When transplantation started all organs were retrieved from patients immediately after cardio-respiratory arrest, i.e. from non-heart-beating donors. After the recognition that death resulted from irreversible damage to the brainstem, organ retrieval rapidly switched to patients certified dead after brainstem testing. These heart-beating-donors have become the principal source of organs for transplantation for the last 30 years. The number of heart-beating-donors are declining and this is likely to continue, therefore cadaveric organs from non-heart-beating donor offers a large potential of resources for organ transplantation. The aim of this study is to examine clinical outcomes of non-heart-beating donors in the past 10 years in the UK as an way of decreasing pressure in the huge waiting list for organs transplantation.
The imbalance between supply of organs for transplantation and demand for them is widening all over the world. In the United Kingdom (UK) the figures are not different, by the end of December 2004 there were over 6000 people on the active waiting list for organ transplantation. Recent data suggest that over 400 of these people will die each year before a new organ becomes available.1
When transplantation started all organs were retrieved from patients immediately after cardio-respiratory arrest, i.e. from non-heart-beating donors (NHBDs). After the recognition that death resulted from irreversible damage to the brainstem by Harvard Medical Committee2 and the subsequent introduction in 19763 of direct brainstem testing to determine when death has occurred, organ retrieval rapidly switched to patients certified dead after brainstem testing. These heart-beating-donors (HBDs) have become the principal source of organs for transplantation for the last 30 years.
The number of HBDs are declining and this is likely to continue for two major reasons: fewer young people are dying as a result of severe injury or cathastrophic cerobrovascular events4, and improvements in diagnosis and management of severe brain injuries mean that fewer fulfil the brainstem testing criteria.
Although numbers of NHBDs are slowly increasing, they still accounted for only 85 of 750 (11.3%) UK cadaveric donors in 2004–2005.5
The fundamental problem with NHBDs is warm ischemia which may lead to suboptimal transplanted organ function. Developments in organ protection will only lead to more successful outcomes from NHBD if strategies can be divised to keep warm ischaemia times as short as possible.
The aim of this study is to examine clinical outcomes of NHBDs in the past 10 years in the UK as an way of decreasing pressure in the huge waiting list for organs transplantation.
A literature review was performed based on a Medline (Pubmed from 1997 to 2006) search to identify articles on clinical NHBDs in the UK.
Information on the rates of primary non-function (PNF), delayed graft function (DGF), acute rejection, graft and patient survival were registred. Also NHBDs technique, perfusion and recipient immunosupression were mentioned.
All centres have developed programmes based on the Maastricht protocol,6 which includes the following principles:
- 1.
approval by local medical ethics committee,
- 2.
diagnosis of death by doctors who are independent of the transplant team,
- 3.
the 10-min rule (after declaration of cardiac death, the body is left untouched for a period of 10 min prior intervention),
- 4.
rapid in situ cooling using a catheter inserted into the aorta, and organ retrieval using standard surgical techniques. Declaration of cardiac death implies irreversible cessation of heart function and the 10-min hands-off period ensures the process of irreversible brain death has begun.
We also recorded the criteria for exclusion of NHBDs, the Maastricht classification, the current criteria for both brain-stem death for HBDs and cardiac death for NHBDs, and finally ethics and legal issues involved in the NHBDs transplantation.
The first International Workshop in Maastricht7 defined four categories of NHBD:UNCONTROLLEDCategory I – includes victims of accident and suicide ( some centers exclude suicide victims from their programs ) who are found dead at the scene and resuscitation is deemed pointless (e.g. fatal cervical spine fracture). These are the worst group of potential donors because of the unknown primary warm ischemic time.
Category II – donors are mostly victims of sudden cardiac (the majority) or cerebral catastrophe who are brought to emergency departments while being resuscitated by ambulance personnel or who died in the department. Other sources include patients suffering isolated brain injury, anoxia and stroke, and victims of major trauma who died soon after hospital admission.
CONTROLLEDCategory III – encompasses patients who are dying, often on an intensive care unit. These are the patients awaiting cardiac arrest where the treating clinicians have decided to withdraw treatment and not commence resuscitation for various reasons.
Category IV – comprises patients who suffer unexpected cardiac arrest during or after determination of brain death.
Ethics and Legal IssuesThere is an increasing worldwilde discrepancy between the availability of, and need for organs allografts. It has been estimated that the number of donor organs could rise by 25% through the expanded use of NHBD 9 making it inevitable in an era of universal shortage of donors.
Non-Heart-Beating Donors - Maastricht classification7
| Description | ||
|---|---|---|
| I | Dead on arrival | Uncontrolled |
| II | Unsuccessful resuscitation | Uncontrolled |
| III | Awaiting cardiac arrest | Controlled |
| IV | Cardiac arrest while brain dead (death during procurement; death duringexplantation) | Controlled |
Criteria for exclusion of non-heart-beating donors8
|
Criteria for brainstem death apply to heart-beating donors8
|
#These tests are performed by two experienced clinicians on two separate occasions.
Criteria for cardiac death apply for non-heartbeating donors8
|
#Cardiac death in the context of potential organ donation is defined as occurring after 30 minutes of unsuccessful cardiopulmonary resuscitation under hospital conditions.
#Resuscitation must include external cardiac massage, intubation, ventilation, defibrillation (if indicate), and appropriate intravenous medication.
#Unsuccessful means that these measures did not achieve spontaneous contractile cardiac activity or peripheral circulation.
All transplant procurement strategies come with an ethical dimension but this particular process raises multiple concerns, not least of which is ambiguity as to the timing and definition of death.
The principal ethical issues concerning NHBDs programs are the use of in situ perfusion to consent the diagnosis of death by cardiac rather than brain-stem criteria, and at what time after pronouncement of death the in situ cooling should be started (dead donor rule).
English law does not require consent for prolonged ventilator support or placement of the double-balloon triple-lumen (DBTL) catheter, but catheter placement is an invasive procedure and the family members may not wish for this10.
The dead donor rule11 is pivotal to NHBD organ donation and states that the donor should not be killed by the act of donation (i.e. the donor must be dead by cardiac criteria at the time of retrieval). This became relevant when a decision is taken to discontinue life support measures in a patient who does not meet the criteria for brain-stem death and raises the question of when death should be pronounced after cardiac arrest 12.
There is a period when the patient is dead by cardiac criteria but not by brain-stem criteria13 and 10 minutes is considered sufficient for the discrepancy to be corrected. There has been considerable debate over the length of time that the patient should be left14. For ideal preservation the kidneys should be perfused as soon as the 10-minute waiting period is over.
These considerations were taken into account at the Maastricht workshop (1995). The conclusions of this discussions was that it was safer to apply the dead-donor rule only after a 10-minute period of asystole7,15. There can be little doubt that after normothermic ischaemia for this period, it would be impossible to restore myocardial function and there will be irreversible loss of all neurological function. Then, the criteria for cardiac and brain death will have been satisfied simultaneously.
Warm Ischaemia Renal InjuryThe period of warm ischaemia is usually defined as the time between cardiac arrest and the start of cardiopulmonary resuscitation.
This could more accurately be described as the absolute warm time because there may be other less obvious periods of warm ischaemia. The efficacy of external cardiac massage is achieving renal perfusion is not definitely known and will vary according to how well resuscitation is performed. It is likely that a degree of renal warm ischaemia is common during cardiopulmonary resuscitation and this could be described as relative warm time.
Conversely cardiac massage and ventilation which are effective in oxygenating the kidneys after a period of circulatory standstill, may also be deleterious by initiating the reperfusion injury syndrome.
Warm ischaemia is known to be a major determinant of renal function after kidney transplantation. However, the amount of reversible warm ischaemic injury that the human kidney can sustain is still not known for certain. Most human NHBD kidney transplant protocols exclude kidneys which such prolonged warm times, the usual cutoff being in the of 30 to 45 minutes16,17.
Renal allografts from controlled NHBDs sometimes function immediately suggesting that the human kidney tolerates short periods of warm ischaemia quite well18. In uncontrolled NHBDs the warm time is not always accurately known. It may need to be determined by taking a history from relatives, ambulance staff, and medical personnel and in some cases this will provide only an approximate estimate.
Surgical Technique1. Leicester Model for NHBD (In situ kidney perfusion/Cooling and kidney retrieval in NHBD)NHBDs kidneys were perfused and cooled in situ using a DBTL aortic catheter placed via femoral artery cut-down in the groin. The technique as described originally by Garcia-Rinaldi et al19, involves insertion of the DBTL catheter into the abdominal aorta via femoral arteriotomy. Inflation of the caudal balloon at the aorta bifurcation and inflation of the cranial balloon isolates the segment of aorta from which the renal arteries originate (vertebral level L1). A plain abdominal radiograph can be taken to show the position of the catheter, which is radio-opaque.
Wheatley et al20 modification is to mix a small amount of Conray (May and Baker, Dagenham, UK) radio-contrast dye with saline injected into the balloons to allow easier identification of the balloons on radiography. Using a mixture of Conray and saline in a ratio 1:10 rather than neat Conray makes injection of the viscous liquid much easier.
The balloons were inflated with radiographic contrast medium, and the positioning checked by plain abdominal x-ray20.
The system was vented by placing a Foley catheter into the inferior vena cava via the right femoral vein. Following in situ renal perfusion the NHBD was transferred to an operating theatre for bilateral donor nephrectomy.
The perfusion fluid used for NHBD was a 10 to 20 L Marshall’s hyperosmolar citrate solution at 4 C infused under gravity and all kidneys were held in static ice storage before transplantation.
2. Newcastle upon-Tyne Model for NHBD (NHBD retrieval ; pumping perfusion system)In situ organ perfusion was performed by cannulating the femoral artery using a DBTL cannula (TXF Medical, High Wycombe, UK). The preservative solution was cold (4–8 C) heparinized (1000 IU/L) Marshall’s solution. The venous venting was through placement of a cannula into the femoral vein. No radiological confirmation of placement was done. After retrieval the kidneys were cold stored and transported to the Hospital where machine perfusion and viability assessment were carried out21.
Pumping perfusion systemA Belco BL 760 blood pump module was used for perfusion. One pump in the system provided fluid to the renal artery and the other retrieved it through a heat exchanger. The temperature of the system was maintained between 4 and 9 C. The pump was capable of delivering a flow rate of 28–480ml/min and pressure were maintained at 45–60 mm Hg. Thus a closed system of perfusion was achieved.
A viable kidney tends to have a flow rate of more than 50 ml perfusate/minute per 100 g of kidney and a glutathione S-transferase level less than 200 IU/L per 100 g kidney22.
3. Cambridge Model for NHBDFollowing certification of death on the ward, the donor was transported to the operating theatre. Laparotomy was performed, a large bore (22F) aortic cannula inserted and the kidneys were perfused in situ with at least 3L of cold University of Wiscosin (UW) solution containing 20 000 units of heparin per litre.
The supra-coeliac aorta was cross-clamped to facilitate perfusion of the kidneys and the venous system was decompressed via inferior vena cava. To provided additional cooling, 2 L of crushed frozen saline were applied around the kidneys during perfusion. Donor nephrectomy was then performed23.
4. London Model for NHBDAn interval of 15 minutes after cardiac arrest was always allowed before cold in situ perfusion or crash retrieval was commenced. All donors were cooled using Soltran Kidney Perfusion Solution (Baxter Medical, Houston, TX, USA) with an additive of 20,000 IU of heparin via femoral access using a DBTL inserted into the femoral artery. Cannulas were placed only after consent of relatives was given.
The kidneys of the controlled donors were perfused via rapid aortic cannulation after laparotomy or crash retrieved with no flush and thereafter perfused with ice-cold solution on the bench 24.
Pulsatile kidney perfusion with the RM3 pump (Water Medical Systems, Rochester, MN, USA) for organ assessment and preservation of up to 12 hours was used.
RESULTSDuring ten-year period analysed, NHBDs were used mainly for kidney transplantation in four centres in the UK as summarized in (Table 5).
England non-heart-beating donors transplant details
| Author | Year | Centre | No. patients | Organ |
|---|---|---|---|---|
| Nicholson et al25 | 1997 | Leicester | 30 | Kidney |
| Butterworth et al26 | 1997 | Leicester | 37 | Kidney |
| Nicholson et al27 | 2000 | Leicester | 77 | Kidney |
| Balupuri et al 21 | 2000 | Newcastle upon-Tyne | 15 | Kidney |
| Balupuri et al 28 | 2001 | Newcastle upon-Tyne | 28 | Kidney |
| Metcalfe et al 29 | 2001 | Leicester | 72 | Kidney |
| Gok et al30 | 2002 | Newcastle upon-Tyne | 43 | Kidney |
| Gerstenkorn et al31 | 2002 | London | 202 | Kidney |
| Gok et al32 | 2002 | Newcastle upon-Tyne | 46 | Kidney |
| Sudhindran et al23 | 2003 | Cambridge | 42 | Kidney |
| Gok et al33 | 2003 | Newcastle upon-Tyne | 25 | Kidney |
| Brook et al34 | 2003 | Leicester | 55 | Kidney |
| Gerstenkorn et al35 | 2003 | London | 41 | Kidney |
| Gok et al36 | 2004 | Newcastle upon-Tyne | 72 | Kidney |
| Brook et al37 | 2004 | * | 285 | Kidney |
| Gok et al38 | 2004 | Newcastle upon-Tyne | 02 | Kidney |
| Wilson et al 39 | 2005 | Newcastle upon-Tyne and Leicester | 51 | Kidney |
| Bains et al40 | 2005 | Leicester | 37 | Kidney |
| Navarro et al 41 | 2006 | Newcastle upon-Tyne | 05 | Kidney |
| Gok et al42 | 2006 | Newcastle upon-Tyne | 19 | Kidney |
| Navarro et al 43 | 2006 | Newcastle upon-Tyne | 81 | Kidney |
| Sohrabi et al44 | 2006 | Newcastle upon-Tyne | 05 | Kidney |
| Sohrabi et al 45 | 2006 | Newcastle upon-Tyne | 36 | Kidney |
| Muiesan et al46 | 2006 | London | 07 | Liver |
NHBDs in the UK centres according to the Maastricht classification are shown in (Table 6).
Non-heart-beating donors in England centres according to the Maastricht classification.
| Centre | NHBD* not mentioned category (n=365) | NHBD Uncontrolled Category I e II (n=575) | NHBD Controlled Category III e IV (n=398) | NHBD Total (n=1334) |
|---|---|---|---|---|
| Cambridge | - | 0 | 42 | 42 |
| Leicester | 144 | 144 | 20 | 308 |
| London | 202 | 8 | 40 | 250 |
| Newcastle upon-Tyne | 19 | 178 | 201 | 398 |
| Cambridge, Leicester, London, Newcastle upon-Tyne | - | 217 | 68 | 285 |
| Leicester, Newcastle upon-Tyne | - | 24 | 27 | 51 |
Comparing NHBD with HBD the results of PNF, only 3 out of 24 articles have shown significant differences. As far as DGF is concern 8 out of 24 articles have shown significant differences. Acute rejection was reported significant in only 1 out of 24 articles (Table 7).
Comparation of the results of NHBD/HBD in England relating to primary non-function, delayed graft function and acute rejection.
| Author | NHBD/HBD | PNF(%)NHBD/HBD | DGF(%)NHBD/HBD | AR(%)NHBD/HBD |
|---|---|---|---|---|
| Nicholson et al25 | 30/114 | 3/13(s) | 25/87(s) | 48/27(s) |
| Butterworth et al26 | 37/91 | 11/1(s) | 100/28(s) | 27/36(ns) |
| Nicholson et al27 | 77/224 | 9.1/2.7(s) | 84.3/21(s) | 28.6/32.6(ns) |
| Balupuri et al21 | 15/nm | 6.6/- | 66.6/- | nm |
| Balupuri et al28 | 28/nm | 3.57/- | 91.6/- | nm |
| Metcalfe et al29 | 72/192 | 7/4(ns) | 80/19(s) | 24/31(ns) |
| Gok et al30 | 43/nm | - | - | - |
| Gerstenkorn et al31 | 202/nm | 21.8/- | 82.3/- | 13.1/- |
| Gok et al32 | 46/46 | 8.7/2.2 | 94.9/41(s) | 52.2/41.3(ns) |
| Sudhindran et al23 | 42/84 | 0/2 | 50/17(s) | 33.3/40.5(ns) |
| Gok et al33 | 25/nm | 2/nm | 75/nm | - |
| Brook et al 34 | 55/69 | 5/3 | 93/17 | 24/23(ns) |
| Gerstenkorn et al35 | 41/0 | 14.6 | 80 | - |
| Gok et al36 | 72/nm | 7.85/- | 75.6/- | 41.4/- |
| Brook et al37 | 285/0 | 15 | 79.7 | 41 |
| Gok et al38 | 2/0 | 0/0 | 100/0 | 100/0 |
| Wilson et al39 | 51/nm | 2/nm | 7/nm | - |
| Bains et al40 | 37/75 | 0/0 | 31/8(s) | 7/27(ns) |
| Navarro et al41 | 81/- | nm | nm | nm |
| Gok et al42 | 19/15 | nm | 57.9/45.5(s) | 36.8/20(s) |
| Navarro et al43 | 5/- | nm | nm | nm |
| Sohrabi et al44 | 5/- | 0/- | 80/- | nm |
| Sohrabi et al45 | 36/- | 6.3/- | nm | 35/- |
| Muiesan et al46 | 07/0 | 0 | 0 | 3 |
s-significant; ns- not statistically significant; nm- not mentioned; nhbd-non-heart-beating donor;hbd-heart-beating donor; pnf-primary non-function;dgf-delayed graft function;ar-acute rejection.
Graft survival was equal for 1, 2,3 and 5 years when comparing NHBD with HDB except in 1 article that has shown significant differences in 3 and 5 years time, (Table 8).
Graft survival in NHBD in England.
| 1 y(%) | 2 y(%) | 3 y(%) | 5 y(%) | ||
|---|---|---|---|---|---|
| Nicholson et al25 | NHBD | 78 | 75 | 73 | - |
| HBD | 90 | 85 | 82 | ||
| Butterworth et al26 | NHBD | 73 | 73 | 73 | - |
| HBD | 83** | 79** | 77** | ||
| Nicholson et al27 | NHBD | 85** | 87** | 87** | 79** |
| HBD | 85 | 82 | 80 | 75 | |
| Balupuri et al21 | NHBD | 91.7 | - | - | - |
| Balupuri et al28 | NHBD | 88.1 | - | - | - |
| Metcalfe et al29 | NHBD | 81 | - | 77 | 73 |
| HBD | 86** | 78** | 65** | ||
| Gok et al30 | NHBD | 89.6 | - | - | - |
| HBD | 91.4** | ||||
| Gerstenkorn et al31 | NHBD | 86.9 | - | 75.5 | 65.5 |
| Gerstenkorn et al35 | NHBD | - | - | 82.9 | - |
| Brook et al34 | NHBD | 79 | - | 75 | 69 |
| Gok et al 32 | NHBD | 89.6 | - | 89.6 | - |
| HBD | 91.4** | 91.4** | |||
| Sudhindran et al23 | NHBD | 84 | - | 80 | 74 |
| HBD | 89** | 85** | 80** | ||
| Brook et al37 | NHBD | 88 | - | 84 | 84 |
| HBD | 82** | 73* | 62* | ||
| Gok et al 36 | NHBD | 92.1 | - | - | - |
| Sohrabi et al45 | NHBD | - | - | 95 | - |
| Muiesan et al46 | NHBD | 84 | - | - | - |
Patient survival was equal in 1, 3 and 5-years when comparing NHBD with HBD as shown in (Table 9).
Patient survival in NHBD in England.
| 1 y(%) | 3 y (%) | 5 y(%) | ||
|---|---|---|---|---|
| Gok et al30 | NHBD | 87.9 | 87.9 | - |
| HBD | 89.7 | 89.7 | ||
| Gerstenkorn et al31 | NHBD | 93.1 | 85.3 | 76.2 |
| Sudhindran et al23 | NHBD | 91 | 91 | 84 |
| HBD | 94 | 92 | 90 | |
| Gok et al36 | NHBD | 92.1 | - | - |
| Muiesan et al46 | NHBD | 87 | - | - |
nhbd-non-heart-beating donor;hbd-heart-beating donor;y-year.
United Kingdom centres and variations of NHBDs technique, use of double-ballon triple-lumen, machine perfusion, type of organ perfusion solution as well as immunossupression are demonstrated in (Table 10).
England centres and variations of non-heart-beating donors programmes.
| Centre | NHBD technique | In situ Perfusion | Immunossupression |
|---|---|---|---|
| Cambridge | Laparotomy + aortic cannula | UW | CSA/AZA/PRED |
| Leiscester | Femoral arteriotomy + DBTL catheter | Marshall’s | CSA/AZA/PRED or TAC/MMF/PRED |
| London | Kidney-femoral arteriotomy +DBTL | Marshall’s | CSA/AZA/PRED |
| Liver- PV cannulation | UW | TAC/PRED | |
| Newcastle upon-Tyne | Femoral arteriotomy + DBTL catheter + MP system | Marshall’s | Ab induction; TAC/MMF/PRED |
UW-University of Wisconsin; DBTL – double-balloon triple-lumen; SKPS-Soltran kidney perfusion solution; PV- portal vein; MP – machine perfusion;CSA-cyclosporine(7mg/Kg/d); TAC-tacrolimus (0.1mg/kg/d); AZA-azathioprine(1mg/kg/d);PRED – prednisolone(20mg/d reducing to 5 mg/d at 6 months); MMF – mycophenolate mofetil (2g b.i.d.); Ab – interleukin-2 receptor antibody.
Cadaveric organs from NHBD have been used for decades. Since the introduction of “brain-stem death” criteria in 1968, NHBDs have been largely abandoned in favor of brain-dead donors47 NHBD offers a large potential of resources for renal transplantation. The process of graft selection involves a significant number of potential grafts being discarded because they are judged to be nonviable. The reported discard rate of kidneys from NHBD is significant, with estimates ranging from 50 to 65% with uncontrolled donors48.
NHBD programs remain unpopular despite the potential to increase the donor pool by up to 30%49. A number of legal, ethical and logistic reasons as well as medical concerns are responsible for this and have even compromised existing NHBD programs50.
Legal and ethical issues such as cannulation of the femoral vessels for in situ cooling prior to consent by the relatives and an undefined interval of no-touch between cardiac arrest, declaration of death and organ resuscitation/preservation efforts remain an unsolved problem in the United Kingdom. If relatives were present the consent rate for organ donation after cardiac arrest was more than 70%.
In addition, the logistic requirements for a successful, financially efficient NHBD program are immense and require good planning, management and organization. Transplant surgeons and coordinators must be within close reach of potential donor locations in emergency departments, intensive care units, hospital wards, and hospices. Furthermore a sufficient number of trained staff members are required to share a rota for ininterrupted on-call cover. This might be possible only for a large transplant units or particularly dedicated centers. Organ preservation by perfusion is an additional issue that requires further expertise and is expensive21,51 but it might be the only reliable technique for assessing the viability of NHBD kidneys and marginal donors organs52
The 125 NHBD transplants performed in 2005–2006 (82 kidneys only; 36 kidney/liver; 1 kidney, thoracic & liver, 2 kidney, liver & pancreas and 4 liver only) rose 44% comparing with 87 NHBD in 2004–2005 but still represent a small proportion of the total transplant activity on the UK53.
The average NHBD retrieval rate for 2001 was 1.3 million population (pmp) for the four centres reported here. This compares with an average national rate for HBD kidneys of 23.5 pmp (United Kingdom Transplant Data54. Although the number of NHBD transplants is small the potential is greater; the most encouraging figures come from Daemen et al (55) who report 40% of their kidneys were accounted for by NHBDs.
Varty et al49 reported 38% of donors were NHBD in 1991 and later Nicholson56 reported that NHBD accounted for 21% of transplant activity. Light et al57 stated that the number of NHBD transplant opportunities equals that of HBD whilst other authors have suggested that there are twice as many potential NHBD as there are HBD 58. It has been suggested that if all potential NHBD kidneys were retrieved waiting lists for kidney transplantation could be eliminated59.
Two methods of harvesting of NHBDs have been advocated to decrease ischemic insult: 1. procurement methods include in situ intravascular cooling (universal), intra-peritoneal lavage and cooling (used in the United States), hypothermic and normothermic partial cardiopulmonary bypass (used in Spain) and hypothermic extracorporeal membrane oxygenation (used in Taiwan); and 2. machine preservation methods include: pulsatile intermittent perfusion and continuous-and-constant perfusion.
Ischemic injury is almost inevitable in NHBD renal grafts and primarily results from prolonged hypotension, cardiac arrest and warm ischemia during the primary warm ischaemia time (WIT). Development of allograft dysfunction can result in DGF and PNF.
As far as the NHBD for liver transplantation is concern Muiesan et al46 based their donor selection on several factors including age less than 40 years, short intensive care unit stay, normal liver function tests, short interval from withdraw of therapy to cardiac arrest, short WIT and good appearance and perfusion of the liver, as judged by an experienced transplant surgeon. When the majority of these parameters were satisfied they provided organs suitable for bench segmental reduction.
They started the procedure of reduction/spltting as soon as the recovery team had returned to their centre. Care was taken to keep the temperature of the University of Wisconsin (UW) solution at 4 C and to avoid re-warming of the graft. One split procedure was performed. The left lateral segment was transplanted with 7 h of cold ischemia and provided excellent immediate function with an International Normalized Ratio of 1.2 on the second post-operative day. The adult recipient who received the right lobe split was transplanted sequentially with a cold ischemia time of 14.3 h and experienced PNF. He died of multi-organ failure after emergency re-transplantation. Subsequent reduction of NHBD grafts was performed with transplantation only of the left lateral segment or left lobe in children46.
The recent largest retrospective study comparing outcomes of adults recipients of NHBD and HBD hepatic allografts between 1993 and 2001 based on the United Network of Organ Sharing database confirmed their greater vulnerability to cold ischemia and the higher incidence of PNF among a group of 144 NHBD livers60.
Abt et al61 have emphasized the importance of short cold ischemic time for liver grafts. When the cold ischemic time was less than 8 h there was 10.8% of graft failure within 60 days of transplantation which increased to 30.4% and 58.3% when the cold ischemia time was greater than 8 and 12 h, respectively. The combination of warm and cold ischemia in NHBDs appears to make these grafts more susceptible to biliary complications. A higher incidence of ischemic cholangiopathy has been reported61,62.
D’Alessandro et al63 also recognized increased incidence of ischaemic biliary complications in NHBD liver graft recipients from donors older than 40 years of age.
To date there have been no vascular complications and no evidence of major biliary complications with particular reference to ischaemic cholangiopathy in these children after a mean follow-up of 19 months46.
Reddy et al64 described various cytoprotective strategies involving administration of drugs before cardiac arrest that have been successfully used in NHBD liver transplantation.
Kidneys from different Maastricht categories recovered at different rates although they were all similar at 3 months. Kidneys from NHBDs have undergone more ischemic insult than kidneys from HBDs.This occurs because of the prolonged early (primary) warm ischemia.
For Maastricht category II donors this the period between collapse and effective resuscitation, variably effective resuscitation and the “no-touch” period before perfusion.
For category III donors after withdrawal of support there can be an agonal period of hypotension followed by the “ no-touch” period and then perfusion.
Category IV donors are known to be brainstem dead and are the closest to HBDs. They often arrest in theatre, therefore the primary ischemic time does not include the “no-touch” period. Thus the primary warm ischemic insult is likely to be maximal for category II and minimal for IV with III in-between (II greater than III greater than IV)36.
With maximal primary warm ischemic damage comes the increasing chance of in situ thrombosis, greater oxygen debt, and increasing acidosis and reduction of cellular adenosine triphosphate. Viability testing excludes those organs that are so badly damaged they are not likely to function. As a consequence the prolonged warm ischemia and reperfusion syndrome is likely to be more severe for kidneys from category II donors as opposed to III or IV.
A contrary argument has been put forward that a person who is hospitalized and in an intensive therapy unit for a protracted period is more likely to have inotropic support and sepsis which may result in unmeasured hypoperfusion of kidneys. Therefore, kidneys from a sudden collapse (category II) are possibly healthier than those from a hospitalized patient8.
Gok et al36 demonstrated that the PNF rate is slightly higher for category II donors (13.5%) than category III (2.2%) and category IV (0%, p<0.05). In addition DGF incidence is greatest for category II donors (83.8%), less for category III (67.4%) and best for category IV (0%).
The introduction of pulsatile hypothermic machine-perfusion of NHBD kidneys, along with viability testing has resulted in a viable grafts acceptable survival rates with DGF in recipients. The main advantages of machine perfusion are the provision of metabolic support via replenishment of ATP by high energy yielding phosphate bonds from the perfusate (UW solution). Apart from the mechanical flush provided by continuos perfusion, the natural ischemia-induced capillary vasoconstriction is reversed as demonstrated by the reduction of intra-renal vascular resistance. This in turn is reflected in lower incidence of delayed graft function. Machine perfusion also allows monitoring and assessment of viability in an NHBD kidney graft.
Opelz and Terasaki concluded no added advantage of machine perfusion in HBD65. Machine perfusion fell into disrepute due to its complex logistics needs66,67,68. It was also reported in some cases that machine-perfusion was damaging to the graft69.
Renewed interest in this method of preservation came about through the use of marginal organs and improved preservative solutions (UW). With the improved solutions, the incidence of DGF could be reduced using kidneys from HBDs or those with prolonged cold ischaemia70,71.
Increased demand for viable organs has led to a recent upsurge in retrieval from the NHBDs. The difficulty experienced here was the viability of such kidneys. As the primary warm ischaemia times are prolonged with such donors, viability assessment and organ modulation have been done by machine perfusing the NHBD kidneys before transplantation 72,73,74,75.
The measurement of intra-renal vascular resistance and alpha GST is practiced by the Maastricht group, who have increased their donor pool by 20% 76. Most of the studies have demonstrated a beneficial effect of pulsatile perfusion in NHBD kidneys77,78. Machine perfusion has been shown to improve the graft function in cases of marginal kidneys as well as those with prolonged cold ischaemic times78.
In the setting of NHBD kidney transplantation, PNF represents the transplant of an organ irreparably damaged by warm ischemia. WIT correlates well with graft damage and there is a point at which organs become non-viable. There is no strict maximum WIT in NHBDs beyond which transplantation is contraindicated. Limits of 30 min79, 35 min 25 and 45 min80 have been advocated. Functional recovery in animal models has been achieved after substantially longer periods of 120 min79 and 140 min81.
Renal transplants with prolonged WIT, that is primary warm ischemia, demonstrated a relative increase in free radical generation during NHBD renal transplantation. Use of traditional tissue injury markers LDH, AST and lactate and the specific markers of tissue injury Ala-AP and FABP during kidney transplantation complemented the finding of free radical injury in NHBD renal transplants. Combined markers enabled the monitoring of different types of cell injury. This correlates with the high incidence of acute tubular necrosis and subsequent DGF in NHBD renal transplants.
Reperfusion injury is such that antioxidant strategies may be of benefit. Potential measures that could be used are nitric oxide addition82 and free radical scavengers (eg allopurinol, superoxide dismutase, catalase and dimethyl sulfoxide) with antioxidant supplementation ( eg gluthatione, vitamin E and gingko biloba)83,84, cytokine-chemokine suppressors, adhesion molecule blockers85,86 and neutrophil-endothelial cell blockade87,88.
The role of free radicals in the pathophysiology of ischaemia-reperfusion injury in transplantation is increasingly recognized. Free radical formation appears to occur in 2 phases, characterized as reperfusion mediated injury (early and short-lived, that is seconds to minutes) and neutrophil mediated injury (late and long-lived, that is minutes to an hour). In reperfusion mediated injury adenosine triphosphate depletion during hypoxia results in the accumulation of hypoxanthine which is coverted to free radicals ( superoxide and hydrogen peroxide radicals) upon reperfusion by xanthine oxidase activation89. In neutrophil mediated injury reperfusion results in the activation of neutrophil NADPH oxidase and the release of further free radicals (superoxide, hydrogen peroxide and hydroxyl radicals)90.
In kidney allograft free radicals can be formed throughout the renal parenchyma in the intracellular, intravascular and injury compartments. Ischaemia-reperfusion injury consist of 2 injury mechanisms namely ischemia characterized as oncotic necrosis and reperfusion injury. In the clinical setting this damage may delay the recovery of renal function prolong or complicate postoperative recovery or precipitate immunological reactions involved in the subsequent rejection reaction42.
In practice allowable maximum WIT varies in a qualitative manner i.e. a young and previously fit donor may be allowed a longer WIT than an older donor. The PNF average rate in the current study was 6.17% which is consistent with the 8 – 15 % reported previously from NHBDs55,91. This is higher than 2–5% quoted for HBD kidneys26,92. Shiroki et al93 claimed that PNF rate is highest in those NHBD kidneys with warm time of > 30 min. Tanabe et al94 disagreed stating that warm time bore no relationship to PNF rate but no WIT was > 30 min in their study. Brook et al 5 showed no episode of PNF in controlled donors with a 20% PNF rate in uncontrolled NHBD kidneys, indicating an association of warm time with PNF.
The reported incidence of PNF after transplantation using kidney from NHB donors varies from 4 to 40%, although most studies do not make distinction between kidneys from controlled and non-controlled NHB donors when describing the incidence of PNF22,27,58,75,91,94–99. The PNF is probably a consequence of ischaemic cortical necrosis5
The perceived risk of PNF and poor graft outcome has limited the adoption of NHB donor programmes to a relatively small number of transplant centres. Some of these have used machine perfusion preservation to try and reduce the risk of PNF, although direct evidence as to its effectiveness is lacking48.
In Newcastle upon-Tyne the introduction of machine perfusion coincided with a fall in the incidence of PNF from 54 to 7%21,22. This most probably reflects the ability to perform viability testing and in Newcastle and other centres, kidneys are discarded if during machine perfusion intra-renal resistance measurements or levels of S-transferase are abnormal21,22,74.
DGF occurs more frequently in NHBD (50–100%)92,94 than in HBD (20–60%) kidneys57,91,100. This increased DGF rate in NHBD kidney is likely to be a consequence of acute tubular necrosis (ATN) secondary to warm ischaemic damage. Not all DGF is due to ATN, although ATN is the most common cause and it is not therefore surprising that NHBD kidneys have a higher incidence of ATN than those from HBD101.
Brook et al37 showed in controlled donors 48% of DGF in both NHBD and HBDs whilst the uncontrolled donors had a significantly higher rate ((88%). It is important to note that warm time is not the only variable that influences DGF; duration of pre-transplant dialysis and recipient body weight also correlate with post-transplant early graft function 102.
The influence of DGF o kidney allograft survival is controversial. A number of studies have demonstrated poorer survival in HBDs with DGF 103,104,105 compared with HBDs with immediate function, while others authors have reported no such effect, independent of acute rejection106,107.
Brook et al37 demonstrate that serum creatinine is stable in recipients of kidneys from NHBDs from 3 months to 7 yr post-transplant. There is disagreement in the literature over NHBD post-transplant renal function. In some studies NHBD kidneys achieved early serum creatinine levels in the normal range26,49,58,108,109 whist others studies reported poor graft function than HBD in both the short and medium term73,91.
NHBDSs kidneys in the medium term achieve a good level of renal function with a mean serum creatinine at 12 months of 174 umol/L 76 and a median of 199 umol/L at 18 months49. So far, there is no evidence of accelerated deterioration of NHBDs kidneys because of a reduced functioning glomerular mass due to initial ischaemic damage.
Acute rejection is thought to occur more frequently and with greater severety in kidneys with prolonged ischaemia and DGF110. This may be a result of the increased rate of detection of sub-clinical rejection because biopsies are taken more frequently in the presence of DGF111.
Brook et al34, demonstrated for the first time that the high rate of DGF associated with renal transplantation from NHBDs does not lead to poor graft survival when compared with HBDs with DGF.
In recent years there has been a re-evaluation of the use of NHBDs for renal transplantation. While some studies have shown poorer graft survival for NHBD kidneys103,105, others have demonstrated favourable graft survival compared with HBDs25,91,112,113. This is despite the detrimental effects of warm ischaemic damage in NHBDs with consequent high rates of DGF.
Brook et al37 reported that despite the detrimental effects of long WIT in NHBD with consequent high rates of PNF and DGF, there have been favourable comparisons with HBD in terms of graft survival also demonstrating that NHBD kidneys display parity with HBD meeting the British Transplant Society guidelines114 for HBD allograft survival at 1 and 5 yr of 80 and 60% respectively.
It would seen that long ischaemic time causes reversible graft problems at an early stage in terms of PNF and DGF. Later NHBD grafts appear to perform at least as well as those from HBDs.
Finally, as previously published there are many ways to make transplantation demand compatible with organ supply 115,116,117,118,119,120. We have always to bear in mind that the gap between demand and supply of organs for transplantation continues to grow. One solution to this problem has been to return to the practice of using grafts from NHBDs. The challenge of NHBD transplantation is to minimize the first period of warm ischaemia and the consequent reperfusion injury.
CONCLUSIONNHBDs kidney transplants are associated with allograft dysfunction as PNF and DGF which is related to primary warm ischaemic injury. This warm ischaemia is more deleterious in uncontrolled than controlled NHBDs.
Kidney transplant from NHBDs can be performed successfully. The significant degree of warm ischemic injury suffered by NHBD kidneys leads to a high incidence of DGF but the data available so far suggest that this does not adversely influence long-term graft survival.