Transplantation of adult‐sized kidneys in low‐weight pediatric recipients achieves short‐term outcomes comparable to size‐matched grafts

Goldsmith PJ, Asthana S, Fitzpatrick M, Finlay E, Attia MS, Menon KV, Pollard SG, Ridgway DM, Ahmad N. Transplantation of adult‐sized kidneys in low‐weight pediatric recipients achieves short‐term outcomes comparable to size‐matched grafts.
Pediatr Transplantation 2010: 14:919–924. © 2010 John Wiley & Sons A/S. Abstract: Low‐weight pediatric recipients are disadvantaged by scarcity of size‐matched donors. ASK have been successfully used for pediatric recipients. We report the results of renal transplantation using ASK in low‐weight pediatric recipients and compare outcomes in weight‐matched and unmatched donor–recipient pairs. The outcomes of renal transplants using ASK grafts in low‐weight (<20 kg) recipients from a single center over a 10‐yr period were reviewed. Two groups, comprising recipients of grafts from weight‐matched and mismatched donors, were compared. Primary outcome was one‐yr graft survival. Secondary outcomes were one‐ and two‐yr calculated eGFR, changes in recipient body weight, perioperative cardiovascular stability, rates of AR and DGF. Twenty‐three low‐weight recipients were transplanted. Eleven received ASK grafts from high‐weight donors and 12 grafts from low‐weight donors. One patient in each group had early graft loss. No significant difference was observed in rates of DGF, AR, one‐yr graft or patient survival and perioperative cardiovascular parameters. ASK with considerable donor:recipient weight discrepancies can be safely transplanted into small pediatric recipients with comparable outcomes to grafts with less weight discrepancy.     

Outcomes of children receiving en bloc renal transplants from small pediatric donors

The utilization of en bloc renal allografts from small pediatric donors has been adopted as an effective strategy to expand the organ donor pool in adult recipients. Data in children are limited. The aim of our study is to describe the outcomes of en bloc renal transplants in children from our center. Medical records of children receiving pediatric en bloc renal transplants at our institution from January 2007 were abstracted. Data collected included recipient and donor demographics, operative technique and complications, and post‐operative studies. Eight children received en bloc renal transplants at a median age of 17 yr; median follow‐up was 0.9 yr. Donor body weight ranged from 4 to 22 kg. One kidney was lost to intra‐operative thrombosis, while the other kidney from this en bloc graft remained viable. All grafts showed increased renal size at follow‐up ultrasound. Surveillance biopsies showed glomerulomegaly in two patients. At last follow‐up, the median eGFR was 130 mL/min/1.73 m². The urinary protein to creatinine ratio was normal in four of seven patients. Our data suggest that in experienced centers, en bloc renal transplantation from young donors into pediatric recipients is effective. Long‐term follow‐up to monitor for complications, including hyperfiltration injury, is warranted.     

Optimizing the utilization of kidneys from small pediatric deceased donors under 15 kg by choosing pediatric recipients

Currently, most kidneys from small pediatric deceased donors are transplanted into adult recipients (i.e., PTA). However, due to the weight mismatch, there is a high discard rate and a high ratio of EBKTs if adopting PTA. Here, we sought both to optimize utilization of these challenging but scarce donor grafts by selecting pediatric recipients and to characterize the feasibility and efficacy of this PTP allocation strategy. From February 2012 to October 2014, kidneys from 27 infant donors ≤15 kg were procured and distributed to 38 pediatric candidates in our center. The grafts were utilized for EBKT if the donor weighed 2.5–5 kg and for SKT if the donor weighed 5–15 kg, leading to 10 EBKTs and 28 SKTs. The overall utilization rate from small pediatric deceased donors was 94.12%. After a follow‐up of 3–26 months, the graft survival rate was 89.47%, with four graft losses due to vascular thrombosis. Kidneys from low‐body‐weight donors should be applied to pediatric recipients, and the kidneys from infant donors ≥5 kg can be used in single‐kidney‐transplant procedures at experienced centers to optimize utilization.     

Using pediatric liver grafts (≤6 yr) for adult recipients: A considerable option?

In LT, the common policy is to allocate pediatric liver grafts to pediatric recipients. Pediatric organs are also offered to adults if there is no pediatric recipient. However, they are rarely accepted for adult recipients. So far, there is no information available reporting outcome of LT in adult recipients using pediatric livers from donors ≤6 yr. In this study, we included nine adult recipients (seven females and two males) who received grafts from children ≤6 yr from January 2008 to December 2013. We evaluated the graft quality, the GBWR and analyzed the recipients’ perioperative course. Laboratory samples and graft perfusion were analyzed. Nine adults with a median age of 49 yr (range: 25–65) and a median weight of 60 kg (range: 48–64) underwent LT with a pediatric donor graft. Median donor age was five yr (range: 3–6). Median GBWR was 1.02 (range: 0.86–1.45). After a median follow‐up of 3.9 yr (range: 11 months–6.6 yr), patient survival was 100%; graft survival was 89%. One patient needed re‐transplantation on the second postoperative day due to PNF. Eight recipients were discharged from the ICU after 2–9 days with a regular graft function. Doppler scans revealed regular flow patterns at any time. Only if denied for pediatric recipients, the use of pediatric livers from donors ≤6 yr for adult recipients is a considerable option.     

Impact of donor preprocurement cardiac arrest on clinical outcomes in pediatric deceased donor liver transplantation

PPCA has historically been considered detrimental to donor quality in LT, but transplantation of grafts from this group of donors is now routine. Our study aims to evaluate the outcomes associated with use of donors with a history of PPCA in the pediatric population. This study is a single‐center retrospective analysis of all pediatric LTs performed over an 18‐year period. Donors and recipients were stratified by the presence and length of donor PPCA time. Preprocurement donor and post‐transplant recipient laboratory values were collected to assess the degree of ischemic liver injury associated with each donor group. Cox regression analysis was used to compare survival. The records for 130 deceased pediatric LT donors and corresponding recipients were reviewed. There were 73 (56%) non‐PPCA donors and 57 (44%) PPCA donors. Donors that experienced a PPCA event demonstrated a higher median, pretransplant peak alanine aminotransferase (ALT) level (P < .001). When comparing post‐transplant recipient median ALT levels, donors with any PPCA had lower median peak ALT (P = .15) and day 3 ALT (P = .43) levels than the non‐PPCA group. Rates of early graft loss did not differ. The PPCA group with >40 minutes of ischemia had markedly lower survival at 10 years, but this finding did not reach statistical significance. Liver grafts from donors with or without PPCA demonstrated no statistically significant differences in function or survival. A history of donor PPCA alone should not be used as an exclusionary criterion in pediatric liver transplantation.     

Donor‐to‐recipient weight ratio is a risk factor for hepatic artery thrombosis after whole‐liver transplantation in children under 25 kg

Hepatic artery thrombosis (HAT) following pediatric liver transplantation increases morbidity and risk of graft failure. We performed a retrospective chart review of all patients who underwent deceased‐donor liver transplantation from August 2002 to July 2016. Multi‐organ transplant recipients were excluded. We examined the incidence of HAT at our institution and sought to identify associated donor or recipient risk factors. A total of 127 deceased‐donor liver transplant patients with a median age of 1.7 years (IQR 0.67‐6.7) were identified. Of those, 14 developed HAT, all weighing under 25 kg. Among 100 patients under 25 kg, whole‐liver graft recipients had an odds ratio of 3.98 (95% confidence interval [CI]: 1.03, 15.34; P = .045) for developing HAT compared with split‐liver graft recipients. Within the whole‐liver recipient group under 25 kg, 11 patients developed HAT with a median donor‐to‐recipient ratio (DRWR) of 0.9 (IQR: 0.7‐1.2) compared with a median DRWR of 1.4 (IQR: 1.1‐1.9) for those who did not develop HAT. Multivariate analysis showed DRWR to be an independent risk factor for HAT in patients weighing under 25 kg who received whole organ grafts, with an odds ratio of 3.89 (95% CI: 1.43, 10.54; P = .008) for each 0.5 unit decrease in DRWR. Our results suggest that in recipients under 25 kg 1) split‐liver grafts may have a lower rate of HAT and 2) selecting whole organ donors with a higher DRWR may decrease the incidence of HAT.     

Donation after cardiac death kidneys are suitable for pediatric recipients

Despite the high number of children listed for kidney transplantation and shortage of deceased organ donors, there is reluctance to utilize DCD kidneys in pediatric recipients. We examined outcomes in pediatric kidney transplant patients who received a DCD kidney allograft. UNOS database was queried to examine outcomes in all pediatric kidney transplant recipients from 1994 to 2017. Pediatric status was defined as <18 years at the time of transplantation. Recipients were divided by DBD or DCD allograft status. Donor and recipient demographic data were examined. Patient and allograft survival was calculated, and Kaplan‐Meier survival curves were generated. A P‐value of <0.05 was considered to be significant. A total of 286 pediatric kidney transplant recipients received a DCD allograft. The donors in the DCD group were significantly younger than those in the DBD group (21.7 vs 23.3 years), with a higher KDPI (26.5% vs 22.9%). In the DCD group, the average age at transplant was younger (11.6 vs 12.9 years), with no difference in cold ischemia time or length of stay between the two groups. Rates of delayed graft function were higher in the DCD group, but despite this, there were no significant differences in allograft or patient survival between the groups. There is no difference in allograft survival in pediatric kidney transplant recipients who receive a DCD kidney allograft. DCD kidney allografts are suitable for transplantation in pediatric patients and can greatly expand the donor pool.     

Use of public health service increased risk kidneys in pediatric renal transplant recipients

With the opioid epidemic and expansion of “IR” classification, 25% of deceased donors are categorized PHS‐IR. Studies have assessed utilization of PHS‐IR organs among adults, but little is known about pediatric recipients. This retrospective cohort study from 2004‐2016 (IR period) aimed to: (a) assess IR kidney utilization patterns between adults and children; (b) identify recipient factors associated with transplant from IR donors among pediatric kidney recipients; and (c) determine geography's role in IR kidney utilization for children. The proportion of pediatric recipients receiving IR kidneys was significantly lower than adults (P < 0.001), even when stratified by donor mechanism of death (non‐overdose/overdose) and era. In mixed effects models accounting for clustering within centers and regions, older recipient age, later era (post‐PHS‐IR expansion), and blood type were associated with significantly higher odds of receiving an IR kidney (17 years era 5: OR 5.16 [CI 2.05‐13.1] P < 0.001; 18‐21 years era 5: OR 2.72 [CI 1.05‐7.06] P = 0.04; blood type O: OR 1.32 [CI 1.06‐1.64] P = 0.013). The median odds ratio for center within region was 1.77 indicating that when comparing two patients in a region, the odds of receiving an IR kidney were 77% higher for a patient from a center with higher likelihood of receiving an IR kidney. Utilization of PHS‐IR kidneys is significantly lower among pediatric recipients versus adult counterparts. More work is needed to understand the reasons for these differences in children in order to continue their access to this life‐prolonging therapy.     

Transient elastography assessment of liver allograft fibrosis in pediatric transplant recipients

TE measures liver stiffness to assess fibrosis. Its use in post‐transplant patients was reported in few small pediatric studies. We evaluated TE ability to predict liver graft fibrosis in a large cohort while comparing it to the performance of APRI and FIB‐4. We also investigated the effect of graft type on LSMs. Patients at Boston Children's Hospital who underwent LT and LSM ≤ 1 year from biopsy (2007‐2018) were eligible. Ninety‐four patients (45%M) aged 1‐21 years (89% < 18 years; 13% < 2 years) were eligible. Median time between transplant/biopsy and LSM was 5.1 years and 52 days, respectively. Thirty‐nine percent received whole‐liver grafts, 54% TV grafts, and 6% as part of MV. At LSM, median ALT was 25 [IQR 16‐33] IU/L. Twenty‐one percent had METAVIR ≥ F2. LSM was statistically higher among those with significant fibrosis (METAVIR ≥ F2) compared to those with METAVIR F0/F1 (median [IQR] 7.5 [4.6, 13.6] vs 5.1 [4.0, 6.4] kPa, respectively) (P = .005 by Wilcoxon rank‐sum test). APRI and FIB‐4 distributions were not different across METAVIR stages. The AUROC for LSM was 0.71 (95% CI 0.56‐0.85) with an optimal cut‐point of 6.5 kPa. Graft type had no influence on the AUROC for LSM. TE is useful for assessing significant graft fibrosis in children and young adult LT recipients and performs better than APRI and FIB‐4. TV grafts demonstrate similar correlation with histology as whole‐liver grafts.     

Lymphocyte‐depleting induction therapy lowers the risk of acute rejection in African American pediatric kidney transplant recipients

The use of lymphocyte‐depleting induction immunosuppression has been associated with a reduction in risk of AR after KT among adult recipients, particularly among high‐risk subgroups such as AAs. However, data on induction regimen and AR risk are lacking among pediatric KT recipients. We examined outcomes among 7884 first‐time pediatric KT recipients using SRTR data (2000‐2014). Characteristics were compared across race using Wilcoxon rank‐sum tests for continuous and chi‐square tests for categorical variables. Risk of AR was estimated using modified Poisson regression, stratified by recipient race, adjusting for recipient age, gender, BMI, primary diagnosis, number of HLA mismatches, maintenance immunosuppression, and donor type. Risk of AR within 1 year was lower in AA recipients receiving lymphocyte‐depleting induction (ATG or alemtuzumab; RR, 0.66; 95% CI, 0.52‐0.83 P < .001) compared to AA recipients receiving anti‐IL‐2 receptor antibody induction. This difference was not seen in non‐AA recipients receiving lymphocyte‐depleting induction (RR, 0.93; 95% CI, 0.81‐1.06, P = .26) compared to IL‐2 induction. These findings support a role for lymphocyte‐depleting induction agents in AA pediatric patients undergoing KT and continued use of IL‐2 inhibitor induction in non‐AA pediatric KT recipients.     

First report of successful transplantation of a pediatric donor liver graft after hypothermic machine perfusion

One of the main limiting factors in pediatric liver transplantation is donor availability. For adults, DCD liver grafts are increasingly used to expand the donor pool. To improve outcome after DCD liver transplantation, ex situ machine perfusion is used as an alternative organ preservation strategy, with the supplemental value of providing oxygen to the graft during preservation. We here report the first successful transplantation of a pediatric DCD liver graft after hypothermic oxygenated machine perfusion. The full‐size liver graft was derived from a 13‐year‐old, female DCD donor and was end‐ischemic pretreated with dual hypothermic oxygenated machine perfusion. Arterial and portal pressures were set at 18 and 4 mm Hg, slightly lower than protocolized settings for adult livers . During 2 hours of machine perfusion, portal and arterial flows increased from 100 to 210 mL/min and 30 to 63 mL/min, respectively. The pretreated liver graft was implanted in a 16‐year‐old girl with progressive familial intrahepatic cholestasis type 2. Postoperative AST, ALT, and prothrombin time normalized within a week. The recipient quickly recovered and was discharged from the hospital after 18 days. One year after transplantation, she is in excellent condition with a completely normal liver function and histology. This case is the first report of successful transplantation of a pediatric DCD liver graft after hypothermic oxygenated machine perfusion and illustrates the potential role of ex situ machine perfusion in expanding the donor pool and improving outcome after pediatric liver transplantation.     

Kidney transplantation from pediatric donors: size-match-based allocation

Abstract:  Use of kidneys from pediatric donors has been associated with worse outcome. We review our 20-yr experience using pediatric kidneys as single grafts in children and adult recipients. Charts review of 29 recipients, transplanted between 1986 and 2005, who received a graft from a donor ≤6 yr was performed. One recipient received "en bloc" graft and the remaining patients received a single kidney. Nine recipients were adults and 21 were children. Creatinine at discharge and at follow-up was recorded and actuarial graft and patient survivals were calculated using life table analysis. All 29 recipients are alive at mean follow-up of 92 months. Five grafts were lost for: primary non-function (1), recurrent FSGS at 14 month (1) and chronic rejection (3). All five recipients who lost their graft received a graft from donors ≤3 yr. Mean calculated GFR (Schwartz formula) at one and five yr were 84.2 mL/m²/1.73 and 98.3 mL/m²/1.73, respectively. Actuarial graft survival was 93.2%, 89.6%, and 81.9% at one, five and at 10 yr after transplant. The use of a single kidney graft from pediatric donors yields good long-term results. Kidneys from small pediatric donors should be allocated first to matched-weight recipients but otherwise can be transplanted in older children or in adults.     

Transplantation of adult‐size kidneys in small pediatric recipients: A single‐center experience

RTx of adult‐size kidneys presents a size mismatch in small pediatric recipients, and there are potential surgical complications. This study reveals the outcomes of intra‐ and extraperitoneal RTx in low‐weight (less than 15 kg) pediatric recipients. We studied 51 pediatric patients weighing less than 15 kg who received a living‐related donor renal transplant between 2009 and 2017. The intraperitoneal (group A, n = 24) and extraperitoneal (group B, n = 27) approaches were compared. In group A, the mean age, Ht, and weight were 3.8 ± 1.6 years, 83.7 ± 6.5 cm, 10.5 ± 1.8 kg; in group B, 5.0 ± 1.9 years, 95.3 ± 7.3 cm, and 13.0 ± 1.4 kg. Single renal artery grafts (21 in group A and 16 in group B) and double renal artery grafts (three in group A and 11 in group B) were performed. Of the patients with double renal artery transplants, one in group A and six in group B underwent ex vivo arterial reconstruction. The eGFR (mL/min/1.73 m²) at 1‐week post‐transplant in group A was significantly higher than that in group B; the eGFRs at 4 weeks post‐transplant did not differ. One graft was lost in group B because of vascular thrombosis. Post‐transplant complications included ileus and transplant ureteral stenosis. There was no significant difference in 5‐year graft survival rate (group A 100%, group B 91.7%). Both transplant approaches are feasible to adapt to a size mismatch between the adult‐size donor kidney and low‐weight pediatric recipients.     

Outcomes and predictive factors of pediatric kidney transplants: An analysis of the Thai Transplant Registry

As universal coverage for pediatric kidney transplantation (KT) was introduced in Thailand in 2008, the number of recipients has been increasing. We evaluated predictive factors for graft failure to understand how to improve clinical outcomes in these children. Using data obtained from the National Transplant registry, we assessed the risk of graft failure using the Kaplan–Meier method and Cox proportional hazards regression. Altogether, 201 recipients aged <21 yr at the time of KT were studied. Living donors (LD) were significantly older than deceased donor (DD). Mean cold ischemia time of DD was 17 h. The mean donor glomerular filtration rate (GFR) was 84.0 mL/min/1.73 m². Induction immunosuppressive therapy was administered more frequently in DD than in LDKT. Delayed graft function (DGF) occurred in 36 transplants. Over 719 person years of follow‐up, 42 graft failures occurred. Graft survival at one, three, and five yr post‐transplant were 95%, 88% and 76%, respectively. Two factors independently predicted graft failure in multivariate analysis. The hazard ratios for graft failure in patients with DGF and in patients with donor GFR of ≤30 mL/min/1.73 m² were 2.5 and 9.7, respectively. Pediatric recipients should receive the first priority for allografts from young DD with a good GFR, and DGF should be meticulously prevented.     

Pediatrics and donor‐derived disease transmission: The US OPTN experience

PDDTE are tracked by the OPTN Ad Hoc DTAC. Specific evaluation of potential transmissions from pediatric deceased donors or the impact of donor‐derived disease transmissions to pediatric organ recipients has not been previously undertaken. PDDTE reported to the DTAC between 2008 and 2013 were reviewed, characterized as proven, probable, possible, IWDT, unlikely, or excluded for both the whole event and each individual recipient. Pediatric donors and recipients were defined as being 0‐17 years of age. Analysis was undertaken to characterize potential disease transmission from pediatric donors to adult or pediatric recipients and also to evaluate potential transmission from all donors to pediatric recipients. P/P cases were further analyzed. A total of 5238 pediatric deceased US donors accounted for 17 456 organ transplants during the study period; 103 PDDTE reports arose from these donors (2.0%). PDDTE were characterized as P/P (15%), possible (13%), IWDT (9%), unlikely, and excluded (63%). Disease was transmitted to 22 of 54 potentially exposed (adult and pediatric) recipients with six attributable deaths. An infectious pathogen accounted for 13/15 of the P/P PDDTE associated with pediatric donors, affecting 19 of 50 potentially exposed recipients and resulting in five deaths. Four separate viral pathogens from six donors accounted for P/P transmissions to 11 recipients with the unanticipated transmission of CMV most common. No pediatric donor transmitted HIV, HBV, or HCV. Bacteria, fungi, and parasites accounted for three (all staphylococci), three (Zygomycetes and Histoplasma), and two (both Toxoplasma) P/P transmissions from seven donors, respectively. From the recipient side, 11/11,188 pediatric recipient deceased and living donor transplants during the study period were associated with a P/P PDDTE (<0.1%) with infectious pathogens accounting for 9/11 P/P events. Infections were split among pathogen categories (bacteria 2, viruses 3, parasites 3, and fungi 1). Reporting rates of PDDTE involving pediatric donors were very low and similar to rates from all donors, with resulting P/P transmissions occurring in only 0.1% of exposed recipients, but transmissions were associated with six deaths. Rates of P/P transmission to pediatric recipients from any donor (<0.1%) were also very low and similar to that of all recipients. Additional studies are needed to compare the pattern and outcome of donor‐derived disease transmission from and to pediatric and adult donor and recipients.     

Donor–recipient height ratio and outcomes in pediatric heart transplantation

Height matching in pediatric HTx has been proposed as a superior method of evaluating graft size, but no studies have examined survival advantage for height‐matched donor–recipient pairs. We hypothesized that in pediatric patients with DCM, an oversized donor improves survival and aimed to define the optimal height ratio in this patient group. Pediatric primary HTx recipients with DCM between 10/89 and 09/12 were identified in the OPTN database. Patients were stratified into three donor–recipient height and weight ratio categories. One‐ and five‐yr survival was compared using Kaplan–Meier analysis and HRs were computed. A total of 2133 children with DCM who underwent HTx during the study period were included. Unadjusted one‐yr survival was worse for DRHR <0.87 (HR, 2.15 [95% CL, 1.30, 3.53]; p < 0.01). This difference was not present at five yr post‐HTx or when stratified by weight. After adjustment for other risk factors affecting transplant survival, height matching was no longer significant. Although height matching appears to predict short‐term survival better than weight in pediatric HTx recipients with DCM, other factors play a more important role as height matching loses significance in multivariate analysis.     

Reduced ATG‐F dosage for induction in pediatric renal transplantation: A single‐center experience

Rabbit antithymocyte globulin (ATG‐F) is an extensively used induction agent. To our knowledge, no study to date has assessed reduced ATG‐F dosage in children undergoing renal transplantation. This was a retrospective analysis of pediatric renal recipients in the Department of Kidney Transplantation, The First Affiliated Hospital of Zhengzhou University, from May 2007 to February 2013. Thirty‐nine children underwent renal transplantation including 25 living related and 14 cardiac deceased donor transplantation. Each recipient received ATG‐F 1.5 mg/kg/d once daily for 4 days. Of the 39 recipients, five (12.8%) showed delayed graft function, including one of 25 recipients (4%) of living donor and four of 14 recipients (28.6%) of deceased donor transplantation (p < 0.05). Six of the 39 recipients (15.4%) showed acute rejection on renal biopsy. Follow‐up in these children ranged from 6 to 87 months. The one‐, three‐, and five‐yr recipients and grafts survival rates postoperation were each 94.9% and 97.3%, 97.3%, and 94.6%, respectively. The incidence of postoperative infection was 35.9% (14/39), and did not differ significantly in the living related and deceased donor groups (p > 0.05). Low‐dose ATG‐F can be safely used as an immune induction agent in pediatric renal transplantation.     

Variability in donor selection among pediatric heart transplant providers: Results from an international survey

There is considerable variability in donor acceptance practices among adult heart transplant providers; however, pediatric data are lacking. The aim of this study was to assess donor acceptance practices among pediatric heart transplant professionals. The authors generated a survey to investigate clinicians’ donor acceptance practices. This survey was distributed to all members of the ISHLT Pediatric Council in April 2018. A total of 130 providers responded from 17 different countries. There was a wide range of acceptable criteria for potential donors. These included optimal donor‐to‐recipient weight ratio (lower limit: 50%‐150%, upper limit: 120%‐350%), maximum donor age (25‐75 years), and minimum acceptable left ventricular EF (30%‐60%). Non‐US centers demonstrated less restrictive donor selection criteria and were willing to accept older donors (50 vs 35 years, P < 0.001), greater size discrepancy (upper limit weight ratio 250% vs 200%, P = 0.009), and donors with a lower EF (45% vs 50%, P < 0.001). Recipient factors were most influential in the decision to accept marginal donors including recipients requiring ECMO support, ventilator support, and highly sensitized patients with a negative XM. However, programmatic factors impacted the decision to decline marginal donors including recent programmatic mortalities and concerns for programmatic restrictions from regulatory bodies. There is significant variation in donor acceptance practices among pediatric heart transplant professionals. Standardization of donor acceptance practices through the development of a consensus statement may help to improve donor utilization and reduce waitlist mortality.     

The relationship of donor source and age on short- and long-term allograft survival in pediatric renal transplantation

Abstract:  Limited pediatric data on allograft survival from advanced aged kidney donors exist. To determine the influence of donor source and age on allograft survival in pediatric renal transplant recipients, we analyzed the OPTN database. Allograft survival for 7291 pediatric renal transplants was evaluated. Up to five yr post-transplantation, graft survival was higher for LD vs. DD recipients. At seven yr, allograft survival was 71% in 18–54 yr-old LD recipients, 59.1% in ≥55 yr-old LD, and 45.1% in ≥50 yr-old DD recipients. An approximate 35% improvement in allograft survival in 18–54 yr-old LD recipients was observed. Multivariate results showed that recipients of LD 35–49 (aRR 0.66, 95% CI 0.55–0.80) and LD 50–54 (aRR 0.65, 95% CI 0.45–0.94) have a graft survival advantage over the ideal DD. In LD ≥55 yr, no improvement in graft survival was observed when compared with the 18–34 yr-old DD. In summary, we observed in a pediatric population, <55 yr-old LD kidneys afford improved long-term allograft survival when compared with DD kidney recipients. Increasing awareness of the long-term graft survival advantage for children receiving an LD kidney, even from older donors, should be a priority.     

Donors' characteristics and impact on outcomes in pediatric heart transplant recipients

Organ availability and acceptability limit pediatric HTx. What characteristics define an unacceptable or high‐risk pediatric donor remains unclear. The purpose of this study was to characterize a large cohort of pediatric donors and determine the donor risk factors, including cumulative risk, that affect recipient survival. Data from the PHTS, a prospective multicenter study, were used to examine the impact of donor factors on the outcomes of patients listed <18 yr of age who received a HTx between 1993 and 2009. Donor data were available for 3149 of 3156 HTx (99.8%). Donor cause of death, need for inotropes, or CPR did not affect survival outcomes (p = 0.05). Ischemic time also did not have an impact on overall recipient survival; however, longer ischemic times negatively impacted one‐yr post‐transplant survival (p < 0.0001). There was no impact of cumulative risk factors on survival (p = 0.8). Although used in a minority of cases, hormonal therapy in the donor positively impacted survival (p = 0.03). In multivariate analysis, the only donor factor associated with decreased survival was smaller donor BSA, the other factors being related to the recipient characteristics. When analyzed by recipient age, there were no donor‐related factors that affected survival for those who received a transplant at <6 months of age. Longer ischemic time (p < 0.0001) and greater age difference between the recipient and donor (p = 0.0098) were donor‐related factors impacting early‐phase survival for recipients who received a graft at ≥10 yr of age. Factors perceived to define a marginal or high‐risk pediatric heart donor including inotrope use, CPR and donor cause of death may have less impact on outcomes than previously thought. Longer ischemic times did impact one yr, but not overall survival, and this impact was much greater with older donors. Parameters for accepting a donor heart can potentially be expanded, especially in the infant age group, but strong consideration should always be given to the interaction between ischemic time and donor age.