Abstract
Heart transplantation remains the gold standard treatment for patients with end-stage heart failure. In the USA, the number of available donors has remained stable despite the steadily increasing need for organs. Optimal donor selection and management are critical to deriving the greatest benefit from this limited resource. Methods to expand the donor pool without compromising long-term outcomes for heart recipients are needed.
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Introduction
The recent advancements in surgical technique, immunosuppressive therapy, and myocardial protection have established cardiac transplantation as the ultimate treatment strategy for end-stage heart failure. The dramatic increase in the number of procedures performed during the late 1980s and early 1990s, despite persistent mismatch in the donor/recipient numbers, has been attributed to donor pool expansion to include older donors and donors from remote areas, resulting in longer ischemic times [1]. Despite these factors and the increasing age of recipients, cardiac transplantation is nowadays performed with relatively low morbidity and mortality; according to UNOS database, the 1-year survival at high-volume centers approaches 95 % [2]. Still, there remains a donor shortage and there is resurgence in interest in methods to increase access. Optimal donor selection and management are essential in improving conversion of organs and providing the recipient the best opportunity of a good outcome. Frequently, practice has been dictated by prior experience and prevailing myths regarding what constitutes an optimal donor. Herein, we review the available data for optimal donor selection and management.
Donor Assessment and Evaluation
General
In general, deceased cardiac donors are declared dead by neurologic criteria (DNC), previously termed brain dead. Once potential heart donors are identified and the donor has been declared brain dead, thorough assessment of donor characteristics and comorbidities as well as heart function must be performed in a timely manner. Evaluation of cardiac function includes serum cardiac enzyme markers (creatinine phosphokinase-MB fraction and troponin), 12-lead electrocardiogram, echocardiogram, and coronary angiogram when indicated [3]. Although serum troponin levels are commonly measured, the association with recipient outcomes has remained unclear. Troponin is commonly used as a marker to evaluate for graft dysfunction, but mildly elevated levels should not limit donor acceptability when found in conjunction with normal graft function and normal coronary anatomy [4]. A complete transthoracic echocardiogram should be performed for evaluation of graft function. Important parameters include global ventricular function, wall motion, left ventricular wall thickness, valvular disease, and septal defects [5]. Left ventricular wall thickness greater than 1.4 cm has been shown to be associated with increased recipient death [6]. Coronary angiogram is typically recommended in male donors >40 years old and in female donors >45 years old. Pre-existing coronary artery disease may be associated with a higher incidence of progression and development of angiographic allograft coronary artery disease after transplantation, although this does not appear to affect survival [7, 8].
Donor Age
Acceptable donor age is becoming an increasingly debated topic. Early in the transplant experience, the upper age limit of donor age was 35 years. According to the International Society Heart and Lung Transplantation (ISHLT) Registry, the mean age of heart donors rose from 23 years in 1985 to 35 years from 2006 to 2013 [9]. In general, it is widely accepted that increased donor age is associated with poor recipient outcome. According to Del Rizzo and colleagues, donor age above 50 and ischemic time over 4 h are associated with increased 1- and 2-year mortality. The effect of increasing donor age is quite dramatic at 1- and 2-year marks, reducing the survival to 50.0 % among those who have received an organ from a donor older than 50 years. Additionally, if the ischemic time was beyond 240 min, the 1-year actuarial survival fell to 16.7 % [10]. A more recent analysis of the UNOS registry, examining the interaction of donor age with ischemic time, and their effect on survival, confirms these early findings. Specifically, among the two older age groups (20–33 and >33 years), a statistically significant difference was observed between ischemic time and mortality, suggesting greater tolerance for prolonged ischemic times among younger donors. Increased number and duration of comorbidities are often seen in older donors. Furthermore, changes in coronary endothelial function occur as early as age 35, suggesting a theoretical risk of graft dysfunction after this age. Nevertheless, there is a growing experience with older donors, particularly in Europe. Use of heart donors 50 years and older appears to be safe but associated with higher incidence of cardiac allograft vasculopathy [11, 12]. Transplant of older donor hearts into older recipients is associated with increased risk of mortality at 5 years as well [13]; however, the risk associated with no transplant was greater than that associated with transplant with an older donor [14]. Thus, in evaluating the risk of accepting an older donor, factors such as ischemic time and the risk of the recipient must be taken into account.
Donor Sex
Donor-recipient sex mismatch has been associated with poor outcomes. Prendergast and colleagues demonstrated that sex mismatch was associated with a higher number of rejection episodes and reduced survival in the first year after transplantation [15]. There have been several studies that have identified female donor sex as an independent predictor of mortality [16–20]. On closer evaluation, it appears that the greatest negative impact on survival is for male recipients of female donors [15, 21] and men who received organs from male donors have the highest cumulative survival at 5 years [22]. Khush and colleagues found that female donor to male recipient transplant was associated with a 10 % increased risk of mortality and reduced graft survival compared to male donor to male recipient; however, in this analysis of ISHLT Registry data, female donor to female recipient conferred a 10 % survival advantage [22]. There was no significant difference in acute rejection or cardiac allograft vasculopathy when sex-matched and sex-mismatched orthotopic heart transplantation (OHT) recipients were compared. In a single-center study, donor gender had no effect on survival in women or men <45 years old; however, female donors conferred a higher risk of mortality in men ≥45 years old [21]. The mechanism underlying disparate outcomes with gender mismatch is unclear and may be related to cardiac size mismatch despite matched weight [23]. Evidence to support non-use of a donor heart for gender mismatch is less than compelling, and therefore, sex mismatch should not be perceived as a strong indication for decline.
Donor Size
Weight within 20–30 % or a donor-to-recipient weight ratio of 0.8–1.2 is generally considered acceptable for matching. In the 2007 International Society of Heart and Lung Transplantation annual report, Taylor and colleagues found that decreasing donor-to-recipient body mass index ratio was a significant predictor for 5-year mortality [24]. Patel and colleagues evaluated the United Network for Organ Sharing/Organ Procurement and Transplantation Network Registry from 1999 to 2007 and found that the 30-day mortality was highest for those with a weight ratio <0.8 but this finding was not statistically significant. They also evaluated recipients with a pulmonary vascular resistance >4 Woods units and showed a trend towards decreased survival in recipients with low weight ratio [25]. However, there is growing evidence that donor weight may not be the best discriminator of risk after transplant. Reed and colleagues demonstrated that when using weight-based matching, there did not appear to be a difference in survival between underweight, overweight, and best-matched donors. However, when predicted left ventricular (LV) mass was used, a mismatch >10–15 % below the recipient predicted LV mass was associated with reduced survival [23].
Some centers have advocated for using oversized hearts to manage elevated pulmonary arterial pressures in the recipients [26]. More recent studies have not shown similar short-term and long-term mortality from both undersized and oversized donors in recipients with mild to moderate pulmonary arterial hypertension [27].
Ischemia Time
In general, a cold ischemic time <240 min is considered optimal, although the impact of increased ischemic times on outcomes has been unclear [28]. When the impact of donor age on ischemic time was evaluated, there was no association between prolonged ischemic time and survival for donors <20 years old. On the contrary, survival was decreased in the 20–33-year-old and in the ≥34-year-old terciles with prolonged ischemic times of 3.5–6.24 and 3.5–5.49 h, respectively, and with extended ischemic times of ≥6.25 and ≥5.5 h, respectively [2]. Based on these data, ischemic times appear to have the greatest impact among older donors.
Reasons for Non-use of Hearts
Decreased donor availability remains a difficult reality for patients requiring heart transplantation. In order to increase the donor pool, there has been significant research to help risk stratify potential donors that may have been discarded in the past. Cardiac allograft use decreased from 56 % in 2002 to 37 % use in 2007 [29]. Risk factors for non-use of donor organs include donor age ≥45–50 years, female sex, cerebrovascular accident (CVA), hypertension, diabetes mellitus, history of cocaine or methamphetamine use, high-inotrope requirement, elevated troponin I, left ventricular ejection fraction <50 %, cardiac arrest, hypernatremia, coronary artery disease, left ventricular regional wall motion abnormalities, and left ventricular hypertrophy (septal or posterior wall thickness >1.1 cm) [29, 30]. Requirement for vasoactive therapy, positive donor cytomegalovirus, longer graft ischemic time, and lower donor body weight are additional reasons for declining organs [19]. Although these are common reasons that donor hearts are declined, they do not necessarily constitute risk factors for outcomes. Although Smits and colleagues found 12 risk factors for non-use, only ventricular hypertrophy ≥13 mm and age constituted risk factors for 3-year mortality [30]. To better understand reasons for declined organs, Khush and colleges evaluated 1872 potential organ donors in the California Transplant Donor Network (CTDN). Of the total number of potential organ donors, 808 (43 %) of the donors were accepted for heart transplantation. Donors that were not accepted for transplant were more likely to be older, were female, and had CVA/stroke as a cause of death. These donors also had a higher incidence of smoking, hypertension, diabetes mellitus, coronary artery disease, as well as a positive troponin assay. Using a multivariable model, the most important predictors for allograft use were donor age, cause of death, left ventricular ejection fraction, and history of hypertension. There was no significant difference in the overall survival for recipients of allografts with these risk factors at 1 year after transplant. Diabetes mellitus was the only donor predictor of increased recipient mortality [29].
Preventing Transmission of Infections
Donors are routinely screened for the presence and risk of infection. Donor screening for infection includes a medical and social history, serologic testing, blood and urine cultures, and chest X-ray (Table 1). The Organ Procurement and Transplantation Network (OPTN) policy requires donor screening for HIV, hepatitis B, hepatitis C, syphilis, cytomegalovirus, and Epstein-Barr virus. In the past, HTLV-1/2 testing was required but has been eliminated. The transmission of HIV, HBV, and HCV remains a concern despite the low risk. Donors may be deemed high risk for transmitting infectious disease based on epidemiology, behavior, and exposure [2]. Informed consent must be obtained and documented if a recipient accepts a donor at high risk of transmissible disease.
Donor Risk Scores
Donor risk scores are used as a tool to assess both donor organ acceptance as well as short-term mortality. Using the Eurotransplant Registry, Smits and colleagues created a heart transplant donor score using over 20 donor risk factors. Using a multivariate logistic regression model, they were able to assess the effects of donor factors on the discard rate. The heart donor score was significantly associated with acceptance of the donor organ as well as 3-year survival [30]. Weiss and colleagues developed a quantitative donor risk index using a 15-point scoring system that used four variables: ischemic time, donor age, race mismatching, and blood urea nitrogen/creatinine ratio. Using this scoring system, each 1-point increase was associated with a 9–13 % increase risk of 1-year death [31]. Other risk prediction models such as IMPACT have more focus on recipient risk factors to develop a risk score. The 50-point scoring system was associated with increased odds of 1-year mortality [32] as well as 30-day and 5-year mortality on a follow-up validation study [33].
Primary graft failure (PGF) remains one of the most common reasons for death within 30 days after orthotopic heart transplantation (OHT) [34]. Segovia and colleagues retrospectively reviewed a series of 621 heart transplants done at a single-center hospital in years between 1984 and 2006. PGF occurred in 56 out of 621 heart transplants. Using a multivariate analysis, six independent predictors were identified: Right atrial pressure ≥10 mmHg, recipient Age ≥60 years, Diabetes mellitus, Inotrope dependence, donor Age ≥30 years, and Length of ischemic time ≥240 min. Based on these results, a risk calculator, RADIAL, was developed. One point is assigned per risk for a total of 6. Increasing RADIAL score was associated with significantly increased risk of PGF; a score of 4–6 was associated with >5-fold increase in risk of PGF (OR = 5.33, p = 0.01) [35].
Donor Management
General
Optimal cardiac donor management is a critical component to ensuring good graft function and the function of other organs. Brain death is associated with catecholamine surge and inflammatory activation [36]. This sympathetic storm results in intense peripheral vasoconstriction, coronary vasoconstriction, and hypertension. Cardiac dysfunction may ensue, and contraction band necrosis is a common pathologic finding [37, 38]. An echo obtained within the first 6 h may show depressed cardiac function; however, since ejection fraction may improve after resuscitation, it may be better to avoid early echocardiograms in favor of waiting 6–12 h until physiologic derangements and electrolyte abnormalities have been corrected. An ejection fraction of 50 % or greater is typically considered acceptable.
If there is loss of spontaneous circulation or CPR, ischemia time becomes a major concern. In this setting, vasoactives may be required to support circulation but they can negatively impact cardiac function and transplantability of the organ. Because of the physiologic derangements associated with brain death, circulatory support, restoration of organ perfusion, and correction of electrolyte abnormalities constitute early management. Donor management is typically performed in an intensive care setting, although specialized centers for managing donors have become more common. Central venous and arterial line placement and hemodynamic monitoring are recommended. In 2006, the Canadian Council for Donation and Transplantation (CCDT) published recommendations for donor management goals (DMGs) [39] (Table 1). Achieving optimal donor management goals has been demonstrated to increase the yield of organs per donor and transplants per donor [40]. Additional studies have shown an increased number of organs transplanted per donor when achieving greater than or equal to seven DMGs [40, 41].
Donors may have low levels of triiodothyronine (T3) and thyroxin (T4). As a result, thyroid hormone administration is frequently a component of aggressive management protocols in order to stabilize hemodynamics and to facilitate weaning of inotropes, although this practice is debated. In general, randomized trials have not demonstrated benefit with thyroid hormone alone or in combination with other hormone replacements while retrospective studies reported a beneficial effect [42]. Thyroid hormone does not appear to have any benefit on donor cardiac index or vasoactive drug requirement. Posterior pituitary function is also commonly affected leading to diabetes insipidus and associated fluid and electrolyte shifts. Additional hormone replacement may include corticosteroid and vasopressin [43–46].
Perioperative and Surgical Considerations
Primary allograft failure leads to catastrophic consequences and is among the leading causes of in-hospital mortality after cardiac transplantation; therefore, optimal myocardial protection plays a pivotal role in the success of the surgical procedure. While ex vivo perfusion systems may hold a promising role in the future, particularly within the donation after cardiocirculatory death donor population, the optimal technique of preserving myocardial viability and decreasing ischemia/reperfusion injury has not been established. Current organ preservation strategies are based on hypothermia in conjunction with a preservation solution, generally classified on the basis of sodium concentration as either extracellular or intracellular. The best solution for preservation of the donor heart has been a subject of debate and controversy, leading to a lack of standardization among transplant centers around the globe. A recent survey of the transplant centers in the USA revealed that at least 167 different solutions are utilized [47]. It appears that intracellular solutions (sodium content <70 mEq/L) are associated with a reduced risk of in-hospital death. Cannata and colleagues studied the effect of three different myocardial preservation solutions (HTK-Custodiol, Celsior, and St. Thomas) on intraoperative graft failure and in-hospital mortality. They observed no significant effect of the kinds of cardioplegic solution but did note that the recipient and donor age above 60 years and previous cardiac surgery were independent risk factors for in-hospital mortality, with odds ratios of 27.9 and 13.0, respectively [48]. Among the newer preservation solutions, Celsior® is perhaps emerging as the solution of choice. Compared to HTK and University of Wisconsin solutions, Celsior may be associated with better post-transplant heart recovery and lower rates of graft failure [49, 50]. Stahel et al. examined the benefits of an additional dose of cardioplegia dispensed immediately before implantation and found that it may benefit the organs suffering from longer ischemic times and improve early and late outcomes following transplantation [51].
Intraoperative blood loss secondary to coagulopathy and surgical bleeding has been associated with increased use of blood products, consequently leading to adverse outcomes following cardiac surgical procedures in general. An increasing proportion of heart transplant recipients in the USA are supported with ventricular assist devices and are receiving anticoagulation. Some require re-do sternotomy and extensive mediastinal dissection, leading to increased blood loss and utilization of blood products. Awad and colleagues investigated the effect of prior sternotomy on the postoperative mortality and morbidity after heart transplantation. While they demonstrated no difference in 60-day mortality, the 1-year survival was higher in the primary sternotomy group. The patients with prior operation had longer cardiopulmonary bypass times and ICU and hospital stays and required more blood products. The subgroup of patients with prior VAD implantation had lower 60-day and 1-year survival [52]. Historically, anticoagulation with warfarin has been discontinued or rapidly reversed immediately prior to transplantation. A recent retrospective data analysis by Morris et al. found no correlation between preoperative or postoperative international normalized ratio (INR) and chest tube output. They also noted no correlation between the preoperative INR and the perioperative use of fresh frozen plasma, suggesting that preoperative warfarin may be safely continued in patients awaiting transplantation [53].
The Future of Donor Selection and Management
Donor Selection
Evidence-based donor selection remains a challenge. The Donor Heart Study, an NIH-funded trial, is investigating evidence-based evaluation and acceptance of donor hearts. The goals of this study are to collect systematic data on cardiac function and real-time data on reasons for donor non-acceptance and to develop clinical tools for decision-making.
Ex Vivo Perfusion
The major limitations to increasing the donor pool are distance and the subsequent risk of prolonged ischemic time. The transportable Organ Care System (TranMedics; Andover, MA, USA) is a clinical ex vivo heart perfusion platform that can maintain the donor heart in a warm, beating, near-physiological state for transplantation. The Organ Care System is the only clinical platform for ex vivo perfusion of donor hearts. The results of the PROCEED II study, which randomized 130 patients to the Organ Care system, were recently published and demonstrated non-inferiority of the Organ Care System when compared to standard cold storage on short-term clinical outcomes [54]. Additional studies are needed to determine the best application of ex vivo perfusion. This technology may decrease the consequences of ischemic time and allow procurement of organs remote to the transplant site in the future [54].
Donation After Circulatory Death
Donation after circulatory death (DCD) was the method used on the first heart transplant in 1967 by Christiaan Barnard [55]. Since that time, the definition of brain death has been introduced, leading to the more common method of donation after brain death (DBD) transplantation. Recently, there has been increasing interest in DCD as a method to increase donor organ availability [56]. Previous studies have shown similar outcomes at 1 year for DCD kidney [57] and lung [58] transplants when compared to transplants donated after brain death. Factors that complicate DCD transplantation in heart transplantation include the inability to assess cardiac function and the risk of warm ischemic insult [59]. Recently, a case series was published of three DCD heart transplantations. Four hearts were retrieved and transferred to an Organ Care System for preservation, resuscitation, and transportation; three of the hearts were transplanted. Two of the recipients required temporary mechanical circulatory support, but all three had normal cardiac function within 1 week. Clearly, additional evaluation of DCD in heart transplant is required; however, this may represent an additional way to expand the donor pool in the future.
Conclusion
Donor selection and management are the initial determinants of outcomes after heart transplant. Systematic evaluation of risk factors and standardized donor management will provide the basis for optimal use of donor hearts. Evidence-based donor selection and management are needed and may serve to broaden the donor pool.
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Dr. Gillian Grafton, Dr. Gordon Samoukovic, and Dr. Monica Colvin declare that they have no conflict of interest.
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This article does not contain any studies with human or animal subjects performed by any of the authors.
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Grafton, G., Samoukovic, G. & Colvin, M.M. Cardiac Donor Selection and Management. Curr Transpl Rep 2, 338–344 (2015). https://doi.org/10.1007/s40472-015-0078-1
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DOI: https://doi.org/10.1007/s40472-015-0078-1