Liver transplantation

Graft rejection

After a liver transplantation, immune-mediated rejection (also known as rejection) of the allograft may happen at any time. Rejection may present with lab findings: elevated AST, ALT, GGT; abnormal liver function values such as prothrombin time, ammonia level, bilirubin level, albumin concentration; and abnormal blood glucose. Physical findings may include encephalopathy, jaundice, bruising and bleeding tendency. Other nonspecific presentation may include malaise, anorexia, muscle ache, low fever, slight increase in white blood count and graft-site tenderness.^{[citation needed]}

Three types of graft rejection may occur: 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.
• Acute rejection is mediated by T cells (versus B-cell-mediated hyperacute rejection). 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 one year. The cause of chronic rejection is still unknown, but an acute rejection is a strong predictor of chronic rejections.

Biliary complications

Biliary complications include biliary stenosis, biliary leak, and ischemic cholangiopathy. The risk of ischemic cholangiopathy increases with longer durations of cold ischemia time, which is the time that the organ does not receive blood flow (after death/removal until graft placement).^[2] Biliary complications are routinely treated with Endoscopic Retrograde Cholangiopancreatography (ERCP), percutaneous drainage, or sometimes re-operation.^[5]

Vascular complications

Vascular complications include thrombosis, stenosis, pseudoaneurysm, and rupture of the hepatic artery.^[1] Venous complications occur less often compared with arterial complications, and include thrombosis or stenosis of the portal vein, hepatic vein, or vena cava.^[1]

Cooling

Between removal from donor and transplantation into the recipient, the allograft liver is stored in a temperature-cooled preservation solution. The reduced temperature slows down the process of deterioration from normal metabolic processes, and the storage solution itself is designed to counteract the unwanted effects of cold ischemia. Although "static" cold storage method has long been standard technique, various dynamic preservation methods are under investigation. For example, systems which use a machine to pump blood through the explanted liver (after it is harvested from the body) during a transfer have met some success ^{[citation needed]}(see Research section for more).

Living donor transplantation

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 use disorder, 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.^{[citation needed]}

Historically, LDLT began with terminal pediatric patients, whose parents were motivated to risk donating a portion of their compatible healthy livers to replace their children's failing ones. The first report of successful LDLT was by Silvano Raia at the University of São Paulo Faculty of Medicine in July 1989.^{[9][page needed][10]} It was followed by 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.^[11] 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 to decrease further as surgeons gain more experience in this procedure.^[12] 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.^[13]

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.^[14]

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.^{[medical citation needed]}

Donor requirements

Any member of the family, parent, sibling, child, spouse or a volunteer can donate their liver. The criteria^[15][16] for a liver donation include:

• Being in good health^[15]
• Having a blood type that matches or is compatible with the recipient's,^[15] although some centres now perform blood group incompatible transplants with special immunosuppression protocols.^{[medical citation needed]}
• Having a charitable desire of donation without financial motivation^[15]
• Being between 20 and 60 years old^[15] (18 to 60 years old in some places^[16])
• Have an important personal relationship with the recipient^[16]
• Being of similar or larger size than the recipient^[16]
• Before one becomes a living donor, the donor must undergo testing to ensure that the individual is physically fit, in excellent health, and not having uncontrolled high blood pressure, liver disease, diabetes or heart disease.^[16] Sometimes CT scans or MRIs are done to image the liver. In most cases, the work up is done in 2–3 weeks.^{[citation needed]}

Pediatric transplantation

In children, living liver donor transplantation has 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.^[19]

Post-transplant immunosuppression

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. Most liver transplant recipients receive corticosteroids plus a calcineurin inhibitor such as tacrolimus or ciclosporin, (also spelled cyclosporine and cyclosporin) plus a purine antagonist such as mycophenolate mofetil. Clinical outcome is better with tacrolimus than with ciclosporin during the first year of liver transplantation.^[22][23] If the patient has a co-morbidity such as active hepatitis B, high doses of hepatitis B immunoglubins are administered in liver transplant patients.^{[citation needed]}

Due to both the pharmacological immunosuppression and the immunosuppression of underlying liver disease, vaccinations against vaccination-preventable diseases are highly recommended before and after liver transplantation. Vaccine hesitancy in transplant recipients is less than in the general population.^{[24] [25]} Vaccinations are preferably administered to the recipient before the transplant, as post-transplant immunosuppression leads to reduced vaccine effectiveness.^[5]

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.^{[medical citation needed]} 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.^{[citation needed]}

Famous liver transplant recipients

See also: Category:Liver transplant recipients and List of organ transplant donors and recipients

• Eric Abidal (born 1979), French footballer (Olympique Lyonnais, FC Barcelona), transplant in 2012
• Gregg Allman (1947–2017), American musician (The Allman Brothers Band), transplant in 2010 (survival: 7 years)
• George Best (1946–2005), Northern-Irish footballer (Manchester United), transplant in 2002 (survival: 3 years)
• David Bird (1959–2014), American journalist (The Wall Street Journal), transplant in 2004 (survival: 10 years)
• Jack Bruce (1943–2014), Scottish musician (Cream), transplant in 2003 (survival: 11 years)
• Frank Bough (1933–2020), English television presenter, transplant in 2001 (survival: 19 years)
• Robert P. Casey (1932–2000), American politician (42nd Governor of Pennsylvania), transplant in 1993 (survival: 7 years)
• David Crosby (1941–2023), American musician (The Byrds, Crosby Stills, Nash (& Young)), transplant in 1994 (survival: 28 years)
• Gerald Durrell (1925–1995), British zookeeper (Durrell Wildlife Park), transplant in 1994 (survival <1 year)
• Vaughn Eshelman (1969–2018), American Major League Baseball pitcher (Boston Red Sox), transplant in 2018 (survival <6 months)
• Shelley Fabares (born 1944), American actress (The Donna Reed Show, Coach) and singer ("Johnny Angel"), transplant in 2000
• Freddy Fender (1937–2006), American musician ("Before the Next Teardrop Falls," "Wasted Days and Wasted Nights"), transplant in 2004 (survival: 2 years)
• "Superstar" Billy Graham (1943–2023), American wrestler (WWF), transplant in 2002 (survival: 20 years)
• Larry Hagman (1931–2012), American actor (Dallas, Harry and Tonto, Nixon, Primary Colors), transplant in 1995 (survival: 17 years)
• Dahlan Iskan (born 1951), Indonesian minister, transplant in 1987
• Steve Jobs (1955–2011), American businessman (Apple Inc.), transplant in 2009 (survival: 2 years)
• Chris Klug (born 1972), American snowboarder, transplant in 2000
• Evel Knievel (1938–2007), American stunt performer, transplant in 1999 (survival: 8 years)
• Chris LeDoux (1948–2005), American musician and rodeo champion, transplant in 2000 (survival: 5 years)
• Kyung Won Lee (born 1928), Korean-American journalist, transplant in 1992
• Phil Lesh (1940-2025), American musician (Grateful Dead), transplant in 1998 (Survival: 16 years)
• Linda Lovelace (1949–2002), American pornographic actress (Deep Throat), transplant in 1987 (survival: 15 years)
• Mickey Mantle (1931–1995), American baseball player (New York Yankees), transplant in 1995 (survival: <1 year)
• Mike MacDonald (1954–2018), Canadian comedian and actor (Mr. Nice Guy), transplant in 2013 (survival: 5 years)
• Jim Nabors (1930–2017), American actor (The Andy Griffith Show), transplant in 1994 (survival: 23 years)
• John Phillips (1935–2001), American musician (The Mamas & the Papas), transplant in 1992 (survival: 9 years)
• James Redford (1962–2020), American documentary filmmaker and environmentalist, transplant in 1993 (survival: 27 years)
• Lou Reed (1942–2013), American musician (The Velvet Underground), transplant in 2013 (survival: <1 year)
• U. Srinivas (1969–2014), Indian musician, transplant in 2014 (survival: <1 year)
• Mike IX Williams (1968), American vocalist and songwriter (Eyehategod), transplant in 2016

Cooling

There is increasing interest in improving methods for allograft preservation following organ harvesting. The standard "static cold storage" technique relies on flushing a liver with a preservation solution and then placing it in static cold storage at a decreased temperature (usually 4 degrees Celsius) to slow down anaerobic metabolic breakdown.^[5] An alternative method involves machine perfusion, in which oxygenated, preservation solutions are continually pumped through the liver prior to transplantation. This is currently being investigated with cold (hypothermic), body temperature (normothermic), and under body temperature (subnormothermic) preservation solutions. Hypothermic machine perfusion has been used successfully at Columbia University and at the University of Zurich.^[30][31] A randomized controlled clinical trial comparing normothermic machine preservation with conventional cold storage showed less donor liver injury, less discarded donor livers (due to suboptimal condition), better early function, and longer preservation times compared with static cold stored livers. Graft survival and patient survival after transplant were similar with both approaches.^[32] Machine perfusion prior to transplant is associated with decreased tissue re-perfusion ischemic injury (a process in which liver cells are damaged as a statically stored liver is re-perfused after transplant) as well as a decreased risk of intrahepatic biliary strictures.^[5]

A 2014 study showed that the liver preservation time could be significantly extended using a supercooling technique, which preserves the liver at subzero temperatures (-6 °C)^[33]

Normothermic Regional Perfusion

Donation after circulatory death (DCD) has become an increasingly important source of organs for transplantation, with categories ranging from uncontrolled to controlled DCD (cDCD) donors. Despite its growing use, DCD organs generally suffer from warm ischemia injuries, leading to fewer and lower-quality organs compared to those from donation after brain death (DBD).^[34] To mitigate these issues, there has been a rising interest in normothermic regional perfusion (NRP), a technique that temporarily restores oxygenated blood flow to organs after death, thereby improving their viability prior to recovery.^{[citation needed]}

NRP works by reversing the detrimental effects of warm ischemia on cellular energy substrates and antioxidants, thereby reconditioning the organs before transplantation. This technique, often facilitated by extracorporeal membrane oxygenation (ECMO) technology, allows for organ assessment and optimization, reducing the risk of graft failure.^[34] NRP can be established either abdominally or thoracoabdominally, depending on the intended organs for transplantation, with specific techniques and monitoring protocols in place to ensure optimal outcomes. Clinical outcomes of NRP in DCD organ transplantation have shown promising results, particularly in kidney and liver transplantation, with lower rates of complications and improved graft survival compared to traditional preservation methods.^[34] Through the utilization of NRP, Dr. Fondevila et al. at Hospital Universitario La Paz have achieved successful transplantation of livers that have undergone extensive warm ischemic periods of up to 2.5 hours prior to recovery.^[35] This has resulted in biliary complication and graft survival rates comparable to those observed in controlled DCD livers that have experienced significantly less warm ischemia.^[36]

While ethical considerations remain, especially regarding the use of NRP in controlled DCD scenarios, ongoing research aims to address these concerns and expand the application of NRP to other organ types, ultimately increasing the availability of viable organs for transplantation and improving outcomes for patients with end-stage organ disease^{[citation needed]}

Herpesvirus 6 Reactivation

A study published in The Journal of Infectious Diseases in 2024 investigated the reactivation of inherited chromosomally integrated human herpesvirus 6 (iciHHV-6B) in a liver transplant recipient and its impact on the graft. The research, conducted by Hannolainen et al., utilized hybrid capture sequencing and various molecular techniques to analyze the viral sequences and host immune response. The findings demonstrated active replication of iciHHV-6B within the graft tissue and significant immune activation, suggesting the pathological impact of viral reactivation on transplant outcomes. The study highlights the importance of monitoring iciHHV-6 reactivation in liver transplant recipients.^[37]

Alcohol dependence

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.^[38] It is an important part of the selection process to differentiate transplant candidates who have alcohol use disorder as opposed to those who were susceptible to non-dependent alcohol use. The latter who gain 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.^[39]

HIV

Historically, HIV was considered an absolute contraindication to liver transplantation. This was in part due to concern that the infection would be worsened by the immunosuppressive medication which is required after transplantation.^[4]

However, with the advent of highly active antiretroviral therapy (HAART), people with HIV have much improved prognosis. HIV controlled with HAART is no longer a contraindication to liver transplantation.^[5] Uncontrolled HIV disease (AIDS) remains an absolute contraindication.^[5]

Medical cannabis

Medical criteria for transplant often require "lack of substance abuse". The changing status of cannabis has resulted in many patients who never abused any substance – merely used one – either being turned down for transplants, forced to stop a useful medicine suggested by their doctors, or both.^{[citation needed]}

For example, in 2011, Cedars-Sinai Medical Center denied a liver transplant to medical cannabis patient Norman Smith. They removed Mr. Smith from a transplant waiting list for "non-compliance of our substance abuse contract",^[40] despite his own oncologist at Cedars-Sinai having recommended that he use the cannabis for his pain and chemotherapy.^[41] Dr. Steven D. Colquhoun, director of the Liver Transplant Program, said that the hospital "must consider issues of substance abuse seriously", but the transplant center did not seriously consider whether Mr. Smith was "using" cannabis versus "abusing" it.^[42] In 2012, Cedars-Sinai denied a liver transplant to a second patient, Toni Trujillo, after her Cedars-Sinai doctors knew and approved of her legal use of medical cannabis. In both cases, the patients acceded to the hospital's demand and stopped using cannabis, despite its therapeutic benefits for them, but were both sent back to the bottom of the transplant list.^[43][44] Smith's death inspired Americans for Safe Access to lobby for the California Medical Cannabis Organ Transplant Act (AB 258), which was enacted in July 2015 to protect future patients from dying at the hands of medical establishments prejudiced against the legal use of medical cannabis.^[45]