Recommendations of everolimus use in liver transplant

Rubín Suárez, Angel; Bilbao Aguirre, Itxarone; Fernández-Castroagudin, Javier; Pons Miñano, José Antonio; Salcedo Plaza, Magdalena; Varo Pérez, Evaristo; Prieto Castillo, Martín

doi:10.1016/j.gastre.2017.10.006

Información del artículo

Resumen

Texto completo

Bibliografía

Descargar PDF

Estadísticas

Figuras (2)

Tablas (2)

Table 1. Studies on the use of everolimus in de novo liver transplant.

Table 2. Main adverse effects of everolimus at 12 months in prospective studies.

Mostrar másMostrar menos

Abstract

Mammalian target of rapamycin (mTOR) inhibitors, everolimus (EVL) and sirolimus are immunosuppressive agents with a minor nephrotoxic effect, limited to the development of proteinuria in some cases. The combination of EVL and low-dose tacrolimus has proven to be as safe and effective as standard therapy with tacrolimus for the prevention of acute cellular rejection. Early initiation of EVL-based immunosuppressive regimens with reduced exposure to calcineurin inhibitors has been shown to significantly improve renal function of LT recipients during induction and maintenance phases, with comparable efficacy and safety profiles. In patients with established kidney failure, initiating EVL may enable clinicians to reduce calcineurin inhibitors exposure, thereby contributing to the improved renal function of these patients. Although there is not sufficient evidence to recommend their use to prevent the recurrence of hepatocellular carcinoma and the progression of de novo tumours, they are used in this context in routine clinical practice.

Keywords:

Liver transplantation

Immunosuppression

Everolimus

Sirolimus

Renal insufficiency

Nephrotoxicity

Hepatocellular carcinoma

Resumen

Los fármacos inhibidores de la mTOR, everolimus (EVL) y sirolimus, son inmunosupresores con muy poco efecto nefrotóxico, limitado al desarrollo de proteinuria en algunos casos. En la prevención del rechazo agudo EVL combinado con tacrolimus a dosis reducidas tiene una eficacia y seguridad comparables a la inmunosupresión estándar con tacrolimus. La aplicación temprana de una inmunosupresión basada en EVL con minimización de la exposición al inmunosupresor calcineurínico en trasplantados hepáticos permite mejorar los resultados de la función renal, con tasas similares de eficacia y seguridad, tanto en el período de novo como de mantenimiento. En pacientes con disfunción renal establecida la introducción de EVL permite minimizar la exposición al inmunosupresor calcineurínico, con la consiguiente mejoría en la función renal. Aunque no hay evidencia suficiente para recomendar su uso para prevenir la recurrencia del hepatocarcinoma y la progresión de tumores de novo, es práctica clínica habitual utilizarlos en este contexto.

Palabras clave:

Trasplante hepático

Inmunosupresión

Everolimus

Sirolimus

Insuficiencia renal

Nefrotoxicidad

Hepatocarcinoma

Texto completo

Introduction

The introduction of the new immunosuppressants has seen the incidence of acute rejection fall and liver transplant (LT) survival rates increase to >80% and >70% at year one and five, respectively.1 However, given that significant toxicity is associated with these drugs, immunosuppressive regimens that meet the following objectives are needed: (1) maintain immunosuppressive efficacy to prevent acute rejection; (2) reduce short- and long-term nephrotoxicity; (3) reduce the number of side effects that give rise to increased cardiovascular risk (diabetes, hypertension, dyslipidaemia, obesity); (4) reduce recurrent hepatocellular carcinoma (HCC); and (5) reduce the onset of de novo tumours. One of the therapeutic strategies to achieve these objectives is based on the withdrawal or reduced administration of calcineurin inhibitors (CNIs) and their combination with mammalian target of rapamycin (mTOR) inhibitors.

Everolimus (EVL) and sirolimus (SRL) act on a different level to CNIs, specifically on the T-cell activation cascade. This inhibits mTOR, the protein kinase involved in the third signal for T-cell activation.2–4

EVL has a shorter half life than SRL,5 enabling stable blood concentrations to be reached more quickly.6

This article is a collection of evidence- and experience-based clinical recommendations proposed by experts in the field.

Everolimus in the prevention of acute rejection in liver transplant

Four prospective studies with EVL in de novo liver transplant patients have been conducted, each with different objectives (Table 1). Levy et al. analysed the efficacy and safety of EVL up to 36 months after LT in a phase II study (study RAD B158).7 All patients (n=119) were treated with cyclosporin (CsA) plus steroids and three EVL doses were compared (1mg, 2mg or 4mg daily) versus placebo. A trend towards a lower rate of acute rejection was observed in patients treated with EVL versus the placebo group (39.3%, 30%, 29% vs 40%, respectively), which did not reach statistical significance. In another study, Masetti et al. analysed the impact of early withdrawal of CsA (30 days after LT) followed by EVL monotherapy on kidney function in 78 liver transplant recipients.8 No significant differences in efficacy (rejection and survival) were found between the two groups.

Table 1.

Studies on the use of everolimus in de novo liver transplant.

Author, year (ref.)	Design	Sample size (n)	Duration of follow-up	Difference in eGFR (MDRD-4) EVL group vs control group (p)	Summary of results
Levy et al.,7 2006	EVL vs placebo	119	36 months	8.3a (p=0.15)	Similar efficacy of EVL+CsA vs CsA+placebo, with no significant differences in renal function
Masetti et al.,8 2010	EVL monotherapy at 30 days post-LT vs CsA	78	12 months	27.7 (p<0.001)	EVL monotherapy at 30 days has similar efficacy with significantly better renal function vs CsA
Fischer et al.,9 2012	PROTECT study: EVL monotherapy after switching from CNI vs CNI	203	12 months	7.8 (p=0.02)	EVL monotherapy has similar efficacy with significantly better renal function vs CNI
De Simone et al.,12 2012	EVL+reduced-dose TAC vs standard TAC	719	12 months	8.5 (p<0.001)	EVL+reduced-dose TAC has similar efficacy with significantly better renal function vs standard TAC

CNI: calcineurin inhibitors; CsA: cyclosporin; eGFR: estimated glomerular filtration rate; EVL: everolimus; MDRD: Modification of Diet in Renal Disease; TAC: tacrolimus.

a

Creatinine clearance calculated by the Cockcroft-Gault equation.

In the PROTECT 203 study, patients received four-week induction therapy with basiliximab and a CNI with or without steroids.9 From the fourth week, the control group (n=102) continued with the CNI, while the study group (n=101) was administered a reduced dose of the CNI and EVL was introduced with the intention to withdraw the CNI eight weeks after the transplant. No significant differences in survival or biopsy-proven acute rejection were observed at one year,9 and these outcomes were maintained at three and five years of follow-up.10,11

The clinical trial that led to EVL being approved in liver transplant was the phase III study H230412. In this prospective and open-label multicentre study, 719 patients were randomised at 30+5 days post-LT into three arms: tacrolimus (TAC) withdrawal (group suspended early due to a higher rate of acute rejection), reduced EVL-TAC (TAC-r) (EVL at 3–8ng/ml and TAC at 3–5ng/ml) and the control arm, which maintained TAC (at 8–12ng/ml) until month 4 before reducing the dose to 6–10ng/ml. The 12-month global analysis found no inferiority in the incidence of the primary composite endpoint (biopsy-proven acute rejection, graft loss or death) in the EVL-TAC arm, which was lower than in the TAC control arm (6.7% vs 9.7%, p<0.001).12 Efficacy was maintained at 24 and 36 months in patients who continued with EVL.13,14 Based on the results of this study, EVL was approved by the European Medicines Agency and the US Food and Drug Administration in the indication of prophylaxis of acute rejection, in combination with reduced-dose TAC, from the fourth week after liver transplant.

Key points:

1.
EVL in combination with reduced-dose TAC has shown comparable efficacy and safety to standard immunosuppression with TAC at 12, 24 and 36 months after liver transplant.
2.
EVL in monotherapy is not recommended in the early post-transplantation period owing to the increased risk of rejection.

Everolimus in renal dysfunction after liver transplantation

It is estimated that approximately 50% of liver transplant recipients experience renal dysfunction to varying degrees, with 8–28% suffering severe renal failure. These figures increase as the post-LT follow-up period increases.15–17 However, recent studies have found lower rates of renal dysfunction, with a five-year cumulative incidence of 18–22% using a low-dose CNI.18 A fall >30% in the glomerular filtration rate in the first year after LT has been found to be an important predictor of chronic nephropathy and death after the first year post-LT,19,20 and recent studies suggest a significant increase in mortality when the glomerular filtration rate is <30ml/min/1.73m2 (measured by iothalamate clearance).21

In general, renal function during the first year after liver transplantation is the most important predictive factor of long-term renal failure.15,17 Although CNIs are the cornerstone of immunosuppressive therapy in LT, their use is unequivocally associated with the onset of both acute and chronic nephrotoxicity17,22 and they are considered the main pathogenic mechanism of post-LT chronic kidney disease (CKD).

In light of the above, the late introduction, reduction or even withdrawal of CNIs in both the induction and long-term post-LT maintenance phases should result in greater preservation of renal function. To avoid any detrimental effect on patient survival or liver graft function, these ‘nephroprotective’ protocols should stipulate the use of non-nephrotoxic immunosuppressants like mycophenolate mofetil (MMF) or mTOR inhibitors, potentially in combination with corticosteroids and monoclonal antibodies like basiliximab.

Everolimus in preservation of renal function in the initial post-transplant period

The first study to assess the early withdrawal of calcineurin inhibitors with early conversion to EVL monotherapy and its effect on renal function was conducted by Masetti et al.8 (see the section “Everolimus in the prevention of acute rejection in liver transplant” and Table 1). In this study, the estimated glomerular filtration rate (eGFR), as assessed by the Modification of Diet in Renal Disease (MDRD-4) equation, was significantly better (87.6±26.1ml/min/1.73m2) in the EVL group versus the CsA group (58.2±17.9ml/min/1.73 m2; p<0.001).

The PROTECT study (see the section “Everolimus in the prevention of acute rejection in liver transplant” and Table 1) was originally published in 2012 by Fischer et al.,9 with the subsequent publication of three- and five-year outcomes.10,11 The objective was to analyse renal function after switching to EVL monotherapy. At one year, renal function assessed by the MDRD-4 equation was significantly better (7.8ml/min/1.73m2; p=0.02) in the EVL group than in the CNI group. At three years, the superiority of the CNI-free regimen increased (9.4ml/min/1.73m2) following the slight but progressive deterioration of the eGFR in the CNI cohort, despite reduced exposure to calcineurin inhibitors.10 The five-year results confirm the superiority trend of the CNI-free regimen in terms of improved renal function, with the eGFR increasing to 11.4ml/min/1.73m2.11 No case of hepatic artery thrombosis was reported.

The registration study that led to the approval of EVL in liver transplant (see the section “Everolimus in the prevention of acute rejection in liver transplant” and Table 1) tested the efficacy of this non-nephrotoxic immunosuppressant in the preservation of renal function after LT. This study compared the results of an EVL+TAC regimen with reduced tacrolimus trough concentrations (3–5ng/ml) vs standard TAC concentrations (8–12ng/ml) until month 4, followed by concentrations of 6–10ng/ml.12–14 The eGFR assessed by the MDRD-4 equation was greater in the everolimus group, with significant differences of 8.5ml/min/1.73m2 and 7.6ml/min/1.73 m2 at 12 and 24 months after transplantation, respectively, versus the control group (p<0.001).12,13 This stabilisation of renal function was maintained at 36 months,14 with no differences in efficacy between both treatment arms. The above results confirm that TAC minimisation combined with the introduction of EVL in the first month after liver transplantation is a safe and effective alternative, with superior renal function compared to standard immunosuppression with TAC. This registration study also showed that the early withdrawal of TAC, substituted with EVL monotherapy, is associated with a significantly greater risk of acute rejection.12

A prospective study comparing EVL (3–8ng/ml) in combination with reduced-dose TAC (<5ng/ml) (EVL+TAC-r) vs standard treatment with TAC (6–10ng/ml) in combination with MMF is currently ongoing in Spain (NCT02040584). The results of this study will reveal the impact on renal function of an everolimus plus TAC-r regimen versus standard immunosuppressive therapy (TAC+MMF).

Everolimus in preservation of renal function in the maintenance period

The onset of renal dysfunction between three and six months after liver transplantation has been found to be a predictor of long-term renal failure.17,23 Studies on the early post-LT period, as well as kidney transplant studies, suggest that EVL is a potent immunosuppressant that can substantially reduce CNI doses in the early post-LT phase, thereby optimising renal function without impacting on efficacy against rejection.10,24,25

EVL's nephroprotective effect in the post-LT maintenance period has been analysed in numerous studies. In one such study, De Simone et al. found no improved renal function in patients with CNI-related renal dysfunction randomised to convert to everolimus therapy with CNI reduction (20%) or discontinuation (80%) versus the control group.26 The high frequency of dose reductions in the control group (77%) and the relatively long post-transplant time (>3years) might explain the lack of difference in renal function between the two patient groups. However, other non-comparative studies have found a significant improvement in renal function after the introduction of EVL and the reduction or withdrawal of CNIs, without increasing the risk of rejection.27,28 A French multicentre study of 240 patients found a significant mean eGFR increase >8ml/min/1.73m2 (18.2%) in patients with kidney failure assessed 12 months after EVL initiation, at a mean of 4.9±5.2 years after liver transplantation, and 60% did not receive CNIs after this period.26 A recent Spanish observational, retrospective and multicentre study involving 477 patients treated with EVL maintenance therapy found that renal dysfunction was the reason for converting in 32.6% of cases, at a mean of 23.8 months after liver transplantation.29 Although the eGFR, measured by the MDRD-4 equation, improved in all conversion indications (renal dysfunction, HCC prophylaxis and de novo tumours), the greatest improvement in renal function was seen in the group of patients administered EVL due to renal dysfunction, with a significant increase of 10.9 and 6.8ml/min/1.73 m2 at three and 12 months after initiating EVL, respectively. A particularly striking finding of this study was that the improvement in eGFR was greatest in patients who switched early to EVL (within one year of liver transplantation). Indeed, no improvement in eGFR was seen in patients who converted to everolimus five years after transplantation, which suggests that conversion to EVL post-LT should not be postponed unless absolutely necessary, as early CNI minimisation strategies are feasible and safe using EVL. Mean EVL dose and exposure was lower than in the French study28 with no detrimental impact on safety, reflecting the knowledge gained from the increasingly frequent use of this drug.

Key points:

1.
The early and personalised implementation of an everolimus-based protocol with minimised exposure to calcineurin inhibitors in liver transplant recipients results in improved renal function with similar efficacy and safety rates.
2.
CNI reduction strategies in combination with everolimus effectively prevent renal dysfunction in de novo transplant recipients, as well as during the maintenance phase.
3.
In patients with established renal dysfunction, the addition of EVL to the immunosuppressant regimen is a viable option as it minimises exposure to CNIs and may even lead to their withdrawal, thereby improving renal function.
4.
The preservation of renal function during the induction and maintenance phases is expected to have an impact on final LT outcomes (morbidity, survival and even cost), particularly in high-risk patients.

Everolimus in hepatocellular carcinoma

Hepatocellular carcinoma (HCC) is the third leading cause of cancer death worldwide30 and accounts for 16–25% of all liver transplants in Spain,31,32 with a post-LT recurrence rate of 16–20%.33 Recurrences are resectable in <10% of cases, and are associated with a mean post-diagnosis survival of one year.34,35 Molecular studies36 have shown that the mTOR pathway is pivotal for HCC development in 30–40% of cases.37 This explains why mTOR inhibitors may have a role to play in the immunosuppressive regimen of HCC transplant recipients.38 This antiproliferative effect on HCC cell lines appears to be maintained even with the concomitant administration of tacrolimus.39 Some studies have established a link between the risk of HCC recurrence and high concentrations of CNI, even in the first month after transplant.40,41

The efficacy of mTOR inhibitors in the prevention or treatment of HCC recurrence after liver transplantation has been analysed in three meta-analyses.42–44 In the first two,42,43 the survival of HCC transplant recipients treated with an mTOR inhibitor as part of an immunosuppressive regimen was superior to subjects not treated with an mTOR inhibitor. However, these results were only based on five retrospective studies with a very limited number of patients, and inconsistent criteria were used to define the tumour characteristics. A more recent meta-analysis44 evinced the same trend in the global analysis, but when the results were adjusted for study and tumour type, a benefit was only observed for those cases which met the Milan criteria.

The results of the SILVER study,45 the only prospective, randomised study to date with extended follow-up that has assessed the use of mTOR inhibitors (SRL) in HCC transplant recipients, were recently published. Globally, the study showed improved recurrence-free survival during the first three to four years of follow-up, which is not maintained from year five. Greater benefits were also found for the subgroup of patients <60 years of age and for those with tumours within the Milan criteria (and not in liver explant high-risk patients). However, the most striking short- and long-term benefits were found in SRL monotherapy patients, although these patients only accounted for 19% of the SRL group. Another limitation of the study was that it did not analyse other recognised poor prognostic factors, whether classification-related (e.g. high risk of recurrence) or patient-related (poor tumour differentiation, microvascular invasion or high alpha-foetoprotein levels).

In a recent study, Yanik et al.46 analysed the effect of SRL maintenance immunosuppression in 3936 HCC transplant recipients between 2002–2012 in the United States of America, 234 (6%) of whom received SRL in the first three months after liver transplantation. The study found no differences in cancer-related death or HCC recurrence between patients who received SRL and those who did not.46 However, the study was limited by the small SRL sample size, and it therefore lacks the statistical power necessary to identify significant differences. Furthermore, 26% of the patients in the SRL group did not undergo follow-up beyond the first three months after transplantation, and explant data are not available. As a result, neither the histological differentiation grade of the tumour nor the potential onset of microvascular invasion were analysed.

The study of the efficacy and adverse effects profile of everolimus in combination with sorafenib in the treatment of post-LT HCC recurrence has yielded contradictory results.47–49

A clinical trial (NCT01888432) evaluating the use of EVL with reduced-dose TAC in living donor recipients is currently ongoing. Its secondary endpoint is to analyse if the benefit of this immunosuppressive regimen for HCC recurrence is maintained in tumours that do not meet the Milan criteria (which is not an exclusion criteria), as well as to assess the role of alpha-foetoprotein, microvascular invasion and tumour differentiation grade.

New studies that prospectively evaluate the advantages of EVL administration in HCC transplant recipients are therefore needed, as such cases represent 30% of this drug's use in clinical practice.29 It is also important to identify the subgroup of patients at high risk of recurrence who could benefit from the use of mTOR inhibitors.

Everolimus in de novo tumours

The incidence of de novo tumours after liver transplant ranges from 5% to 16%, two to three times higher than in the general population.50 De novo tumours are one of the leading causes of long-term mortality.51 The main risk factors are immunosuppression, age, smoking and alcohol consumption, the latter two taking on particular relevance in de novo lung and oropharyngeal cancer.52,53

Numerous preclinical studies on both in vitro cell cultures and animal models have shown that a wide variety of solid tumours, as well as lymphoproliferative disorders, rely on the mTOR pathway.54 Clinical evidence of the role of mTOR inhibitors in the treatment of post-LT de novo tumours is still scant and based on publications of isolated cases or short retrospective series.55–59 Nevertheless, despite the low level of evidence, one third of all post-LT everolimus is administered in the context of a de novo tumour in routine clinical practice in Spain.29 This is because EVL at concentrations of 3–8ng/ml is administered at many transplant centres in order to minimise or withdraw the CNI.

Despite the lack of sufficient evidence to substantiate a recommendation, mTOR inhibitor-based immunosuppressive regimens to prevent or treat post-LT HCC recurrence, or after the manifestation of a de novo tumour, are routinely used in clinical practice at liver transplant units.

Key points:

1.
mTOR inhibitors inhibit angiogenesis and apoptosis to impede the transformation and propagation of neoplastic cells.
2.
The retrospective studies performed, as well as the only prospective study carried out to date on HCC transplant recipients, have found lower recurrence and increased survival in certain subgroups of patients who receive mTOR inhibitors. However, until these findings are confirmed in new prospective studies, the generalised use of mTOR inhibitors in all HCC transplant recipients cannot be recommended. Instead, for the time being it seems reasonable to use these drugs in patients at the highest risk of recurrence.
3.
The efficacy of mTOR inhibitor-based immunosuppressive regimens to prevent or treat post-LT HCC recurrence, or after the manifestation of a de novo tumour, should be confirmed with future prospective and randomised studies.

Everolimus regimens and doses in liver transplant

As well as the indications mentioned above, mTOR inhibitors may be used in other situations including adjuvant therapy in the event of acute rejection or CNI-induced neurotoxicity even during the early post-transplant period. The EVEROLIVER study29 found that conversion to EVL due to CNI-induced neurotoxicity accounted for 11.6% of cases (56/481), while biopsy-proven rejection accounted for 5.2% (6/481). Nevertheless, there is insufficient evidence to formulate a recommendation concerning these indications.

Practical considerations: metabolism and interactions

Everolimus is an oral drug with a narrow therapeutic index, which is taken twice a day with or without food together with a CNI. As it is primarily metabolised in the liver, the dose must be adjusted in the event of impaired liver function (reduce the starting dose by 30%, 50% and 60% in patients with Child–Pugh A, B and C cirrhosis, respectively).60 Because EVL is metabolised by CYP3A4, the concomitant administration of potent CYP3A4 inhibitors (e.g. ketoconazole, itraconazole, voriconazole, clarithromycin and ritonavir) or inducers (e.g. rifampicin and rifabutin) is not recommended unless the benefits outweigh the risks.

Unlike in a kidney transplant where EVL was administered in combination with CsA, in a liver transplant it was administered with reduced-dose TAC.12 In a kidney transplant, CsA was found to have a synergistic effect with EVL when both drugs were administered together (a lower EVL dose is required when administered in combination with CsA, and, when the CsA dose is reduced, EVL concentrations may also fall,6,61,62 especially if the CsA trough levels are <50ng/ml). This effect was not seen with TAC in a liver transplant, leading to the conclusion that it would seem sensible to administer lower starting doses of EVL with CsA than with TAC in a liver transplant.

Everolimus dosage63

In early use, the EVL starting dose is 1mg every 12h, administered simultaneously with TAC (0.75mg/12h if in combination with CsA). The EVL dose may be adjusted (increased or decreased by 0.25mg/12h) according to trough levels (C0) obtained at least five days subsequent to the last dose adjustment, until a C0 level of 3–8ng/ml is established. Tests should be performed until two consecutive C0 levels show stable EVL concentrations. Once these levels have been achieved, the TAC dose should be progressively reduced. Although the reduced concentration of TAC in combination with EVL has not been established in a de novo liver transplant, 5–6ng/ml may be considered a reasonable dose as this was the mean level established in the registration study.12 However, the design of numerous ongoing clinical trials, as well as the use of EVL in transplant referral centres, suggest that the TAC dose could be reduced still further, to 3–5ng/ml (Fig. 1).

Figure 1.

Everolimus management in de novo patients.

(0.24MB).

Where EVL administration is delayed, the drug may be administered at a dose of 0.75–1mg/12h while simultaneously reducing the CNI dose by 25–30%, before adjusting the dose in accordance with concentrations and tolerance54 (Fig. 2). The switch to EVL is similar in patients receiving treatment with CsA. However, due to CsA's special interaction with the drug, EVL levels may be reduced if exposure to CsA is significantly reduced (trough concentration <50ng/ml).

Figure 2.

Everolimus management in maintenance patients.

(0.22MB).

Monitoring levels

Exposure-efficacy and exposure-safety data have established that EVL C0 levels ≥3.0ng/ml are associated with a lower incidence of biopsy-proven acute rejection than concentrations <3.0ng/ml. The recommended upper limit is 8ng/ml,64–68 as levels >8ng/ml are associated with increased side effects. As such, recommended levels are 3–8ng/ml. Dose adjustment is not required in elderly patients (>65 years) or in patients with renal failure.

EVL levels must be strictly monitored in the following circumstances:

1.
Liver failure.
2.
The administration of drugs that induce or activate cytochrome P450 CYP3A4 isoenzyme.
3.
When cyclosporin-based treatment is minimised.
4.
With the onset of adverse effects, in which case the EVL dose should be reduced by at least 0.25mg every 12h, maintaining EVL C0 levels >3ng/ml.

Everolimus tolerance profile and adverse effects

The side effects associated with the use of mTOR inhibitors are well known and can often be controlled with medical treatment and dose reduction.69 The most common EVL-associated adverse reactions recorded by all the controlled clinical trials (CT) are: anaemia, peripheral oedema, elevated creatinine levels when used with full-dose calcineurin inhibitors, hyperlipidaemia, healing abnormalities and oral thrush.12,13,26,70

In the EVL registration study,12 the rate of adverse effects that led to treatment being withdrawn was 25.5% in the EVL-reduced-dose TAC group vs 14.1% in the standard TAC group. Proteinuria (2.9%), recurrent hepatitis C (2%) and pancytopaenia (3%) were the most common events that led to EVL treatment discontinuation.

Some of the most common adverse effects together with treatment recommendations are described below (Table 2).

Table 2.

Main adverse effects of everolimus at 12 months in prospective studies.

Side effect	EVL group (%)	CNI group (%)	Study (ref.)	Treatment
Proteinuria	2.9 9.9	0.4 2	H230411 PROTECT8	Consider EVL dose reduction or even withdrawal if proteinuria >2g/day Angiotensin-converting enzyme (ACE) inhibitors or Angiotensin II receptor blockers (ARBs)
Dyslipidaemia	23.3 22.8 9.6	17.8 10.8 7.7	H230411 PROTECT8 MASETTI7	Heart-healthy lifestyle Lipid-lowering drugs (statins, fibrates, ezetimibe)
Infections	50.2 73.3 46.1	42.6 59.8 46.1	H230411 PROTECT8 MASETTI7	Specific treatment of the infection Reduce or withdraw EVL
Peripheral oedema	17.6 9.6	10.8 0	H230411 MASETTI7	Lower the everolimus dose Evaluate response to diuretics (usually minimal) Consider withdrawing calcium channel blockers If angioedema: corticosteroids+antihistamines and consider EVL withdrawal
Incisional hernia	2.9 11.9 46.1	1.2 10.8 26.9	H230411 PROTECT8 MASETTI7	Do not use EVL in the first month after LT Do not use in malnourished (BMI<20kg/m2) or obese (BMI>35kg/m2) patients until the wound has fully healed Do not use EVL in retransplantation Withdraw EVL between seven and 30 days before major surgery and re-start 15 days after surgery
Anaemia	7.8 18.8	8.3 14.8	H230411 PROTECT8	Reduce everolimus dose if Hb≤8g/dl and withdraw if ≤6g/dl Reduce/withdraw mycophenolate Erythropoietin/iron therapy
Leukopenia	11.8 20.8	5 15.3	H230411 PROTECT8	Reduce/withdraw myelotoxic drugs Reduce everolimus dose if leukocytes ≤3000mm3g/dl and withdraw if ≤2000mm3 Colony-stimulating factor if severe leukopenia, infection or fever
Thrombocytopenia	5.3 7.9	1.7 7.4	H230411 PROTECT8	Reduce everolimus dose or withdraw

Peripheral oedema

Peripheral oedema is a common and at times incapacitating adverse effect, with little or no response to diuretics.

Proteinuria and renal failure

In the clinical trials with post-LT de novo EVL, the rate of proteinuria varies from 3.7–9.9% and is usually mild.8,9,13 The mechanism by which mTOR inhibitors induce proteinuria is not well understood, but is believed to be associated with the reduced tubular reabsorption of proteins. Deteriorated renal function after mTOR inhibitor administration has been reported, particularly in patients with significant prior proteinuria. For this reason, baseline proteinuria must be measured before initiating mTOR inhibitor therapy and its administration is not recommended if concentrations are >800mg/day,71,72 or in patients with eGFR (MDRD4) <40ml/min/1.73 m2. Regular monitoring of renal function and proteinuria (every three to six months) is recommended in patients receiving everolimus.

Incisional hernia and surgical wound complications

The use of mTOR inhibitors after a solid organ transplantation has been associated with poor surgical wound healing and the development of lymphoceles. The study by Masetti et al. found a higher incidence of incisional hernia in the EVL group (46.1% vs 26.9%, p=0.16), although it should be noted that everolimus was administered very early, just 10 days after liver transplantation.8 However, in the registration study in which EVL was started one month after LT, the rate of surgical wound and incisional hernia complications was similar between the EVL and non-EVL groups (11% vs 8.3%, p=0.36 and 9.8% vs 7.9%, p=0.52, respectively).12

Dyslipidaemia

Dyslipidaemia is associated with EVL treatment in both de novo regimens (26.9% EVL group vs 11.6% control group, p=0.001)13 and late conversion regimens (9.7% EVL group vs 2.7% control group p=0.017).24 Dyslipidaemia prevalence ranges from 7% to 43%.73 It is generally controlled with lipid-lowering drugs.

Infections

The rate of EVL-associated infections varies depending on the study. Although the rate did not increase in de novo initiation studies,8,13 it did peak when EVL administration was delayed.9,24 Given that mTOR inhibitors inhibit the proliferation of activated T lymphocytes and interferon gamma induced by interleukin-2, both of which are required for immunity against intracellular bacteria, patients may be predisposed to infection by these microorganisms.

In one of the registration studies,13 56% of patients (138/245) from the EVL+reduced-dose TAC group presented with infection vs 51.7% of patients (125/242) from the conventional TAC group, with no significant differences between both groups in either the global analysis or by infection type (bacterial: 19.6% vs 13.2%, viral: 18.4% vs 18.2% and fungal 3.3% vs 6.2%).

Bone marrow suppression

Everolimus is associated with bone marrow suppression that manifests as anaemia (7.8–18.8%), leukopenia (11.8–20.8%) or thrombocytopaenia (5.3–7.9%). Other potential causes of these haematological manifestations, such as viral infections, deficiencies and myelotoxic drugs (MMF, ganciclovir, valganciclovir, etc.), should be ruled out. It can usually be corrected by reducing the EVL dose, although the drug must be withdrawn in some cases.

Stomatitis and aphthous ulcers

Aphthous ulcers are relatively common in patients treated with EVL. They manifested in 10.6% of patients in the registration study13 and 26.4% of patients in the late conversion studies.26 Concomitant infections must be ruled out in the event of these lesions occurring. Treatment includes reducing the dose of mTOR inhibitors and topical treatment with an anaesthetic. Aphthous ulcers may recur in some patients, requiring EVL to be withdrawn.

Skin lesions

They generally improve spontaneously within weeks, although topical dermatological treatment and reducing the EVL dose may be necessary. Infection should be ruled out.

Pneumonitis

Its incidence was recorded as 2–5% in the H230412–14 and PROTECT studies.9–11 Symptoms are variable, ranging from asymptomatic X-ray abnormalities to severe, potentially fatal, respiratory distress. Its prevalence increases when mTOR inhibitor levels exceed the therapeutic margin.

Key points:

1.
Renal function should be periodically assessed using the MDRD and/or Chronic Kidney Disease Epidemiology Collaboration equations in patients treated with EVL.
2.
Proteinuria should be tested 24hours before introducing EVL and then periodically (every three to six months) once treatment has begun. EVL should be reduced/withdrawn in the event of proteinuria >2g/day.
3.
Dose and administration:
- •
  Starting dose: from 30 days post-LT at a dose of 1mg/12h orally, administered at the same time as TAC (0.75mg/12h if in combination with CsA), with or without food but always consistent, and at the same time as the CNI.
- •
  Maintenance dose and dose adjustment: adjust the dose weekly until trough levels (C0) of 3–8ng/ml are established.
4.
Special populations:
- •
  No dose adjustment is necessary in elderly patients or patients with renal failure.
- •
  Liver failure: mild (reduce the starting dose by 30%), moderate (reduce the starting dose by 50%), severe (reduce the starting dose by 60%).
5.
Precautions:
- •
  Everolimus trough levels (C0) should be monitored after each dose adjustment and after the administration of drugs that interact with its metabolism.
- •
  Renal function (MDRD and/or Chronic Kidney Disease Epidemiology Collaboration equations), proteinuria, complete blood count and lipids should be monitored periodically (every three to six months).

Funding

Study funded by Novartis®.

Conflicts of interest

The authors declare that they have no conflicts of interest.

References

[1]

R. Adam, V. Karam, V. Delvart, J. O’Grady, D. Mirza, J. Klempnauer, et al.

Evolution of indications and results of liver transplantation in Europe. A report from the European Liver Transplant Registry (ELTR).

J Hepatol, 57 (2012), pp. 675-688

http://dx.doi.org/10.1016/j.jhep.2012.04.015 | Medline

[2]

P.F. Halloran.

Immunosuppressive drugs for kidney transplantation.

N Engl J Med, 351 (2004), pp. 2715-2729

http://dx.doi.org/10.1056/NEJMra033540 | Medline

[3]

R.H. Wiesner, J.J. Fung.

Present state of immunosuppressive therapy in liver transplant recipients.

Liver Transpl, 17 (2011), pp. S1-S9

http://dx.doi.org/10.1002/lt.22410 | Medline

[4]

D. Fantus, A.W. Thomson.

Evolving perspectives of mTOR complexes in immunity and transplantation.

Am J Transplant, 15 (2015), pp. 891-902

http://dx.doi.org/10.1111/ajt.13151 | Medline

[5]

F. Lamoureux, N. Picard, B. Boussera, F.L. Sauvage, P. Marquet.

Sirolimus and everolimus intestinal absorption and interaction with calcineurin inhibitors: a differential effect between cyclosporine and tacrolimus.

Fundam Clin Pharmacol, 26 (2012), pp. 463-472

http://dx.doi.org/10.1111/j.1472-8206.2011.00957.x | Medline

[6]

G.I. Kirchner, I. Meier-Wiedenbach, M.P. Manns.

Clinical pharmacokinetics of everolimus.

Clin Pharmacokinet, 43 (2004), pp. 83-95

http://dx.doi.org/10.2165/00003088-200443020-00002 | Medline

[7]

G. Levy, H. Schmidli, J. Punch, E. Tuttle-Newhall, D. Mayer, P. Neuhaus, et al.

Safety, tolerability, and efficacy of everolimus in de novo liver transplant recipients: 12-and 36-month results.

Liver Transpl, 12 (2006), pp. 1640-1648

http://dx.doi.org/10.1002/lt.20707 | Medline

[8]

M. Masetti, R. Montalti, G. Rompianesi, M. Codeluppi, R. Gerring, A. Romano, et al.

Early withdrawal of calcineurin inhibitors and everolimus monotherapy in de novo liver transplant recipients preserves renal function.

Am J Transplant, 10 (2010), pp. 2252-2262

http://dx.doi.org/10.1111/j.1600-6143.2010.03128.x | Medline

[9]

L. Fischer, J. Klempnauer, S. Beckebaum, H.J. Metselaar, P. Neuhaus, P. Schemmer, et al.

A randomized, controlled study to assess the conversion from calcineurin-inhibitors to everolimus after liver transplantation – PROTECT.

Am J Transplant, 12 (2012), pp. 1855-1865

http://dx.doi.org/10.1111/j.1600-6143.2012.04049.x | Medline

[10]

M. Sterneck, G.M. Kaiser, N. Heyne, N. Richter, F. Rauchfuss, A. Pascher, et al.

Everolimus and early calcineurin inhibitor withdrawal: 3-year results from a randomized trial in liver transplantation.

Am J Transplant, 14 (2014), pp. 701-710

http://dx.doi.org/10.1111/ajt.12615 | Medline

[11]

M. Sterneck, G.M. Kaiser, N. Heyne, N. Richter, F. Rauchfuss, A. Pascher, et al.

Long-term follow-up of five yr shows superior renal function with everolimus plus early calcineurin inhibitor withdrawal in the PROTECT randomized liver transplantation study.

Clin Transplant, 30 (2016), pp. 741-748

http://dx.doi.org/10.1111/ctr.12744 | Medline

[12]

P. De Simone, F. Nevens, L. de Carlis, H.J. Metselaar, S. Beckebaum, F. Saliba, et al.

Everolimus with reduced tacrolimus improves renal function in de novo liver transplant recipients: a randomized controlled trial.

Am J Transplant, 12 (2012), pp. 3008-3020

http://dx.doi.org/10.1111/j.1600-6143.2012.04212.x | Medline

[13]

F. Saliba, P. De Simone, F. Nevens, L. De Carlis, H.J. Metselaar, S. Beckebaum, et al.

Renal function at two years in liver transplant patients receiving everolimus: results of a randomized, multicenter study.

Am J Transplant, 13 (2013), pp. 1734-1745

http://dx.doi.org/10.1111/ajt.12280 | Medline

[14]

L. Fischer, F. Saliba, G.M. Kaiser, L. De Carlis, H.J. Metselaar, P. De Simone, et al.

Three-year outcomes in de novo liver transplant patients receiving everolimus with reduced tacrolimus: follow-up results from a randomized, multicenter study.

Transplantation, 99 (2015), pp. 1455-1462

http://dx.doi.org/10.1097/TP.0000000000000555 | Medline

[15]

T.A. Gonwa, M.L. Mai, L.B. Melton, S.R. Hays, R.M. Goldstein, M.F. Levy, et al.

End-stage renal disease (ESRD) after orthotopic liver transplantation (OLTX) using calcineurin-based immunotherapy: risk of development and treatment.

Transplantation, 72 (2001), pp. 1934-1939

Medline

[16]

J.M. Moreno, V. Cuervas-Mons, E. Rubio, F. Pons, T.A. Herreros de, V.S. Turrion, et al.

Chronic renal dysfunction after liver transplantation in adult patients: prevalence, risk factors, and impact on mortality.

Transplant Proc, 35 (2003), pp. 1907-1908

Medline

[17]

E. Varo, R. Banares, M. Guilera.

Underestimation of chronic renal dysfunction after liver transplantation: ICEBERG study.

World J Transplant, 5 (2015), pp. 26-33

http://dx.doi.org/10.5500/wjt.v5.i1.26 | Medline

[18]

P. Sharma, K. Bari.

Chronic kidney disease and related long-term complications after liver transplantation.

Adv Chronic Kidney Dis, 22 (2015), pp. 404-411

http://dx.doi.org/10.1053/j.ackd.2015.06.001 | Medline

[19]

M. Cantarovich, J. Tchervenkov, S. Paraskevas, P. Ghali, P. Wong, M. Deschenes, et al.

Early changes in kidney function predict long-term chronic kidney disease and mortality in patients after liver transplantation.

Transplantation, 92 (2011), pp. 63-1358

[20]

P. Burra, M. Senzolo, A. Masier, H. Prestele, R. Jones, D. Samuel, et al.

Factors influencing renal function after liver transplantation. Results from the MOST, an international observational study.

Dig Liver Dis, 41 (2009), pp. 350-356

http://dx.doi.org/10.1016/j.dld.2008.09.018 | Medline

[21]

A.M. Allen, W.R. Kim, T.M. Therneau, J.J. Larson, J.K. Heimbach, A.D. Rule.

Chronic kidney disease and associated mortality after liver transplantation – a time-dependent analysis using measured glomerular filtration rate.

J Hepatol, 61 (2014), pp. 286-292

http://dx.doi.org/10.1016/j.jhep.2014.03.034 | Medline

[22]

A.O. Ojo, P.J. Held, F.K. Port, R.A. Wolfe, A.B. Leichtman, E.W. Young, et al.

Chronic renal failure after transplantation of a nonrenal organ.

N Engl J Med, 349 (2003), pp. 931-940

http://dx.doi.org/10.1056/NEJMoa021744 | Medline

[23]

D.Y. Kim, C. Lim, R. Parasuraman, M. Raoufi, A. Yoshida, J. Arenas, et al.

Renal disease burden following liver transplantation.

Transplant Proc, 38 (2006), pp. 5-3663

[24]

H. Tedesco Silva Jr., D. Cibrik, T. Johnston, E. Lackova, K. Mange, C. Panis, et al.

Everolimus plus reduced-exposure CsA versus mycophenolic acid plus standard-exposure CsA in renal-transplant recipients.

Am J Transplant, 10 (2010), pp. 13-1401

[25]

R.M. Langer, R. Hene, S. Vitko, M. Christiaans, H. Tedesco-Silva Jr., K. Ciechanowski, et al.

Everolimus plus early tacrolimus minimization: a phase III, randomized, open-label, multicentre trial in renal transplantation.

Transpl Int, 25 (2012), pp. 592-602

http://dx.doi.org/10.1111/j.1432-2277.2012.01465.x | Medline

[26]

P. De Simone, H.J. Metselaar, L. Fischer, J. Dumortier, K. Boudjema, J. Hardwigsen, et al.

Conversion from a calcineurin inhibitor to everolimus therapy in maintenance liver transplant recipients: a prospective, randomized, multicenter trial.

Liver Transpl, 15 (2009), pp. 1262-1269

http://dx.doi.org/10.1002/lt.21827 | Medline

[27]

J.F. Castroagudin, E. Molina, R. Romero, E. Otero, S. Tome, E. Varo.

Improvement of renal function after the switch from a calcineurin inhibitor to everolimus in liver transplant recipients with chronic renal dysfunction.

Liver Transpl, 15 (2009), pp. 1792-1797

http://dx.doi.org/10.1002/lt.21920 | Medline

[28]

F. Saliba, S. Dharancy, R. Lorho, F. Conti, S. Radenne, M. Neau-Cransac, et al.

Conversion to everolimus in maintenance liver transplant patients: a multicenter, retrospective analysis.

Liver Transpl, 17 (2011), pp. 905-913

http://dx.doi.org/10.1002/lt.22292 | Medline

[29]

I. Bilbao, M. Salcedo, M.A. Gomez, C. Jimenez, J. Castroagudin, J. Fabregat, et al.

Renal function improvement in liver transplant recipients after early everolimus conversion: a clinical practice cohort study in Spain.

Liver Transpl, 21 (2015), pp. 1056-1065

http://dx.doi.org/10.1002/lt.24172 | Medline

[30]

A. Jemal, F. Bray, M.M. Center, J. Ferlay, E. Ward, D. Forman.

Global cancer statistics.

CA Cancer J Clin, 61 (2011), pp. 69-90

http://dx.doi.org/10.3322/caac.20107 | Medline

[31]

European Liver Transplant Registry. Volume 2016.

[32]

ONT.

Memoria trasplante hepático 2015. Volume 2016.

(2015),

[33]

A. Forner, J.M. Llovet, J. Bruix.

Hepatocellular carcinoma.

Lancet, 379 (2012), pp. 55-1245

http://dx.doi.org/10.1016/S0140-6736(11)61138-0 | Medline

[34]

E.A. Pomfret, K. Washburn, C. Wald, M.A. Nalesnik, D. Douglas, M. Russo, et al.

Report of a national conference on liver allocation in patients with hepatocellular carcinoma in the United States.

Liver Transpl, 16 (2010), pp. 262-278

http://dx.doi.org/10.1002/lt.21999 | Medline

[35]

M.A. Zimmerman, R.M. Ghobrial, M.J. Tong, J.R. Hiatt, A.M. Cameron, J. Hong, et al.

Recurrence of hepatocellular carcinoma following liver transplantation: a review of preoperative and postoperative prognostic indicators.

Arch Surg, 143 (2008), pp. 182-188

http://dx.doi.org/10.1001/archsurg.2007.39 | Medline

[36]

B. Vogelstein, K.W. Kinzler.

Cancer genes and the pathways they control.

Nat Med, 10 (2004), pp. 789-799

http://dx.doi.org/10.1038/nm1087 | Medline

[37]

M.S. Matter, T. Decaens, J.B. Andersen, S.S. Thorgeirsson.

Targeting the mTOR pathway in hepatocellular carcinoma: current state and future trends.

J Hepatol, 60 (2014), pp. 855-865

http://dx.doi.org/10.1016/j.jhep.2013.11.031 | Medline

[38]

C. Duvoux, C. Toso.

mTOR inhibitor therapy: does it prevent HCC recurrence after liver transplantation?.

Transplant Rev (Orlando), 29 (2015), pp. 168-174

[39]

G. Schumacher, M. Oidtmann, A. Rueggeberg, D. Jacob, S. Jonas, J.M. Langrehr, et al.

Sirolimus inhibits growth of human hepatoma cells alone or combined with tacrolimus, while tacrolimus promotes cell growth.

World J Gastroenterol, 11 (2005), pp. 5-1420

[40]

M. Rodriguez-Peralvarez, M. De la Mata, A.K. Burroughs.

Liver transplantation: immunosuppression and oncology.

Curr Opin Organ Transplant, 19 (2014), pp. 253-260

http://dx.doi.org/10.1097/MOT.0000000000000069 | Medline

[41]

M. Vivarelli, A. Cucchetti, G. La Barba, M. Ravaioli, M. del Gaudio, A. Lauro, et al.

Liver transplantation for hepatocellular carcinoma under calcineurin inhibitors: reassessment of risk factors for tumor recurrence.

Ann Surg, 248 (2008), pp. 857-862

http://dx.doi.org/10.1097/SLA.0b013e3181896278 | Medline

[42]

W. Liang, D. Wang, X. Ling, A.A. Kao, Y. Kong, Y. Shang, et al.

Sirolimus-based immunosuppression in liver transplantation for hepatocellular carcinoma: a meta-analysis.

Liver Transpl, 18 (2012), pp. 62-69

http://dx.doi.org/10.1002/lt.22441 | Medline

[43]

K.V. Menon, A.R. Hakeem, N.D. Heaton.

Meta-analysis: recurrence and survival following the use of sirolimus in liver transplantation for hepatocellular carcinoma.

Aliment Pharmacol Ther, 37 (2013), pp. 411-419

http://dx.doi.org/10.1111/apt.12185 | Medline

[44]

E. Cholongitas, C. Mamou, K.I. Rodriguez-Castro, P. Burra.

Mammalian target of rapamycin inhibitors are associated with lower rates of hepatocellular carcinoma recurrence after liver transplantation: a systematic review.

Transpl Int, 27 (2014), pp. 49-1039

http://dx.doi.org/10.1111/tri.12199 | Medline

[45]

E.K. Geissler, A.A. Schnitzbauer, C. Zulke, P.E. Lamby, A. Proneth, C. Duvoux, et al.

Sirolimus use in liver transplant recipients with hepatocellular carcinoma: a randomized, multicenter, open-label phase 3 trial.

Transplantation, 100 (2016), pp. 116-125

http://dx.doi.org/10.1097/TP.0000000000000965 | Medline

[46]

E.L. Yanik, S. Chinnakotla, S.K. Gustafson, J.J. Snyder, A.K. Israni, D.L. Segev, et al.

Effects of maintenance immunosuppression with sirolimus after liver transplant for hepatocellular carcinoma.

Liver Transpl, 22 (2016), pp. 627-634

http://dx.doi.org/10.1002/lt.24395 | Medline

[47]

C. Gomez-Martin, J. Bustamante, J.F. Castroagudin, M. Salcedo, E. Garralda, M. Testillano, et al.

Efficacy and safety of sorafenib in combination with mammalian target of rapamycin inhibitors for recurrent hepatocellular carcinoma after liver transplantation.

Liver Transpl, 18 (2012), pp. 45-52

http://dx.doi.org/10.1002/lt.22434 | Medline

[48]

A. Mancuso, G. Perricone.

Time to resize the role of everolimus as treatment of hepatocellular carcinoma recurrence after liver transplant.

Transpl Int, 28 (2015), pp. 502

http://dx.doi.org/10.1111/tri.12477 | Medline

[49]

P. De Simone, L. Crocetti, D. Pezzati, I. Bargellini, D. Ghinolfi, P. Carrai, et al.

Efficacy and safety of combination therapy with everolimus and sorafenib for recurrence of hepatocellular carcinoma after liver transplantation.

Transplant Proc, 46 (2014), pp. 4-241

[50]

H. Schrem, M. Kurok, A. Kaltenborn, A. Vogel, U. Walter, L. Zachau, et al.

Incidence and long-term risk of de novo malignancies after liver transplantation with implications for prevention and detection.

Liver Transpl, 19 (2013), pp. 61-1252

[51]

W.N. Schoening, N. Buescher, S. Rademacher, A. Andreou, S. Kuehn, R. Neuhaus, et al.

Twenty-year longitudinal follow-up after orthotopic liver transplantation: a single-center experience of 313 consecutive cases.

Am J Transplant, 13 (2013), pp. 2384-2394

http://dx.doi.org/10.1111/ajt.12384 | Medline

[52]

E. Chak, S. Saab.

Risk factors and incidence of de novo malignancy in liver transplant recipients: a systematic review.

Liver Int, 30 (2010), pp. 1247-1258

http://dx.doi.org/10.1111/j.1478-3231.2010.02303.x | Medline

[53]

S. Benlloch, M. Berenguer, M. Prieto, R. Moreno, F. San Juan, M. Rayon, et al.

De novo internal neoplasms after liver transplantation: increased risk and aggressive behavior in recent years?.

Am J Transplant, 4 (2004), pp. 596-604

http://dx.doi.org/10.1111/j.1600-6143.2004.00380.x | Medline

[54]

M. Majewski, M. Korecka, P. Kossev, S. Li, J. Goldman, J. Moore, et al.

The immunosuppressive macrolide RAD inhibits growth of human Epstein-Barr virus-transformed B lymphocytes in vitro and in vivo: a potential approach to prevention and treatment of posttransplant lymphoproliferative disorders.

Proc Natl Acad Sci USA, 97 (2000), pp. 4285-4290

http://dx.doi.org/10.1073/pnas.080068597 | Medline

[55]

I. Bilbao, C. Dopazo, J. Lazaro, L. Castells, M. Caralt, G. Sapisochin, et al.

Multiple indications for everolimus after liver transplantation in current clinical practice.

World J Transplant, 4 (2014), pp. 122-132

http://dx.doi.org/10.5500/wjt.v4.i2.122 | Medline

[56]

J. Gomez-Camarero, M. Salcedo, D. Rincon, O. Lo Iacono, C. Ripoll, A. Hernando, et al.

Use of everolimus as a rescue immunosuppressive therapy in liver transplant patients with neoplasms.

Transplantation, 84 (2007), pp. 786-791

http://dx.doi.org/10.1097/01.tp.0000280549.93403.dd | Medline

[57]

E. Thimonier, O. Guillaud, T. Walter, E. Decullier, M. Vallin, O. Boillot, et al.

Conversion to everolimus dramatically improves the prognosis of de novo malignancies after liver transplantation for alcoholic liver disease.

Clin Transplant, 28 (2014), pp. 1339-1348

http://dx.doi.org/10.1111/ctr.12430 | Medline

[58]

I. Bilbao, G. Sapisochin, C. Dopazo, J.L. Lazaro, L. Pou, L. Castells, et al.

Indications and management of everolimus after liver transplantation.

Transplant Proc, 41 (2009), pp. 2172-2176

http://dx.doi.org/10.1016/j.transproceed.2009.06.087 | Medline

[59]

C. Jimenez-Romero, A. Manrique, E. Marques, J. Calvo, A.G. Sesma, F. Cambra, et al.

Switching to sirolimus monotherapy for de novo tumors after liver transplantation. A preliminary experience.

Hepatogastroenterology, 58 (2011), pp. 115-121

Medline

[60]

AEMPS. Ficha Técnica Certican.

[61]

H.J. Schuurman, S. Cottens, S. Fuchs, J. Joergensen, T. Meerloo, R. Sedrani, et al.

SDZ RAD, a new rapamycin derivative: synergism with cyclosporine.

Transplantation, 64 (1997), pp. 32-35

Medline

[62]

J.M. Kovarik, J.J. Curtis, D.E. Hricik, M.D. Pescovitz, V. Scantlebury, A. Vasquez.

Differential pharmacokinetic interaction of tacrolimus and cyclosporine on everolimus.

Transplant Proc, 38 (2006), pp. 8-3456

[63]

J. Dumortier, S. Dharancy, Y. Calmus, C. Duvoux, F. Durand, E. Salame, et al.

Use of everolimus in liver transplantation: the French experience.

Transplant Rev (Orlando), 30 (2016), pp. 161-170

[64]

N. Manito, J.F. Delgado, M.G. Crespo-Leiro, F. Gonzalez-Vilchez, L. Almenar, J.M. Arizon, et al.

Clinical recommendations for the use of everolimus in heart transplantation.

Transplant Rev (Orlando), 24 (2010), pp. 129-142

[65]

C. Gurk-Turner, W. Manitpisitkul, M. Cooper.

A comprehensive review of everolimus clinical reports: a new mammalian target of rapamycin inhibitor.

Transplantation, 94 (2012), pp. 659-668

http://dx.doi.org/10.1097/TP.0b013e31825b411c | Medline

[66]

G.M. Keating, K.A. Lyseng-Williamson.

Everolimus: a guide to its use in liver transplantation.

BioDrugs: Clin Immunother Biopharm Gene Ther, 27 (2013), pp. 407-411

[67]

S. Beckebaum, V.R. Cicinnati, A. Radtke, I. Kabar.

Calcineurin inhibitors in liver transplantation-still champions or threatened by serious competitors?.

Liver Int, 33 (2013), pp. 656-665

http://dx.doi.org/10.1111/liv.12133 | Medline

[68]

A. De Pablo, F. Santos, A. Sole, J.M. Borro, J.M. Cifrian, R. Laporta, et al.

Recommendations on the use of everolimus in lung transplantation.

Transplant Rev (Orlando), 27 (2013), pp. 9-16

[69]

B. Kaplan, Y. Qazi, J.R. Wellen.

Strategies for the management of adverse events associated with mTOR inhibitors.

Transplant Rev (Orlando), 28 (2014), pp. 126-133

[70]

P. De Simone, P. Carrai, A. Precisi, S. Petruccelli, L. Baldoni, E. Balzano, et al.

Conversion to everolimus monotherapy in maintenance liver transplantation: feasibility, safety, and impact on renal function.

Transpl Int, 22 (2009), pp. 86-279

[71]

J.C. Ruiz, F. Diekmann, J.M. Campistol, A. Sanchez-Fructuoso, C. Rivera, J. Oliver, et al.

Evolution of proteinuria after conversion from calcineurin inhibitors (CNI) to sirolimus (SRL) in renal transplant patients: a multicenter study.

Transplant Proc, 37 (2005), pp. 5-3833

[72]

F. Diekmann, K. Budde, F. Oppenheimer, L. Fritsche, H.H. Neumayer, J.M. Campistol.

Predictors of success in conversion from calcineurin inhibitor to sirolimus in chronic allograft dysfunction.

Am J Transplant, 4 (2004), pp. 75-1869

[73]

H. Holdaas, L. Potena, F. Saliba.

mTOR inhibitors and dyslipidemia in transplant recipients: a cause for concern?.

Transplant Rev (Orlando), 29 (2015), pp. 93-102

☆

Please cite this article as: Rubín Suárez A, Bilbao Aguirre I, Fernández-Castroagudin J, Pons Miñano JA, Salcedo Plaza M, Varo Pérez E, et al. Recomendaciones de uso de everolimus en el trasplante hepático. Gastroenterol Hepatol. 2017;40:629–640.

☆☆

Independent study conducted by experts from the Sociedad Española de Trasplante Hepático (Spanish Liver Transplantation Society, SETH) and endorsed by the SETH. Funded by Novartis.

Indexada en:

Síguenos:

Suscribirse:

Indexada en:

Síguenos:

Suscribirse:

Suscríbase a la newsletter