections occur in about half of transplant patients and often appear during the first week. Biliary complications are apparent in about 22% of recipient patients (and 6% of donors), and vascular complications occur in 9.8% of recipient patients. Other complications in donors include re-operation (4.5%) and death (0.2%). There are potential social, economic, and psychological problems, and a vast array of possible medical and surgical complications. Close medical surveillance must continue for the rest of the patient's life. PEDIATRIC TRANSPLANTATION In children, living liver donor transplantations have become very accepted. The accessibility of adult parents who want to donate a piece of the liver for their children/infants has reduced the number of children who would have otherwise died waiting for a transplant. Having a parent as a donor also has made it a lot easier for children - because both patients are in the same hospital and can help boost each other's morale.
  • 54. 54 ADVANTAGES OF LIVER TRANSPLANTATION  Liver transplants provide patients a chance for a longer, more active life in the final stages of liver disease or end-stage liver disease.  There’s no question that transplant is a major operation. The recovery can sometimes be the most taxing but anti-rejection medications are making the process easier.  If the transplant is performed before the recipient's health deteriorates, he or she is better able to tolerate the surgery and recovers more quickly.  The donors and recipients recovered quickly, the donors were discharged in about a week and the recipients in 2 to 3 weeks. PATIENT EDUCATION AFTER LIVER TRANSPLANT DIET AND NUTRITION After your liver transplant, you may need to adjust your diet to keep your liver healthy and functioning well and to prevent excessive weight gain. You should maintain a healthy weight, which can help prevent infections, high blood pressure and other complications. Your nutrition specialist (dietitian) and other members of your treatment team will work with you to create a healthy-eating plan that meets your needs and complements your lifestyle. Your dietitian will provide you with several healthy-food options and ideas to use in your eating plan. Your dietitian's recommendations may include:  Eating at least five servings of fruits and vegetables each day  Eating lean meats, poultry and fish  Eating whole-grain breads and cereals and other grains  Having enough fiber in your daily diet  Drinking low-fat milk or eating other low-fat dairy products, to help maintain enough calcium  Maintaining a low-salt and low-fat diet  Following food safety guidelines
  • 55. 55  Avoiding alcohol  Staying hydrated by drinking adequate water and other fluids each day  Avoiding grapefruit and grapefruit juice due to its effect on a group of immunosuppression medications (calcineurin inhibitors) Follow-Up Care to be taken Post Liver Transplantation  After liver transplantation, the patient must frequently visit the transplant surgeon, about 1-2 times a week over about 3 months.  The transplant surgeon and hepatologist monitor the patient's progress through blood tests. After a year of Liver transplantation, follow-up care becomes individualized.  Post transplant, patient will be on several different medications especially Immunosuppression medications which keep the body from fighting off the new organ. You may be on other medications to control blood pressure, Insulin, antibiotics and antivirals, diuretics, and vitamins.  Typically, patients are seen every week for the first month post transplant, and then the frequency is reduced over time.  Additional testing to monitor your health and liver function may vary from patient to patient. Tests may include abdominal scans, ultrasounds, and liver biopsies.  There are few dietary restrictions. The patient is often advised to restrict salt (sodium) intake. A well-balanced diet with adequate protein is necessary. For reasons that are not clear, obesity frequently becomes a problem with liver transplant patients. To avoid this problem, patients should take control of their calorie intake early on.
  • 56. 56 WELCOME TO LIVER TRANSPLANT INDIA
  • 57. 57 LIVER TRANSPLANTATION IN INDIA Dr AS Soin is recognized the world over for pioneering and establishing liver transplantation in India from 1998, when he did the country’s first successful transplant to now, when he leads the country’s largest, and one of the world’s largest and most successful liver transplant programs at Medanta. With over 2500 liver transplants under his belt, he and his team have performed more than 2000 transplants in India. They currently perform 30 liver transplants a month with 95% success - results which are at par with the world's best elsewhere. No wonder, he gets referrals from all over South Asia, Middle East, Far East and Africa, and has transplanted nearly 500 patients from these countries. In addition, he has performed more than 12000 other complex liver, gall bladder and bile duct surgeries in a career spanning 27 years. List of ApprovedHospitals for Liver Transplantation as on 10.07.2015 S.No Name of the Hospital Registration Valid Upto 1 Director of Medical Services, Apollo Hospitals Enterprises Ltd., No.21, Greams Lane, Off.Greams Road, Chennai. 31/08/2016 2 Medical Superintendent, Christian Medial College and Hospital, Vellore 632 004 24.09.2019 3 Chief Operating Officer, Global Hospitals, Global Health City, 439 Cheran Nagar, Perumbakkam, Chennai 600 100 13.05.2019 4 The Dean, Government Stanley Hospital, 27.01.2019
  • 58. 58 Chennai 600 003 5 Medical Director, Sri Ramachandra Medical College and Research Institute, Porur, Chennai-116. 30.09.2014 6 The Chairman, D.D. Hospital and D.D. Medical College, No 66 DD Nagar, Kunavalam Post, Thiruvallur District PIN 631 210 21.03.2015 7 The Madras Medical Mission, 4 A Dr. J. Jayalalitha Nagar, Mogappair, Chennai 600 037 27.12.2015 8 Sri Ramakrishna Hospital 395 Sarojinin Naidu StÏ Siddapudur, Coimbatore 18.05.2016 9 Cethar Hospitals C-108, Fort Station Road, 5th Cross, Thillai Nagar, Trichy 620 018 30.06.2018 10 Kovai Medical Centre and Hospital Ltd Post Box No.3209, Avanashi Road Coimbatore 641 014 16.09.2018 11 Kamakshi Memorial Hospital No.1 Radial Road, Pallikarnai Chennai 600 100 30.09.2018 12 Director of Medical Education and Medical Superintendant, MIOT Hospitals, 4/112, Mount Poonamallee, Manappakkam, Chennai 600 089 16.02.2017 13 Chettinad Hospital and Research Institute IT Highway Kelambakkam 23.04.2018
  • 59. 59 Kanchipuram District 603 103 14 PSG Hospitals Avinashi Road Peelamedu, Coimbatore 641004 01.06.2019 15 Apollo Speciality Hospitals Lake View Road, K.K.Nagar Madurai 625 020 16.12.2019 16 Gem Hospitals 45, Pankaja Mill Road Ramanathapuram, Coimbatore 45 30.11.2019 17 SRM Institute for Medical sciences, No.1, Jawaharlal Nehru Salai, 100 Feet road, Vadapalani, Chennai 600026 05.02.2020 18 SRM Medical College Hosp & Research Centre SRM Nagar, Potheri, Kattankulathur 603203 12.02.2020 Why choose India for Liver Transplantation Liver transplantation in India is performed through cutting- edge clinical solutions, research, extraordinary patient care and infrastructure of world-class standards. This has addressed concerns of many patients and has helped them get rid of complex and most end stage liver diseases.Liver Transplant is a complex surgical exercise and need highly skilled consultants, ingenious technical staff and advanced technology working with perfect harmony, enormous dedication and team work. India offers a one stop solution for all those seeking critical procedures such as Liver transplantation. Cities in India that offers Liver Transplantation at some of the best multi specialty hospitals are as follows; Mumbai Hyderabad Kerala Delhi Pune Goa
  • 60. 60 Bangalore Nagpur Jaipur Chennai Gurgaon Chandigarh What is the Cost of Liver Transplantation in India? Liver transplant cost in India allows people of every class and from every part of the world to avail the best medical care suited to their pocket. Everything from finding a donor and performing the surgery to the prolonged recovery period and lifelong medication, each factor adds to the cost, making liver transplant difficult to afford for some people. Hospitals in India are a perfect destination for medical tourism that combines health treatment with visits to some of the most alluring and awe-inspiring places of the world at an attractively low cost. Other costs associated with transplantation include:  recovery and in-hospital stay  extensive lab tests  anesthesia  fees for transplant surgeons and operating room personnel  organ recovery  transportation to hospital  lodging, transportation and food for family members while the patient is hospitalized  physical therapy and rehabilitation  patient lodging following discharge  anti-rejection drugs and other medications
  • 61. 61 IN KERALA List of Approved Hospitals for Liver Transplantationin Kerala S.No Name of Hospital Address/Contact Details License Valid Until 1 Amrita Institute of Medical Sciences and Research Centre Amrita Lane AIMS Ponekkara Post, Kochi 682 041 Phone: 0484 2801234, 2804321, 4001234 Email: aimsinternational@aims.amrita.edu Website: www.aimshospital.org 02/07/2015 2 Kerala Institute of Medical Sciences P.B.No.1, Anayara P.O, Trivandrum 695 029 Phone: 0471 3041000, 2447575 Email: relations@kimskerala.com Website: www.kimskerala.com 03/01/2018 3 Lakeshore Hospital NH 47 Bypass, Maradu, Nettoor P.O, Kochi 682 040 Phone: 0484-2701032/2701033 Email: info@lakeshorehospital.com Website: www.lakeshorehospital.com 19/05/2015 4 Malabar Institute of Medical Sciences Ltd. Mini By-pass Road, Govindapuram P.O, Calicut 673 016 Phone: 0495 - 2744000 Email: mimsclt@mimsindia.com Website: www.mimsindia.com 19/12/2017 5 Medical Trust Hospital MG Road, Kochi 682 016 Phone: 0484 2358001 09/05/2017
  • 62. 62 S.No Name of Hospital Address/Contact Details License Valid Until Email: medtrust@vsnl.com Website: www.medicaltrusthospital.com COST OF A LIVER TRANSPLANTATION As of 1997, the cost of a liver transplant in the United States was $314,500, including the evaluation, procurement of the liver, hospitalization, physician fees and follow-up care and medications for the first year. As of 2002, the cost of a liver transplant in the United States averaged about $250,000 for immediate hospital and doctor expenses. Necessary pre- and post- operative expenses brought the total to about $314,500. In some cases Medicare provides coverage for liver transplants for some causes of liver failure. Talk to your transplant center to see if they are Medicare approved and you meet the criteria for a Medicare covered transplant. If you have private insurance, you should check with your insurance representative about whether your policy covers liver transplants. This may help to pay some of the costs.
  • 64. 64 REVIEW OF LITERATURE Partial liver transplantation-living donor liver transplantation and split liver transplantation Sascha A. Müller ,Arianeb Mehrabi , Bruno M. Schmied Abstract In the last two decades, liver transplantation (LTx) has become the treatment of choice for several liver diseases including hepatocellular carcinoma in selected cases. Improvements in surgical and anesthesiological procedures have increased patient survival after LTx, resulting in excellent 1-year survival rates. The rate-limiting factor to further increase the number of LTx is the extreme shortage of suitable organs with the consequence that pediatric and adult patients are dying on the waiting list. At present, mortality reported for pediatric and adult patients on the waiting list is 10 to 20%. Living-donor liver transplantation and split liver transplantation are measurements to reduce the severe lack of cadaveric grafts by expanding the donor pool. Major centers around the world now routinely perform partial LTx in infants and adults with survival success equivalent to that after full-size liver transplantation. Frequency and Outcomes of Liver Transplantation for Nonalcoholic Steatohepatitis in the United States Michael R. Charlton,Justin M. Burns,Rachel A. Pedersen,Kymberly D. Watt,Julie K. Heimbach,Ross A. Dierkhising Background & Aims The relative frequency of nonalcoholic steatohepatitis (NASH) as an indication for liver transplantation and comparative outcomes following transplantation are poorly understood.
  • 65. 65 Methods We analyzed the Scientific Registry of Transplant Recipients for primary adult liver transplant recipients from 2001 to 2009. Results From 2001 to 2009, 35,781 patients underwent a primary liver transplant, including 1959 for who NASH was the primary or secondary indication. The percentage of patients undergoing a liver transplant for NASH increased from 1.2% in 2001 to 9.7% in 2009. NASH is now the third most common indication for liver transplantation in the United States. No other indication for liver transplantation increased in frequency during the study period. Compared with other indications for liver transplantation, recipients with NASH are older (58.5 ± 8.0 vs 53.0 ± 8.9 years; P < .001), have a larger body mass index (>30 kg/m2) (63% vs 32%; P < .001), are more likely to be female (47% vs 29%; P < .001), and have a lower frequency of hepatocellular carcinoma (12% vs 19%; P < .001). Survival at 1 and 3 years after liver transplantation for NASH was 84% and 78%, respectively, compared with 87% and 78% for other indications (P = .67). Patient and graft survival for liver recipients with NASH were similar to values for other indications after adjusting for level of creatinine, sex, age, and body mass index. Conclusions NASH is the third most common indication for liver transplantation in the United States and is on a trajectory to become the most common. Outcomes for patients undergoing a liver transplant for NASH are similar to those for other indications. Living Donor Liver Transplantation for High MELD Score Patients H. Chou, C. Lee, R. Soong, T. Wu, T. Wu, K. Chan, W. Lee Background: Liver transplantation is the only effective treatment for the very sick liver failure patients. For the success of liver transplantation, it is better to have good donors for very sick patients. However, liver donation is very short in Asian countries. Liver donor liver transplantation is the only way to rescue the very sick patients. The aim of this study is to