metricas
covid
Buscar en
Cirugía Española (English Edition)
Toda la web
Inicio Cirugía Española (English Edition) Liver Transplant With Donated Graft After Controlled Cardiac Death. Current situ...
Información de la revista
Vol. 91. Núm. 9.
Páginas 554-562 (noviembre 2013)
Visitas
3126
Vol. 91. Núm. 9.
Páginas 554-562 (noviembre 2013)
Review Article
Acceso a texto completo
Liver Transplant With Donated Graft After Controlled Cardiac Death. Current situation
Trasplante hepático con injerto procedente de donación después de muerte cardiocirculatoria controlada. Situación actual
Visitas
3126
Manuel Abradelo De Usera
Autor para correspondencia
manuel.abradelo@hotmail.com

Corresponding author.
, Carlos Jiménez Romero, Carmelo Loinaz Segurola, Enrique Moreno González
Servicio de Cirugía General, Aparato Digestivo y Trasplante de Órganos Abdominales, Hospital Universitario 12 de Octubre, Madrid, Spain
Este artículo ha recibido
Información del artículo
Resumen
Texto completo
Bibliografía
Descargar PDF
Estadísticas
Figuras (1)
Tablas (4)
Table 1. Modified Maastricht Classification (ONT, Madrid 2011) for Donation After Cardio-circulatory Death.
Table 2. Biliary Complications, Ischaemic Cholangiopathy, and Retransplantation With Ischaemic Cholangiopathy.
Table 3. Patient and Graft Survival, as Well as Retransplantation Rate, in Series of Liver Transplants Using Grafts From Controlled Donation After Cardio-circulatory Death.
Table 4. Graft and Recipient Survival, as Well as Retransplantation Rate, in Series of Liver Transplants Using Grafts From Controlled Donation After Cardio-circulatory Death.
Mostrar másMostrar menos
Abstract

An increasing pressure on the liver transplant waiting list forces us to explore new sources, in order to expand the donor pool. One of the most interesting benevolences and with a promising potential is donation after cardiac death (DCD). Initially, this activity was developed in Spain by means of the Maastricht type II donation in the uncontrolled setting. For different reasons, donation after controlled cardiac death has been reconsidered in our country. The most outstanding circumstance involved in DCD donation is a potential ischaemic stress that could cause severe liver graft cell damage, resulting in an adverse effect on liver transplant results, in terms of complications and outcomes. The complex and particular issues related to DCD donation will be discussed in this review.

Keywords:
Liver transplantation
Cardiac death
Asystole
Resumen

La presión en lista de espera de trasplante hepático obliga a la exploración de nuevas fuentes de donación, siendo la utilización de injertos procedentes de donantes después de muerte cardiocirculatoria una de las que reúnen un potencial más prometedor e interesante. Inicialmente, este recurso ha sido utilizado en España a través de la llamada categoría II de Maastricht, previamente denominada asistolia no controlada tipo II. Diferentes motivos han conducido a reconsiderar la donación después de la llamada muerte cardiocirculatoria controlada en el territorio nacional. El fenómeno distintivo en este tipo de donación es el estrés isquémico al que se exponen los órganos del donante con sus importantes implicaciones sobre los resultados. Los aspectos particulares de esta modalidad de trasplante hepático son el objeto de este trabajo.

Palabras clave:
Trasplante hepático
Muerte cardiocirculatoria
Asistolia
Texto completo
Introduction

Expanding the organ donor pool is essential for liver transplantation due to the clear disproportion between candidates on the waiting list and the number of donors, which affects the chance of mortality on the waiting list.

Extended criteria grafts or donors1 are central for the development of liver transplantation; however, there continues to be only a small proportion of donors in the country today.

Spain has the most solid experience in type II uncontrolled liver transplantation and donation after cardio-circulatory death worldwide2–6 (Table 1). This procedure comprised 0.7% of all transplant activity in 2011.7 This statistic contrasts with the much more extensive use of grafts via controlled donations after cardio-circulatory death in countries such as the UK and the US, where the activity of solid organ transplants performed with donors has reached 35% and 10%, respectively.8

Table 1.

Modified Maastricht Classification (ONT, Madrid 2011) for Donation After Cardio-circulatory Death.

Controlled cardio-circulatory death
Patient dies outside of the hospital  Victims of sudden death (traumatic or not) occurring outside the hospital who are not resucitatedd 
II  Unsuccessful resuscitation  Patients suffering from cardiac arrest and undergoing unsuccessful resuscitation manoeuvresThis category includes two subcategories:II.A. Out-of-hospitalCardiac arrest occurring in an out-of-hospital setting and served by out-of-hospital emergency services personnel who transfer the patient to the hospital with cardiac-resuscitation manoeuvres and life supportII. B. Intra-hospitalCardiac arrest occurring in the hospital and witnessed by medical personnel using immediate resuscitation manoeuvres 
Controlled cardio-circulatory death
III  Awaiting cardiac arrest  Patients for whom life sustaining treatments are limited after reaching an agreement between the healthcare team and the family or the patient's representatives 
IV  Cardiac arrest after brain-stem death  Patients who suffer cardiac arrest during or after the establishment of a brain death diagnosis but before they enter the operating room. It is likely that doctors will attempt to restore cardiac activity; however, when these measures are unsuccessful, the procedure can be modified to donation after cardio-circulatory death 

The major reasons for the initial reluctance to use potential donors who were removed from life support are the ethical obstacles in the Spanish Consensus Document produced by the Spanish Transplant Groups and the National Transplant Organisation (ONT) in 1995.9 However, several factors have led to new assessments of this donor pool in Spain.

As discussed above, the pressure on the waiting list has increased gradually; additionally, the experiences observed in other European countries and the US have offered consistent and promising results with regard to the use of liver grafts.

Importantly, the development of Draft Law 121/000132, which regulates the rights of people at the end of their lives,10 implies a change in the legal framework that might lead to the development of controlled donations after cardio-circulatory death programmes in Spain. Finally, the ONT has actively promoted the development of a consensus protocol to establish the basis for this type of organ donation.6

Thus, experiences concerning controlled donations after cardio-circulatory death have already begun. Hospital Santiago Apostol of Vitoria11 is pioneering this field, and many donations have been made sporadically in different centres throughout Spain. Most of these donations have involved renal grafts for implantation, although it is expected that liver grafts will soon follow in parallel.

The first use of a liver graft obtained from a controlled donation after cardio-circulatory death in Spain occurred at the University Hospital 12 de Octubre in Madrid on May 11, 2011: a candidate on the waiting list received a successful transplant.12

These facts encourage us to carefully analyse the complex and interesting details of this type of donation as well as the results achieved from the use of these grafts.

Warm Ischaemia in Donors

Warm ischaemia in donors has important differences with other types of liver donation. Cardiovascular death (in Maastricht II and III categories)5 causes potential ischaemic stress damage, which is of paramount importance in the development of complications among liver transplantation recipients. The transition from a predominantly aerobic metabolism to an anaerobic metabolism that does not meet energy demands can cause serious damage and even cell death. Ischaemic injury to hepatocytes and bile ducts differs: Massive hepatocyte damage will cause primary graft failure immediately, thereby forcing liver re-transplantation, whereas milder degrees of damage can lead to a severe graft dysfunction in which the future viability of the organ depends on its regenerative capacity. Ischaemic injury to the bile ducts will manifest as an inflammatory stenosing disease (also known as ischaemic cholangiopathy), and the transplanted graft viability depends on its intensity. The specific pathophysiological mechanisms involved in the onset of these complications are not well known; nevertheless, the impaired function of the Na/K pump, vascular microthrombosis,13 changes in bile salt metabolism,14 the overproduction of free radicals, or impaired ATP metabolism with hypoxanthine overproduction15 have all been implicated in the occurrence of these adverse events.

These findings show major differences with donations after brain death in which other systemic inflammatory response events prevail with a marked increase of inflammatory mediators and different consequences for transplant graft viability.16

The definitions of warm ischaemia times that must be accounted for in liver graft transplants from controlled donation after cardio-circulatory death and that are essential in this type of donation are included in different guides and protocols6,17,18 and deserve comment.

Cardio-circulatory death occurs sometime after the withdrawal of life support, and it is recommended that the liver not be used if transplantation does not occur in the first 60min after life support is withdrawn. Fig. 1 shows the different phases of donation, preservation, and transplant protocol after controlled cardio-circulatory death. Two concepts must be considered: total ischaemia time and functional or real ischaemia time.

Fig. 1.

Donation, preservation, and transplant protocol for controlled donation after cardio-circulatory death.

(0.18MB).

First, total warm ischaemia time begins by withdrawing life support measures and concludes with the start of preservation, either by cold perfusion or normothermic recirculation using an extracorporeal membrane oxygenation (ECMO) device in the donor. However, functional warm ischaemia (also called real warm ischaemia) is more relevant and begins with the first episode of arterial desaturation (Sat PO2<70%–80%), low blood pressure (SBP<60–50mmHg), or both observed after the withdrawal of life support. It ends with cold perfusion or ECMO administration, which limits the total warm ischaemia time. The maximum acceptable time for safe liver donation is 30min of real or functional ischaemia; however, past reports have used slightly prolonged donor warm ischaemia times.19

In any case, it is remarkable that these warm ischaemia times include 5min of immediate observation after asystole to certify death, the time needed to transfer the body to the operating room or surgical table (when life support is not withdrawn in the operating room), and the time needed to initiate the necessary preservation manoeuvres via cold perfusion or normothermic recirculation.

Controlled Cardio-circulatory Death and Brain Death

Liver transplant surgeons do not decide when to remove life support. This decision must be made previously and independent of the decision to donate an organ for transplantation. In this sense, certain issues with this type of donation must be taken into account.

Indiscriminate replacement or competition between donation after brain death and controlled donation after cardio-circulatory death are disturbing phenomena (as different studies20,21 have discussed) that should be analysed and prevented. When performed indiscriminately, donation replacement after brain death can negatively affect liver transplantation activity, both qualitatively (i.e., transplant outcomes) and quantitatively (i.e., the number of valid organs).

In its recent document Donation after Cardio-circulatory Death in Spain: Current Status and Recommendations,6 the ONT referred to the lower overall profitability of this type of donation given the aforementioned quantitative and qualitative aspects. Furthermore, it recommended that the organ donor pool should not be considered as an alternative to donation after brain death. Rather, this approach should be considered primarily in cases in which the progression to donor brain death (patients with severe neurological diseases and catastrophic functional prognosis in most cases) cannot be predicted.

With regard to the negative quantitative aspects of this type of donation, importantly, 3.6 organs were transplanted per donor after brain death on average, and 2.1 organs were transplanted per donor after controlled cardio-circulatory death in the UK.22 However, the use of a graft from a donor after cardio-circulatory death eliminates adverse factors such as steatosis, the need for drugs, cardiac arrest prior to donation, or other events that add to the ischaemic stress of the donation process and exclude a graft that would otherwise be transplanted after brain death. The age of liver donors has increased gradually. Moreover, given that most transplant groups accept a recommended maximum safe age between 60 and 65 years for liver donors after controlled cardio-circulatory death, indiscriminate replacement would also predict a decline in the number of liver donors.

One additional and remarkable problem from controlled donation after cardio-circulatory death is derived from the high proportion of potential donors who, once life support has been withdrawn, only suffer asystole after long warm ischaemia times, which is especially critical in liver donation and which prevents the use of potential grafts. The incidence of donor cancellation for the aforementioned reasons is approximately 40% of the potential donations after cardio-circulatory death in the UK, resulting in the reduction of liver grafts.22

Technical Aspects

The rapid technique is the most widespread surgical method used to procure these grafts, which was described in Pittsburgh in 1995.23

This technique is performed after death is declared and is based on immediate access to the infrarenal aorta for the direct administration of a heparinised cold preservation solution. The inferior vena cava is drained, and the supraceliac aorta is clamped at the abdominal or intra-thoracic level afterwards to select the perfusion territory. At the same time, the abdominal organs are cooled externally with cold serum, and portal perfusion is also performed with heparinised solution. The premortem percutaneous implantation of a double balloon catheter for selecting the perfusion territory24 streamlines the beginning perfusion process after death; however, it entails requesting the consent of the donor to conduct heparinisation and cannulation, and it increases the cost of the procedure.

New modifications of the procurement technique are currently being investigated.25 One alternative to the rapid cold perfusion technique would be to establish a normothermic recirculation circuit26 similar to those used in the most experienced centres for uncontrolled donation after cardio-circulatory death.3,27 The advantages of using this option are based on ischaemic preconditioning and the possibility of determining the markers of graft viability during maintenance. Currently, scientific evidence does not exist for these potential advantages, nor is there an approach to the recommended donor normothermic recirculation maintenance time. These issues are currently under investigation.

Liver Transplantation and Controlled Cardio-circulatory Death Results

This type of donation requires studying the potential complications that occur with greater prevalence in this type of transplantation. The hypoxia and hypotension related to the time elapsed between the withdrawal of life support and early preservation manoeuvres (either by cold perfusion or normothermic recirculation) likely play a decisive role in the development of these phenomena.

As with the analysis of the potential adverse events derived from using such grafts, the economic implications of this type of donation should be known. Specifically, the use of grafts from cardio-circulatory death donors has been estimated to increase the costs of liver transplantation up to 25%, even doubling the costs of retransplantation.28

Complications: Graft Arterial Thrombosis, Primary Graft Failure, Ischaemic Cholangiopathy, and Hepatitis C Virus Reinfection Recurrence Profile

Although arterial thrombosis was a particularly frequent phenomenon among transplants performed with this type of graft in an initial series,29 the most recent studies do not confirm these findings, and this complication appears at a frequency similar to that of conventional grafts.

Primary liver graft failure is the most common manifestation of ischaemic stress; it involves massive hepatocyte death with fulminant hepatic failure immediately after the implantation, and it requires urgent retransplantation to save the recipient's life. This complication has been reported with variable frequency, and has decreased since the initial series. Currently, it constitutes a rare complication, with appearance rates that did not reach 4% in the most recent series.30–33 Multiple factors are involved in the decreased frequency of this phenomenon, which is related to the surgical learning curve as well as improvements in preservation techniques and organ procurement.

Ischaemic cholangiopathy, which is characterised by the presence of hilar, intrahepatic, or both types of biliary strictures in the absence of arterial thrombosis, is another manifestation of tissue hypoperfusion or hypoxia suffered by the donor. This complication is not immediate, and it appears with varying frequency and timing unlike primary graft failure. The fact that 50% of hepatic blood flows through the bile duct system likely explains why an inflammatory response is triggered during intense transient ischaemic injury, ultimately resulting in the appearance of hilar, intrahepatic, or both types of biliary strictures, despite the patent arterial flow at diagnosis.34

The prevalence of this complication was high in the first procedures that used these controlled donors; however, this phenomenon occurred less frequently in the latest series (Table 2). Specifically, the complication rate of biliary ischaemic cholangiopathy was less than 3%,21 even with the use of extended criteria grafts from donations after cardio-circulatory death.17

Table 2.

Biliary Complications, Ischaemic Cholangiopathy, and Retransplantation With Ischaemic Cholangiopathy.

Author  Year  # Transplantation after cardio-circulatory death  Biliary complication %  Ischaemic cholangiopathy % 
Taner35  2012  200    12 
de Oliveira21  2011  152  19.7  2.5 
de Vera36  2009  141  25   
Foley31  2011  87  47  34 
Hong37  2011  81  29  9.9 
Tariciotti19  2011  66  12.6 
Detry32  2011  58     
Dubbeld33  2011  55    31 
Chan38  2008  52    13.7 
Pine39  2009  39    20.5 
Skaro40  2009  32  22  38 
Croome41  2012  36  25   
Meurisse42  2012  30  50  33.3 

Biliary and ischaemic cholangiopathy complications in a series of liver transplants using grafts from controlled donation after cardio-circulatory death.

In either case, ischaemic cholangiopathy appears to be particularly associated with the use of grafts from asystolic donors, and a recent metaanalysis43 confirmed that this complication occurs in 16% of cases. Thus, the risk of using these grafts is more than 10 times higher than when using grafts from brain death donors.

The risk factors associated with the occurrence of this complication have been investigated, and they include older donor age,31,36,38,40 high donor weight38 or high donor/recipient weight ratio,40 or longer warm35 or cold ischaemia times.31,38,42

Several methods have been used to control the occurrence of this problem, such as arterial pressure perfusion44 or tissue plasminogen activation.13 The management of this condition also depends on its anatomic characteristics and the consequences of this phenomenon on graft function. In the case of a non-diffuse problem that does not cause significant graft dysfunction, the first approach is based on expansion via the percutaneous method of interventional radiology or endoscopic treatment, which has obtained successful responses in 30% of the cases.31

The implications of this complication are extremely far-reaching because it is the most frequent cause of retransplantation when using liver grafts donated after cardio-circulatory death28,40,45; furthermore, most patients who suffer from ischaemic cholangiopathy will require retrasplantation.31,35,41

Therefore, retransplantation should be considered early given the numerous procedures that might be needed to manage this complication, its intrinsic risks, the additional costs incurred by endoscopic treatment or interventional radiology, and the low likelihood of resolving the problem.

Recipient Selection

The proper selection of a suitable recipient for a graft with these characteristics remains the subject of study and debate. Theoretically, candidates with more limited functional reserves should have more difficulties with the complications associated with the use of these grafts; therefore, most recent registry studies have shown a significant trend to implant these organs in patients with lower model of end-stage liver disease (MELD) scores or those that are in particularly compromised clinical situations.45–50 Some studies have suggested the presence of a negative effect on candidates with higher MELD scores or worse clinical conditions46,47,49,51; however, this point remains under investigation. In contrast, the appropriate selection of donors and recipients has yielded satisfactory results using these liver grafts, even when transplants are conducted in patients in critical situations.52

With regard to candidate selection, several adverse prognostic factors have been identified, such as the age of recipient,46–48,51 donated liver grafts after cardio-circulatory death used for liver retransplantation,47,49,51 shared organs48 or the presence of hepatocarcinoma46,48 or renal failure.46,48,51 However, the characteristics of the optimal recipient for this type of transplant are not yet fully defined.

The high prevalence of infection with HCV and its universal recurrence after transplantation in the viremic candidate force us to define HCV graft reinfection as a major problem in liver transplantation. According to a recent multicentre study,47 this phenomenon occurs among candidates undergoing liver transplantation with organs from cardio-circulatory death donors after the withdrawal of life support. Previous studies comparing the evolution of HCV-infected candidates have found worse outcomes associated with these grafts for some patients compared with recurrent HCV when the grafts are transplanted from brain death donors or cardio-circulatory death donors.53 Jay et al. examined 1113 patients48 and determined the maximum likelihood of graft loss in a case study of organ transplant from a donor after cardio-circulatory death for a candidate with HCV infection to establish a reference group for transplant patients with an organ donated after brain death but uninfected with HCV. However, the most recent study based on the United Net of Organ Sharing (UNOS) Registry, United States (which also had a large sample size54) concluded that transplants for HCV-positive candidates using these donors must be considered valid because significant negative effects have not been found for this population.

Recipient and Graft Survival

The characteristics of this type of transplant have promoted graft and patient survival; thus, they should be analysed. Most recent transplant studies have generally shown similar survival rates19,29,30,32,33,35,37,42,55–58 to those obtained using other organ donor pools (Table 3); however, some have shown significant disadvantages for liver transplantations using organs donated after cardio-circulatory death.31,36,39,40,58 Importantly, recent registry studies based on heterogeneous populations (but with consistent sample sizes; Table 4) have shown significantly lower graft survival rates45,50,51 and, in certain cases, poorer graft and recipient survival using transplanted organs from cardio-circulatory death donors46,48,49 compared with other liver donor pools.

Table 3.

Patient and Graft Survival, as Well as Retransplantation Rate, in Series of Liver Transplants Using Grafts From Controlled Donation After Cardio-circulatory Death.

Author  Year  # Transplantation after cardio-circulatory death  Recipient survivalGraft survivalRetransplantation rate 
      a1  3 and 5 years  a1  3 and 5 years 
Taner35*  2012  200  92.6  85  80.9  80.9  72.7  68.9   
de Vera36*  2009  141  79    70  69a    56a  18 
Grewal30*  2009  108  91.5  88.1  88.1  79.3  74.5  71  14.8 
Foley31*  2011  87  84a  68a    69a  56a    19 
Hong37  2011  81        78  62  53   
Tariciotti19  2011  63  88–90      82–90       
Detry32  2009  58  83.3  66.9    72.4  48.8     
Dubbeld33*  2011  55  85  50    74  68    18 
Hernández55  2011  41  88      78       
Pine39*  2009  39  82.1a  68.2a    79.5a  63.6a     
Skaro40*  2009  32  74  74    61a  53a    22 
Meurisse42*  2012  30  93  85  85  90  82  82 
Fujita56  2007  24  86.8  81.7    69.1  58.6    20.8 
Yamamoto29  2010  24  61.9  42.9  42.9  54.2  37.5  37.5   
Nguyen57*  2009  19  89.5    89.5  73.7    63.2  15.8 
Broomhead58*  2012  16  94      75a       

Graft and recipient survival in series of liver transplants using grafts from controlled donation after cardio-circulatory death.

*Comparative studies using a control group of donors with beating hearts.

a

Significance denoting less likely survival for a graft or organ recipient after cardio-circulatory death.

Table 4.

Graft and Recipient Survival, as Well as Retransplantation Rate, in Series of Liver Transplants Using Grafts From Controlled Donation After Cardio-circulatory Death.

Author  Year  # Transplantation after cardio-circulatory death  Survival recipientGraft survivalRetransplantation rate 
      a1  3 and 5 years  a1  3 and 5 years 
Harring46  2012  2351  84.4  74.8  68.9  75.3  63.9  56.2   
Mathur47  2010  1567          64.9    13.6 
Jay48  2011  1113  82  71          14.7 
Lee49  2006  874  82.3  75.9  65.3  72.1  61.8  38.8   
Selck45  2008  855        73.8  57.6    21.6a 
Merion50  2006  472        70.1  60.5     
Mateo51  2006  367        71  60     

Graft and recipient survival in registry studies of liver transplants using grafts from controlled donation after cardio-circulatory death.

a

Included on the retransplantation list.

Conclusions

The use of liver grafts from cardio-circulatory death donors provides promising results. This donor pool (which is just beginning in Spain) must be used rationally without competing with the brain death donor pool. Research on preservation techniques will most likely be helpful in the near future to control the specific complications observed in this type of liver transplantation, thereby substantially improving the results.

Financing

A postgraduate scholarship awarded by the Mutua Madrileña Foundation: Donation after Cardio-circulatory Death (Maastricht type III). Centre: Queen Elizabeth Hospital (Birmingham), UK.

Conflict of Interest

The authors declare no conflict of interest.

Acknowledgements

We thank the ONT for their continued encouragement and efforts towards the maximum development of organ donation in Spain.

References
[1]
F. Durand, J.F. Renz, B. Alkofer, P. Burra, P.A. Clavien, R.J. Porte, et al.
Report of the Paris consensus meeting on expanded criteria donors in liver transplantation.
Liver Transpl, 14 (2008), pp. 1964-2707
[2]
F. Suárez, A. Otero, M. Solla, F. Arnal, M.J. Lorenzo, M. Marini, et al.
Biliary complications after liver transplantation from Maastricht category-2 non-heart-beating donors.
Transplantation, 85 (2008), pp. 9-14
[3]
S. Jiménez-Galanes, M.J. Meneu-Diaz, A.M. Elola-Olaso, B. Pérez-Saborido, F.S. Yiliam, A.G. Calvo, et al.
Liver transplantation using uncontrolled non-heart-beating donors under normothermic extracorporeal membrane oxygenation.
Liver Transpl, 15 (2009), pp. 1110-1118
[4]
C. Fondevila, A.J. Hessheimer, E. Flores, A. Ruiz, N. Mestres, D. Calatayud, et al.
Applicability and results of Maastricht type 2 donation after cardiac death liver transplantation.
Am J Transplant, 12 (2012), pp. 162-170
[5]
G. Kootstra, J.H. Daemen, A. Oomen.
Categories of non-heart-beating donors.
Transplant Proc, 27 (1995), pp. 2893-2894
[6]
Documento Nacional de Consenso.
Donación en Asistolia en España: Situación Actual y Recomendaciones.
(2012),
[7]
Registro Español de Trasplante Hepático.
Memoria.
(2011),
[8]
M.T. Perera, S.R. Bramhall.
Current status and recent advances of liver transplantation from donation after cardiac death.
World J Gastrointest Surg, 3 (2011), pp. 167-176
[9]
J. Alvarez, R. Barrio.
Anexo I Documento de Consenso Español. En Donantes a corazón parado.
Experiencia del Hospital Clínico San Carlos, (1997), 848978423X, pp. 149-153
[10]
Boletín Oficial de las Cortes Generales de17 junio 2011. Número 132-1. 1–9.
[11]
E. Corral, J. Maynar, I. Saralegui, A. Manzano.
Donantes a corazón parado tipo III de Maastricht: una opción real.
Med Intensiva, 35 (2011), pp. 59-60
[12]
J.A. Sánchez-Izquierdo Riera, C. Cisneros Alonso, R. García Guijorro.
Donantes tipo III de Maastricht, Maastricht type III donors.
Med Intensiva, 35 (2011), pp. 524-525
[13]
K. Hashimoto, B. Eghtesada, G. Gunasekarana, M. Fujikia, T.D. Usoa, C. Quintini, et al.
Use of tissue plasminogen activator in liver transplantation from donation after cardiac death donors.
Am J Transplant, 10 (2010), pp. 2665-2672
[14]
M.J. Yska, C.I. Buis, D. Monbaliu, T.A. Schuurs, A.S. Gouw, O.N. Kahmann, et al.
The role of bile salt toxicity in the pathogenesis of bile duct injury after non-heart-beating porcine liver transplantation.
Transplantation, 85 (2008), pp. 1625-1631
[15]
M. Nagayama, T. Katsuramaki, H. Kimura, M. Isobe, M. Meguro, T. Matsuno, et al.
Prediction of graft viability from non-heart-beating donor pigs using hepatic microdialysate hypoxanthine levels.
J Surg Res, 107 (2002), pp. 210-218
[16]
B. Floerchinger, R. Oberhuber, S.G. Tullius.
Effects of brain death on organ quality and transplant outcome.
Transplant Rev (Orlando), 26 (2012), pp. 54-59
[17]
BTS/ICS Consensus guidelines on Organ Donation after Circulatory death. Available from: www.bts.org/transplantation/standards-and-guidelines [accessed 30.08.12].
[18]
S.D. Semie, A.J. Baker, G. Knoll, W. Wall, G. Rocker, D. Howes, et al.
National recommendations for donation after cardiocirculatory death in Canada.
CMAJ, 175 (2006), pp. S1
[19]
L. Tariciotti, C. Rocha, T. Perera, B. Gunson, S. Bramhall, J. Isaac, et al.
Is it time to extend liver acceptance criteria for controlled donors after cardiac death?.
Transplantation, 92 (2011), pp. 1140-1146
[20]
B. Domínguez-Gil, B. Haase-Kromwijk, H. van Leiden, J. Neuberger, L. Coene, P. Morel, et al.
European Committee (Partial Agreement) on Organ Transplantation. Council of Europe (CD-P-TO). Current situation of donation after circulatory death in European countries.
Transpl Int, 24 (2011), pp. 676-686
[21]
M.L. de Oliveira, W. Jassem, R. Valente, S.E. Khorsandi, G. Santori, A. Prachalias, et al.
Biliary complications after liver transplantation using grafts from donors after cardiac death: results from a matched control study in a single large volume center.
Ann Surg, 254 (2011), pp. 716-723
[22]
A.R. Manara, P.G. Murphy, G. O’Callaghan.
Donation after circulatory death.
Br J Anesth, 108 (2012), pp. 108-121
[23]
A. Casavilla, C. Ramírez, R. Shapiro, D. Nghiem, K. Miracle, O. Bronster, et al.
Experience with liver and kidney allografts from non-heart-beating donors.
Transplantation, 59 (1995), pp. 197-203
[24]
M. Kato, K. Mizutani, R. Hattori, T. Kinukawa, K. Uchida, K. Hoshinaga, et al.
In situ renal cooling for kidney transplantation from non-heart-beating donors.
Transplant Proc, 32 (2000), pp. 1608-1610
[25]
M.T. Perera.
The super-rapid technique in Maastricht category III donors: has it developed enough for marginal liver grafts from donors after cardiac death?.
Curr Opin Organ Transplant, 17 (2012), pp. 131-136
[26]
J.F. Magliocca, J.C. Magee, S.A. Rowe, M.T. Gravel, R.H. Chenault 2nd, R.M. Merion, et al.
Extracorporeal support for organ donation after cardiac death effectively expands the donor pool.
J Trauma, 58 (2005), pp. 1095-1101
[27]
C. Fondevila, A.J. Hessheimer, A. Ruiz, D. Calatayud, J. Ferrer, R. Charco, et al.
Liver transplant using donors after unexpected cardiac death: novel preservation protocol and acceptance criteria.
Am J Transplant, 7 (2007), pp. 1849-1855
[28]
C.L. Jay, V. Lyuksemburg, R. Kang, L. Preczewski, K. Stroupe, J.L. Holl, et al.
The increased costs of donation after cardiac death liver transplantation: caveat emptor.
Ann Surg, 215 (2010), pp. 743-748
[29]
S. Yamamoto, H.E. Wilczek, F.F. Duraj, C.G. Groth, B.G. Ericzon.
Liver transplantation with grafts from controlled donors after cardiac death: a 20-year follow-up at a single center.
Am J Transplant, 10 (2010), pp. 602-611
[30]
H.P. Grewal, D.L. Willingham, J. Nguyen, W.R. Hewitt, B.C. Taner, D. Cornell, et al.
Liver transplantation using controlled donation after cardiac death donors: an analysis of a large single-center experience.
Liver Transpl, 15 (2009), pp. 1028-1035
[31]
D. Foley, L.A. Fernández, G. Leverson, M. Anderson, J. Mezrich, H.W. Solinger, et al.
Biliary complications after liver transplantation from donation after cardiac death donors: analysis of risk factors and long term outcomes from a single center.
Ann Surg, 253 (2011), pp. 817-825
[32]
O. Detry, V. Donckier, V. Lucidi, D. Ysebaert, T. Chapelle, J. Lerut, et al.
Liver transplantation from donation after cardiac death donors: initial Belgian experience 2003–2007.
Transpl Int, 23 (2010), pp. 611-618
[33]
J. Dubbeld, H. Hoekstra, W. Farid, J. Ringers, R.J. Porte, H.J. Metselaar, et al.
Similar liver transplantation survival with selected cardiac death donors and brain death donors.
Br J Surg, 97 (2010), pp. 744-753
[34]
P. Deltenre, D.C. Valla.
Ischemic cholangiopathy.
Semin Liver Dis, 28 (2008), pp. 235-246
[35]
B. Taner, I. Butalao, D. Willingham, D. Perry, L. Sibulesky, S. Pungpapong, et al.
Events in procurement as risk factors for ischemic cholangiopathy in liver transplantation using donation after cardiac death donors.
Liver Transpl, 18 (2012), pp. 101-112
[36]
M.E. de Vera, R. Lopez-Solis, I. Dvorchik, S. Campos, W. Morris, A.J. Demetris, et al.
Liver transplantation using donation after cardiac death donors: long-term follow-up from a single center.
Am J Transplant, 9 (2009), pp. 773-781
[37]
J.C. Hong, H. Yersiz, P. Kositamongkol, V.W. Xia, F.M. Kaldas, H. Petrowsky, et al.
Liver transplantation using organ donation after cardiac death: a clinical predictive index for graft failure-free survival.
Arch Surg, 146 (2011), pp. 1017-1023
[38]
E.Y. Chan, L.C. Olson, J.A. Kisthard, J.D. Perkins, R. Bakthavatsalam, J.B. Halldorson, et al.
Ischemic cholangiopathy following liver transplantation from donation after cardiac death donors.
Liver Transpl, 14 (2008), pp. 604-610
[39]
J.K. Pine, A. Aldouri, A.L. Young, M.H. Davies, M. Attia, G.J. Toogood, et al.
Liver transplantation following donation after cardiac death: an analysis using matched pairs.
Liver Transpl, 15 (2009), pp. 1072-1082
[40]
A.I. Skaro, C.L. Jay, T.B. Baker, E. Wang, S. Pasricha, V. Lyuksemburg, et al.
The impact of ischemic cholangiopathy in liver transplantation using donors after cardiac death: the untold story.
Surgery, 146 (2009), pp. 543-552
[41]
K.P. Croome, V. McAlister, P. Adams, P. Marotta, W. Wall, R. Hernandez-Alejandro.
Endoscopic management of biliary complications following liver transplantation after donation from cardiac death donors.
Can J Gastroenterol, 26 (2012), pp. 607-610
[42]
N. Meurisse, S. Vanden Bussche, I. Jochmans, J. Francois, B. Desschans, W. Laleman, et al.
Outcomes of liver transplantations using donations after circulatory death: a single-center experience.
Transplant Proc, 44 (2012), pp. 2868-2873
[43]
C.L. Jay, V. Lyuksemburg, D.P. Ladner, E. Wang, J.C. Caicedo, J.L. Holl, et al.
Ischemic cholangiopathy after controlled donation after cardiac death liver transplantation: a meta-analysis.
Ann Surg, 253 (2011), pp. 259-264
[44]
C. Moench, K. Moench, A.W. Lohse, J. Thies, G. Otto.
Prevention of ischemic-type biliary lesions by arterial back-table pressure perfusion.
Liver Transpl, 9 (2003), pp. 285-289
[45]
F.W. Selck, E.B. Grossman, L.E. Ratner, J.F. Renz.
Utilization, outcomes, and retransplantation of liver allografts from donation after cardiac death: implications for further expansion of the deceased-donor pool.
Ann Surg, 248 (2008), pp. 599-607
[46]
T.R. Harring, N.T. Nguyen, R.T. Cotton, J.J. Guiteau, I.A. Salas de Armas, H. Liu, et al.
Liver transplantation with donation after cardiac death donors: a comprehensive update.
J Surg Res, 178 (2012), pp. 502-511
[47]
A.K. Mathur, J. Heimbach, D.E. Steffick, C.J. Sonnenday, N.P. Goodrich, R.M. Merion.
Donation after cardiac death liver transplantation: predictors of outcome.
Am J Transplant, 10 (2010), pp. 2512-2519
[48]
C. Jay, D. Ladner, E. Wang, V. Lyuksemburg, R. Kang, Y. Chang.
A comprehensive risk assessment of mortality following donation after cardiac death liver transplant – an analysis of the national registry.
J Hepatol, 55 (2011), pp. 808-813
[49]
K.W. Lee, C.E. Simpkins, R.A. Montgomery, J.E. Locke, D.L. Segev, W.R. Maley.
Factors affecting graft survival after liver transplantation from donation after cardiac death donors.
Transplantation, 82 (2006), pp. 1683-1688
[50]
R.M. Merion, S.J. Pelletier, N. Goodrich, M.J. Englesbe, F.L. Delmonico.
Donation after cardiac death as a strategy to increase deceased donor liver availability.
[51]
R. Mateo, Y. Cho, G. Singh, M. Stapfer, J. Donovan, J. Kahn, et al.
Risk factors for graft survival after liver transplantation from donation after cardiac death donors: an analysis of OPTN/UNOS data.
Am J Transplant, 6 (2006), pp. 791-796
[52]
C.B. Taner, I.G. Bulatao, L.C. Arasi, D.K. Perry, D.L. Willingham, L. Sibulesky, et al.
Liver transplantation in the critically ill: donation after cardiac death compared to donation after brain death grafts.
Ann Hepatol, 11 (2012), pp. 679-685
[53]
R. Hernández-Alejandro, K.P. Croome, D. Quan, M. Mawardi, N. Chandok, C. Dale, et al.
Increased risk of severe recurrence of hepatitis C virus in liver transplant recipients of donation after cardiac death allografts.
Transplantation, 92 (2011), pp. 686-689
[54]
T. Uemura, V. Ramprasad, C.S. Hollenbeak, D. Bezinover, Z. Kadry.
Liver transplantation for hepatitis C from donation after cardiac death donors: an analysis of OPTN/UNOS data.
Am J Transpl, 12 (2012), pp. 984-991
[55]
R. Hernadez-Alejandro, W. Wall, A. Jevnikar, P. Luke, M. Sharpe, D. Russell, et al.
Organ donation after cardiac death: donor and recipient outcomes after the first three years of the Ontario experience.
Can J Anaesth, 58 (2011), pp. 599-605
[56]
S. Fujita, S. Mizuno, T. Fujikawa, A.I. Reed, R.D. Kim, R.J. Howard, et al.
Liver transplantation from donation after cardiac death: a single center experience.
Transplantation, 84 (2007), pp. 46-49
[57]
J.H. Nguyen, H. Bonatti, R.C. Dickson, W.R. Hewitt, H.P. Grewal, D.L. Willingham, et al.
Long-term outcomes of donation after cardiac death liver allografts from a single center.
Clin Transplant, 23 (2009), pp. 168-173
[58]
R.H. Broomhead, S. Patel, B. Fernando, J. O’Beirne, S. Mallett.
Resource implications of expanding the use of donation after circulatory determination of death in liver transplantation.
Liver Transpl, 18 (2012), pp. 771-778

Please cite this article as: Abradelo De Usera M, Jiménez Romero C, Loinaz Segurola C, Moreno González E. Trasplante hepático con injerto procedente de donación después de muerte cardiocirculatoria controlada. Situación actual. Cir Esp. 2013;91:554–562.

Copyright © 2012. AEC
Descargar PDF
Opciones de artículo
es en pt

¿Es usted profesional sanitario apto para prescribir o dispensar medicamentos?

Are you a health professional able to prescribe or dispense drugs?

Você é um profissional de saúde habilitado a prescrever ou dispensar medicamentos