• 1.

  Indications for liver transplant in patients infected with hepatitis C virus and pre-transplant factors in potential recipients

  • •

    Given the worse diagnosis in these patients, strict selection criteria should be followed for liver transplant recipients with hepatocarcinoma associated with HCV (Class I-Level B) (Table 1).

  • •

    Age, diabetes, metabolic syndrome, and response to combined antiviral treatment should all be taken into account before indicating liver transplant in patient with HCV infections (Class I-Level B).

• 2.

  Donor/surgical and transplant factors

  • 2.1

    Donor age (Tables 2 and 3)

    • •

      Although there is sufficient scientific evidence to show that the age of the liver donor is the most important independent factor that negatively affects the severity of HCV recurrence, as well as the survival of the graft and the patient, we cannot identify a clear cut-off point for donor age after which they would not be suitable for HCV cirrhotic recipients.

    • •

      The preferential assignment of young liver donors to patients infected with HCV could be a detriment to other patients without HCV infections, and taking into account that a large proportion of the donor population is aging, this could result in increased mortality rates for HCV patients on the waiting list.

    • •

      The recommendation was made that transplant groups study the impact of the age of the donor on recipient survival in patients with and without HCV.

    Table 2.

    Survival of the First Graft Based on Donor Age in Adult Patients With HCV Cirrhosis (Excluding Hepatocarcinomas). Elective Transplants (1984–2009).

    Survival of the 1st Graft (%)	1 Month	1 Year	3 Years	5 Years	10 Years	15 Years
    Donor age
    16–19 years (266)	92.8	83.7	78.6	70.3	60.1	48
    20–24 years (283)	87.9	75.4	69	65.2	56	43.5
    25–29 years (201)	90	79	73.1	65.4	56	45.8
    30–34 years (231)	93.9	82.5	77.2	70.1	58.4	52.1
    35–39 years (235)	91.5	83.2	73.1	69.2	57.3	43.2
    40–44 years (236)	92.3	76.5	63.2	58.8	44	29.9
    45–49 years (336)	90.1	77.6	65.7	53.7	38.1	34.2
    50–54 years (307)	93.1	76.7	65	58.2	41.2	27.3
    55–59 years (315)	93.3	75.3	62.5	57	43.5	33.8
    60–64 years (319)	90.6	75.2	61.7	50.5	27.4	–
    65–69 years (261)	90.4	71.5	55	45.9	25.1	–
    70–74 years (206)	87.3	70.7	57.3	43.7	33.4	–
    75–79 years (126)	90.5	69.3	48	42.8	29.3	–
    >.80 years (40)	75	58.7	34.3	34.3	25.7	–

    Report by Gloria de la Rosa. Date: January 2011. Source: RETH.
    Table 3.

    Survival of the First Graft Based on Donor Age in Adult HCV (–) Patients (Excluding Hepatocarcinomas) in Adults. Elective Transplants (1984–2009).

    Survival of the 1st Graft	1 Month	1 Year	3 Years	5 Years	10 Years	15 Years
    Donor age
    16–19 years (546)	92.3	82.4	76	72.6	62.3	55
    20–24 years (618)	92.4	82.2	77	72.4	62	49.5
    25–29 years (485)	89.5	79	72.7	69	59.8	52.3
    30–34 years (390)	90.2	79.2	71.7	66.2	54	50.2
    35–39 years (421)	90.5	79	74.3	69.2	57.2	47
    40–44 years (481)	89	78.4	71.5	68.8	57.9	46.8
    45–49 years (567)	90.6	78.4	72	67.8	56.1	44
    50–54 years (594)	90.6	79.9	71.5	67.7	57	44.5
    55–59 years (581)	90.7	80.8	74.9	68.5	55.5	40.3
    60–64 years (536)	91.8	83	75.6	69.8	54.8	43.9
    65–69 years (497)	92.5	82.6	75.2	71.8	57	44.9
    70–74 years (437)	94.9	79.2	71.7	66.2	54	50.2
    75–79 years (289)	95.5	81.3	72.2	65.7	50.6	–
    >.80 years (72)	89	83.2	74.3	69.5	69.5	–

    Report by Gloria de la Rosa. Date: January 2011. Source: RETH.
  • 2.2

    Ischaemia time

    • •

      Prolonged duration of ischaemia negatively impacts the severity of HCV recurrence, as well as the survival of the graft and patient.

    • •

      Cold ischaemia should be limited to less than 8h, and/or hot ischaemia should be limited to less than 90min.

  • 2.3

    Anti-HCV donors (+)

    • •

      Donors with HCV infections can be used for cirrhotic patients with HCV infections under the following conditions: donor age <56 years, normal hepatic biochemistry tests, ultrasound results, and visual inspection of the liver, and the recipient must have a genotype 1b HCV infection.

    • •

      The duration of ischaemia should be minimised as much as possible.

    • •

      Although liver biopsies are recommended, we should not wait for the results if ischaemia was to exceed the 8h mark.

  • 2.4

    Other factors

    • •

      We have no recommendations to make regarding other variables such as stenosis, donor–recipient HLA-DR compatibility, the use of non-heart beating donors, or partial grafts from in vivo or split donors.

• 3.

  Viral factors

  Infection from cytomegalovirus should be closely monitored in order to detect and treat it early (Class IIa-Level B).

• 4.

  Recipient factors: metabolic syndrome/diabetes/insulin resistance (post-transplant)

  Effective treatment should be given for diabetes and other components of metabolic syndrome in an attempt to improve the evolution of post-transplant recurrent hepatitis C (Class I-Level B).

• 5.

  Biochemical and histological patterns of recurrence and early histological findings (first 12 months post-transplant)

  • •

    The higher risk of evolution towards cirrhosis can be predicted using the biochemical and histological pattern of recurrence (Class I-Level B).

  • •

    Biochemical cholestasis and/or jaundice at the moment of recurrence are associated with a higher risk of developing cirrhosis (Class I-Level B).

  • •

    Histological findings from a biopsy taken within 12 months of the transplant are very useful for predicting the risk of developing cirrhosis (Class I-Level B).

  • •

    Moderate/severe inflammation and/or fibrosis pose a high risk of developing cirrhosis and the need for starting anti-viral treatment (Class I-Level B).

• 6.

  Biliary complications

  Although there is some controversy regarding the possible influence of biliary complications on the more severe progression of histological lesions from HCV, we recommend an active attitude towards the detection and early treatment of biliary stenosis in order to minimise the negative effects this may have on the development of recurrent HCV hepatitis (Class IIb-Level B).

• 1.

  Role of immunosuppression in the natural history of recurrent hepatitis C

  • 1.1

    Calcineurin inhibitors

    Based on the data currently available, we cannot recommend the use of specific calcineurin inhibitors (CNI), since no differences have been found in graft or patient survival, or in the evolution of recurrent hepatitis C (Class I-Level A).

  • 1.2

    Corticosteroids

    • •

      We recommend avoiding the use of steroid boluses in mild-moderate rejection cases (Class IIa-Level B).

    • •

      Non-steroid treatment plans are safe in patients infected with HCV (Class IIa-Level B).

    • •

      If corticosteroids are used, we recommend progressive withdrawal of the treatment after sixth months (Class IIa-Level B).

  • 1.3

    Role of other immunosuppressive drugs (IS): mycophenolate, azathioprine, mammalian target of rapamycin inhibitors, and interleukin-2 receptor antibodies

    • •

      The use of treatment protocols that include mycophenolate mofetil, non-steroid treatments, or interleukin-2 receptor antibodies does not influence mid-term recurrence severity (Class IIa-Level B).

    • •

      There is no optimal protocol for immunosuppression in patients with HCV infections. The only concrete recommendation is to avoid a state of over-immunosuppression. To this end, we recommend avoiding corticosteroids in boluses and triple or quadruple treatments at full doses (Class I-Level B).

• 2.

  The role of immunosuppression in the response to anti-viral treatment

  The modification of IS treatment has not shown any impact on sustained virological response (SVR), and should be modified according to the toxicity profile in each IS (Class IIa-Level B).

• •

  We recommend anti-viral treatment in all patients on the transplant waiting list that are in a compensated state and class A on the Child-Pugh scale, regardless of the patient's genotype and viral load, as long as contraindications are not present and the patient has responded to previous combined anti-viral treatment (Class I-Level B).

• •

  We also recommend treating patients with functional class A–B on the Child-Pugh scale and a “model for end-stage liver disease” (MELD) score <18, with a good virological response profile (naïve, genotypes 2–3, or genotypes 1–4 with low viral load) (Class I-Level B).

• •

  Treatment is contraindicated in all patients with a functional class C on the Child-Pugh scale or MELD≥18 (Class I-Level B).

• •

  The treatment of choice is a combination of pegylated interferon-alpha and ribavirin at standard doses (Class I-Level C).

• •

  We also recommend the use of growth factors (erythropoietin and granulocyte colony-stimulating factor) if necessary (Class IIa-Level C).

• •

  Anti-viral treatment in liver transplants must be carried out by doctors dedicated to the transplant, or doctors with close contact with the transplant centre (Class I-Level C).

• •

  Post-liver transplant anti-viral treatment is based on the same drugs as those used in immunocompetent patients. However, in order to optimise results, the treatment may not involve the same duration, dosage, rules for early interruption, or the use of growth factors (Class I-Level A).

• •

  In genotypes 2–3, there are no data that indicate that treatment should be shortened (Class I-Level C).

• •

  The absence of an early virological response (EVR) predicts the absence of a response to 12-month-therapies (Class I-Level B).

• •

  Prolonging treatment may be beneficial in some situations. As such:

  • o

    In patients with mild histological lesion and no EVR, anti-viral treatment should be suspended (Class I-Level C).

  • o

    Prolongation/maintenance of treatment may be justified in patients with advanced histological lesions and/or poor prognostic factors, clinical improvement and/or biochemical response, and who tolerate the treatment (Class II-Level C).

• •

  The modification of IS treatment has not been shown to impact SVR, and should be modified according to the toxicity profile of each IS (Class II-Level A).

• •

  Immunosuppression levels should be strictly monitored (Class I-Level C).

• •

  Anti-viral treatment does not imply any modifications to the therapeutic range of IS (Class I-Level C).

• •

  A liver biopsy must be taken before commencing anti-viral treatment (Class I-Level B).

• •

  Treatment is recommended in severe acute cases of hepatitis and in cholestatic hepatitis (Class I-Level B).

• •

  The severity of the hepatitis C infection must be serially evaluated (Class I-Level B).

• •

  Liver biopsy is the gold standard for evaluating the severity of post-transplant recurrent hepatitis C (Class I-Level B).

• •

  A liver biopsy should also be taken 12 months after transplant (Class I-Level B).

• •

  Elastography has been shown to be the non-invasive method with the greatest capacity to identify significant fibrosis and portal hypertension in this context, and can serve as an adequate alternative to biopsy for following the evolution of post-transplant hepatitis C (Class I-Level A).

• •

  Liver retransplantation is not contraindicated in patients infected with HCV.

• •

  We recommend using the “Rosen Score” for determining the indications for retransplantation in these patients.

• •

  In patients with a Rosen score ≥20.5, retransplantation is contraindicated since expected survival after one year is less than 50%.

Liver transplants have spread throughout the world in the last 25 years, with current survival rates close to 95% at one year and above 80% after 5 years. In Spain, in spite of the high rate of cadaveric donation, the number of donors does not meet the needs of recipients. Living-donor liver transplant (LDLT), which was developed especially in Eastern countries due to a lack of cadaveric donors, was quickly extended to Western countries. In Spain, approximately 300 living-donor transplants have been performed, half of these being paediatric cases, with no changes in recent years. This type of transplant represents little over 2% of transplants. In Spain as in other countries, the tendency for this type of transplant is decreasing, contrary to the trend in live kidney transplants.

The results from LDLT are better than those obtained with cadaveric donors, mortality rates on the waiting list appear to remain stable, and in 2010, the possibility of receiving a transplant within one year of entering the waiting list was below 50% in Spain. Additionally, satisfaction surveys filled out by donors revealed that less than 4% feel pressured to donate, and the vast majority are content to have donated.41 The question, then, why is LDLT is on the decrease? Firstly, the almost universal implementation of severity-based prioritisation (model for end-stage liver disease [MELD]) has considerably reduced the urgency of donations, since the patients at the highest risk of death are placed higher on the waiting list.42 Even so, using living donors reduces waiting list mortality rates still more.43 On the other hand, donor morbidity and mortality rates act against LDLT, and for every case of donor death (even though this does not even reach a rate of 0.3%), the interest in live donation decreases, and some programmes even abandon the practice.44–48 In the evaluation process, a large number of donors are ruled out, the majority due to insufficient residual volume or incompatible blood group, which lowers the applicability of this technique, falling below 20%.49–51

LDLT is a good option for patients with hepatocarcinoma (HCC) and conserved liver function, since these patients are not always placed high on the waiting list, even though they receive additional points on the MELD scale. Additionally, there is a tendency to expand the Milan criteria, and LDLT could avoid reducing the quantity of cadaveric organs available for other indications if the criteria are expanded. On the contrary to this advantage, the shorter time spent on the waiting list would avoid the typical progressive worsening of biologically aggressive tumours and results would be worse. However, this same effect is produced if patients with HCC are prioritised giving them additional points. The option of LDLT should be taken into account in HCC patients.52–56

LDLT is considered a good option in children, with lower rates of mortality and morbidity for donors (usually their parents) as a consequence of implanting left lateral segments. This also tends to be an option demanded by the parents.

LDLT in children has shown the same or better survival than in cadaveric transplants, especially in children younger than 2 years, and does not imply a greater risk of graft loss, which does occur in the case of split and reduced liver transplants.57,58

One ethical dilemma presented by this option is the possibility of offering LDLT in emergency situations, when decisions are made by the patient's parents in an emotionally charged context.

In order to promote living donations, the physical, psychological, and economic consequences for the donors must be minimised.The process of donor evaluation must be exhaustive in order to understand any problems that could affect the risk of morbidity/mortality from the procedure. The impact of scarring, which is generally categorised by the donor as seriously inconvenient, could be greatly reduced by performing part of the procedure, or even all in the case of left lateral segment donation, laparoscopically.59–61

The large majority of donors affirm that they suffer economic losses, most of which are due to lost wages. They also communicate difficulties in obtaining life insurance and having to pay increased premiums.62,63 Living liver donors should have a similar protection system to that provided to post-partum mothers (maternal leave and job preservation). This type of donor could be given the status of “social benefactor,” including this type of protection and perhaps even fiscal incentives, since living donors benefit society as a whole, facilitating access to transplants for patients who do not have access to living donors.

The idea of establishing direct economic incentives for living donors is still a controversial issue, but it may be the state that makes this decision, as occurred in other countries to promote living kidney transplants.64,65

On the other hand, it is necessary and should be obligatory to inform recipients on the waiting list in all transplant units as to the option of live donations and all its advantages and inconveniences, even if LDLT is not performed at the hospital where the patient is being treated. Public organisations should assume the costs derived from transferring patients and their possible donors to centres with the capacity for live donations.

Donor evaluation must be an exhaustive process in order to minimise the risks inherent to donation. In all cases, morbidity ranges around 25% and mortality around 0.3%.66,67 These values should be even lower, since the appeal of live donation depends largely upon them.

The evaluation must include an estimate of the general risks of a hepatectomy and a detailed anatomical analysis, which reduces post-operative risk for the donor as well as the recipient.

In the first phase of the analysis, after obtaining informed consent, the clinical history is completed along with a physical examination, laboratory analysis (with serology), Doppler ultrasound, and psychological evaluation, which checks the mental stability of the donor along, that he/she is informed of the whole process, and establishes the altruistic nature of the voluntary donation.

The second phase of the analysis involves laboratory analytical evaluation (complete biochemistry test, immunoglobulins, tumour markers, lipid profile, iron, ferritin, transferrin, alpha-1-antitrypsin, thyroid function, coagulation factors, etc.) This is followed by a cardiopulmonary evaluation (chest X-ray, electrocardiogram, echocardiogram, and spirometry if needed) and a radiological examination of the liver (cholangio-MRI, angio-CT, and other optional methods such as MeVis), with the goal of assessing liver anatomy with the greatest possible level of accuracy, and to avoid the technical difficulties inherent to anatomical variations.

The third phase of the analysis involves a liver biopsy to evaluate the level of steatosis and the presence of portal fibrosis, non-alcoholic steatohepatitis, and inflammatory changes. The need for a biopsy is controversial, and the Vancouver Forum concluded that it should be taken only when there are changes in liver test results or radiological results, or if the patient's body mass index (BMI) is >30, and when the donor is a family member of a recipient with primary biliary cirrhosis or auto-immune hepatitis.68 Some groups perform the biopsy systematically.

During the entire process, blood reserves are also taken for later transfusions.

Before the case can be passed on to the ethics committee, informed consent must be obtained. After the ethics committee has given its approval, the law requires judicial authorisation from the civil registry.69

The ideal donor is between 18 and 55 years, with a BMI<30, no cardiopulmonary, renal, or metabolic diseases, with a liver remnant greater than 30% and an estimated graft weight >0.8% of the recipient's weight, with steatosis lower than 20% and favourable vascular and biliary anatomy.

The donor must also be adequately informed as to the physical, psychological, and work-related consequences of the procedure (scarring, hospitalisation, possible complications, estimated duration of sick leave, risk of recipient death, possibility of late complications, etc.)

The indications for LDLT are the same as for cadaveric transplants. With the current severity-based prioritisation system, which is fundamentally built off the MELD score, patients with a greater risk of death on the waiting list are placed higher on the waiting list. These patients should not be considered for LDLT, since they will receive a cadaveric organ relatively quickly. However, there are other patients who are under-prioritised using the MELD, such as cirrhotic patients with encephalopathy, ascites, and bacterial peritonitis, and are at a high risk of dying while on the waiting list. They would benefit greatly from LDLT. Patients with HCC are excellent candidates for LDLT, since in spite of receiving extra points on the MELD, these patients are always at a high risk of disease progression while on the waiting list. LDLT is a good option for patients who comply with or surpass the Milan criteria and that would fall within the expanded criteria. These patients, in which good survival rates have been demonstrated following cadaveric transplants, are excluded from transplantation by many groups for the sake of avoiding large waiting lists. Even so, LDLT should be developed as an indication for patients with “expanded” criteria in the context of controlled studies.

The incision for extracting the right liver may be subcostal bilateral, or more frequently, vertical supraumbilical, with right transverse prolongation. Other incisions more prone to eventration should be avoided.

Cholangiography is a mandatory step in the correct identification of the patient's biliary anatomy and abnormalities, which are not always entirely revealed by imaging tests, and for estimating the point at which the right hepatic duct(s) will be severed.

The pedicle should be dissected to the right of the bile duct in order to avoid damaging its vascularisation and the left pedicle.

The right liver is released using the piggy-back manoeuvre, respecting the major retro-hepatic veins >5mm, which will provide important drainage to the graft and so must be anastomosed to the recipient.

Ultrasound is used to identify the plane of dissection and the cut-off points for the possible drainage veins in segments V and VIII towards the middle hepatic vein. This vein remains in the donor, although some authors defend its inclusion in the graft, which appears to us to be an unacceptable risk for the donor. The parenchyma is normally dissected using an ultrasonic dissector or similar tool. The bile duct is dissected in the last third of the section, taking special caution not to damage any remnant biliary radicals.

Upon finishing the transection, some surgeons wait 30–45min in order to allow the venous collaterals to open towards the right vein, thus facilitating the future drainage of middle sections of the graft.

The graft is portally perfused in a bench procedure. Normally, the drainage veins of the middle segments must be reconstructed and joined to the right suprahepatic vein using plasty or cryopreserved grafts, with the goal of obtaining venous drainage. In the case of a double artery, the reconstruction is also best performed using a bench procedure so that only one anastomosis is needed. In the case of a double bile duct, plasty can be used if the distance between the two is less than 3mm.

Liver transplants in children involve the left lateral segments, and have a much higher anatomical variability. In fact, the vast majority have only one bile duct. Some experienced groups perform this procedure successfully using a laparoscopic approach.

The venous drainage of the graft is vital for proper immediate functioning, and so retrohepatic veins greater than 5mm in diameter or that drain for more than 5% of the graft in the volume analysis (MeVis) must be anastomosed.

The portal anastomosis is similar to that of the cadaveric donor procedure. The majority of authors describe a temporal portacaval anastomosis in the recipient. It is important to evaluate portal flow rates before the transplant and measure again after revascularising the graft, since a flow rate greater than 2000ml/min could damage the graft and may require other steps to reduce it (ligation of the splenic artery, shunts, etc.)

Biliary anastomosis is the greatest problem in living-donor recipients. The vascularisation of the bile duct can be poor, and may lead to leaks or stenosis. In general, the best anastomoses are duct-to-duct, with or without a Kehr drain, but occasionally a hepaticojejunostomy is necessary. A double anastomosis is not uncommon, and can be performed between the left and the right hepatic ducts of the recipient or using the cystic duct. The rate of biliary complications is greater than 30% in the majority of cases, and requires significant interventional radiological support and an endoscopy.

Infant recipients frequently have undergone previous operations (the majority for biliary atresia) and have severe portal hypertension and hypoplasia. This affects the procedure, since good portal flow is difficult to achieve, which is absolutely necessary for graft survival. Arterial anastomoses, performed using meticulous technique, do not usually give problems, and the rate of thrombosis is very low. Biliary reconstruction always involves a hepaticojejunostomy, and stenosis is not rare, requiring interventional radiological treatment.

In the 2000 Bethesda Conference, held by the National Institute of Health (NIH), the objectives for LDLT were established: increasing the number of donors, reducing recipient morbidity and mortality rates, and increasing long-term survival.70 The results from American, European, and Spanish registries have allowed us to evaluate these objectives. In the USA, the number of LDLT has decreased since 2001, when the peak number of 524 was reached, with only 219 performed in 2009. In 2010, the number increased again to 282, and we predict this upwards curve to continue. There is a 90.1% survival rate after one year, with only an 86.3% survival rate in cadaveric transplants. The 5-year survival rate for live donations is 77.7%, and 71% for cadaveric donations. Graft survival at 1 and 5 years is the same for both types.71

In the European Registry (ELTR), LDLT has increased in recent years, although the global rates are below those from the USA. Survival at 1 and 5 years is better for LDLT than in cadaveric transplants, both for the patient and the graft.72 According to the data from the Spanish Register of Liver Transplants, more than 250 LDLT have been performed in Spain, with similar graft and patient survival rates to those from cadaveric transplants.73 There have been no cases of donor deaths in Spain, although the complication rate is 20%. In infant LDLT, both overall and Spanish results are better than in the case of adults, with 1 and 5 year survival rates around 90%.71–73

LDLT is currently a valid transplant option, allowing quick access to transplants for many recipients, with patient and graft survival rates above those from cadaveric donors, once the learning curve has been passed by the surgical team.

Decreased donor mortality and morbidity rates are crucial for the expanded development of this procedure.

This type of transplant should be offered to all recipients on the waiting list, regardless of the centre in which it can be performed.

Living donors should be considered as “social benefactors” and receive protection from public administrations in medical, economic, and work-related fields, such that they are not put at a disadvantage in any way.

A debate must be opened in order to evaluate the possibility of expanding the indications for LDLT, accepting the fact that recipient survival rates will be somewhat lower than for normal cadaveric donations.

The use of expanded criteria donors (ECD) determines increased risk due to more ischaemia/reperfusion damage.75 This risk must be considered as a continuum of risk that can be measured.76 An analysis of recent studies indicates that there are no donor variables that, alone, constitute a contraindication for donation. This is especially true in the case of donor age.77 In the case of macrovesicular steatosis, which is the main cause of liver graft rejection in Spain, the influence of other variables, such as cold ischaemia, must also be evaluated so that the limit of 30% macrosteatosis can be expanded.78

The scarcity of donors to be able to satisfy current demand has created the need for liver donors with greater risk, as well as the use of donors with whom multiple risk factors are present. This implies higher scores in the scales that evaluate risk, as well as a greater probability of developing ischaemia/reperfusion damage, and in turn, graft dysfunction. Of special interest is the combination of prolonged ischaemia with all other donor variables, which requires intense efforts to minimise it as much as possible whenever another risk factor is present.79,80

Changes in the epidemiological profiles of patients registered in our country have led to a continuously more common scenario: an elderly donor who is brain dead due to a stroke, with added metabolic disorders, inotropic support drugs at high doses, and prolonged hospitalisation in the intensive care unit (ICU). Although the study group was conscious of the excess effort being placed on this subject, they insist that both the personnel in charge of coordinating the transplants in each hospital and those in charge of maintaining the donors must prioritise patient care and optimise their management. Given the pro-inflammatory state that leads to brain death and damage to the liver graft prior to extraction, it is easy to understand that using expanded criteria donors involves and additional burden.81

The need to clarify donor risk has led to the elaboration of multi-factorial scoring systems that use donor variables alone or in association with recipient variables. In this sense, the Donor Risk Index (DRI),82 the SOFT scale (Survival Outcomes Following Liver Transplantation),83 and the D-MELD (Donor-MELD)84 stand out. Although the recent modifications of the data in the Spanish Register of Liver Transplants (RETH) will facilitate the calculation of D-MELD, we must point out that the other scoring systems are not appropriately applicable for donors in Spain, since some of the variables used in these risk scoring systems do not adjust to Spanish donors (for example: African-American racial type, or split-type transplant). The working group therefore recommends the intensification of the collaboration between the Spanish National Transplant Organisation (ONT), and RETH for the expert-coordinated elaboration of a Spanish liver donor risk index, one that is better adjusted to the characteristics inherent to our donors.

The working group does not recommend a systematic usage of liver biopsies from donors, although consensus has not been reached in the case of expanded criteria donors. The possibility of obtaining a biopsy with adequate parameters should be guaranteed in authorised donation centres, or in their absence, hospitals where the transplant will take place, in cases in which the surgical team finds this information pertinent to making the correct decision. The parameters to be measured using the liver biopsy should not be limited to graft steatosis, and the pathologist responsible should be instructed to look for the following85: size of the biopsy and number of portal spaces included, semi-quantitative estimation of micro- and macrovesicular steatosis, level of portal inflammation and periportal necrosis, presence of patchy lobular necrosis, presence of polymorphonuclear infiltrates, presence of bridging lobular necrosis, expansion of fibrosis expressed as the number of fibrous tracts, portal/porto-portal fibrous expansion, level of cholestasis, presence of pigments, ballooning and Mallory bodies in hepatocytes, and an evaluation of intimal narrowing of the arterioles in portal spaces in terms of original arteriole diameter.

The systematic use of expanded criteria for liver function evaluation systems (dyes such as indocyanine green, bioelectric impedance) must still be listed in the category of experimental models, since they have yet to accumulate sufficient scientific evidence in their support.86

The assignment of a given donor to a certain recipient (donor matching) is the subject of much controversy. There are 3 different criteria that can be used to assess this issue: the principle of efficacy, the principle of justice, and the benefit to survival. According to the principle of efficacy, the donor must be assigned to the candidate who would theoretically have the best postoperative results, based on the quality of the donor. Recent studies in this field have shown that the combination of an expanded criteria donor with a recipient with a high MELD score is the combination that offers the worst results. However, this same type of donor paired with recipients with a lower MELD score offers high survival rates after one year. The principle of justice considers that the donor should be assigned to the candidate with the greatest need, this being the patient with the most severe clinical situation and the highest risk of death on the waiting list. According to this principle, there would be no selection process or matching, but rather a strict order of recipients based on the severity of their conditions. The prioritisation scheme for the waiting list in this second case is based on the MELD score, such that patients with higher scores should be the first to receive a transplant.87 The third principle, the benefit of survival, is based on a function that relates the severity of the recipient's condition, and so survival on the waiting list, with post-liver transplant survival, theoretically, based on the quality of the donor. The primary advantage of this principle is that it defines those candidates in which a transplant would be futile, since the survival rate after the liver transplant would not surpass the survival on the waiting list. Applying this line of reasoning, the most severe recipients would receive a greater benefit in terms of survival from a transplant, even when assigned to expanded criteria donors (combined risks) whereas the assignment of this type of donor in patients with lower risk would notably decrease the survival value of the transplant.88,89

The working group did not come to a consensus regarding whether the global series results should prevail over the benefit to recipient survival, and have found advantages and disadvantages in both viewpoints, with more information needed from the practical application of the principle of benefit of survival. Even so, in those groups that currently use the MELD system in Spain, and as such do not have the possibility of matching donor and recipient, the benefit of survival criteria supports that the combination of donor–recipient risks is ethically justifiable.

In light of the recent evidence that the combination of certain donor characteristics with specific diseases in the recipient leads to worse results, we recommend not to designate these donors to other recipients. This is especially relevant in recipients with HCV, elderly donors,6 and in some cases, grafts with severe or moderate steatosis,90 which lead to worse results when compared to other aetiologies. In this sense, sufficient scientific evidence exists to recommend not allocating elderly donors to recipients with HCV-derived cirrhosis.

Given the evolution of cadaveric donation rates and the waiting list for liver transplants, the working group recommends: to stimulate the development of living-donor programmes and to optimise those already in effect, to promote asystolic donation, and to implement the use of normothermic perfusion machines91,92 in donors at a high risk of damage from ischaemia/reperfusion (over the practice of ischaemic preconditioning).

However, a consensus was not reached regarding the implementation of a telephone check-list to determine donor criteria (or combination) that would lead to telephone denial of the donor, thus avoiding useless travel.

An analysis of the data provided by the ONT highlighted that, although Spanish liver transplant teams have been able to adapt in recent years to the epidemiological changes that have occurred in donors, the magnitude of the time spent on the waiting list and its associated mortality, along with the stabilisation and possible reduction of donation rates in Spain, makes the search for alternatives to conventional liver transplants an imperative task. These alternatives include living-donor liver transplant, asystolic donor transplant, and split-type transplant. The need for more development in this field is even more apparent when considering that in 2010 these alternative donors were only 6% of the total number of liver transplants performed in Spain.

The initiatives, conclusions, and recommendations from other working groups, as well as the creation of the national programme for the development of asystolic donation by the ONT, all stand out.

Following the SETH consensus meetings in 2005 and 2008, a series of liver transplant quality indicators were developed, which formed part of the previously published consensus documents.1–4 In the consensus meeting held in Madrid on 18 November 2010, a working group was dedicated to the Quality and Accreditation of Liver Transplant Programmes. On this occasion, the previously proposed quality indicators were reviewed and updated, and specific quality and reference criteria to be required of a clinical unit or health professional that participates or collaborates in the process of a liver transplant.