Predictors of cardiac allograft vasculopathy in pediatric heart transplant recipients

CAV remains a leading cause of late graft loss and mortality among survivors of pediatric heart transplantation. We sought to define the incidence of CAV and identify its predictors in pediatric heart transplant recipients. The OPTN/UNOS database was analyzed for pediatric recipients who underwent heart transplant between 1987 and 2011. The primary end‐point is time from heart transplantation to development of CAV (CAV‐free survival). To identify predictors of CAV‐free survival, demographic and transplant data were analyzed by the Kaplan–Meier survival method and Cox proportional hazards regression. Of 5211 pediatric heart transplant recipients with at least one‐yr follow‐up, the incidence of CAV at five, 10, and 15 yr was 13%, 25%, and 54%, respectively. Multivariate analysis found that risk of CAV was associated with the following variables: Recipient age 1–4 yr (HR 1.25), 5–9 yr (1.45), 10–18 yr (1.83), donor age >18 yr (1.34), re‐transplantation (2.14), recipient black race (1.55), and donor cigarette use (1.54). Older recipient and donor age, recipient black race, donor cigarette use, and re‐transplantation were highly associated with shorter CAV‐free survival.     

Improved outcomes in pediatric liver transplantation for acute liver failure

Miloh T, Kerkar N, Parkar S, Emre S, Annunziato R, Mendez C, Arnon R, Suchy F, Rodriguez‐Laiz G, Del Rio Martin J, Sturdevant M, Iyer K. Improved outcomes in pediatric liver transplantation for acute liver failure.
Pediatr Transplantation 2010: 14:863–869. © 2010 John Wiley & Sons A/S. Abstract: OLT is a life‐saving option for ALF. Aim: To evaluate our outcomes in pediatric OLT for ALF. Methods: Retrospective review of our data between 1992 and 2007. Results: Of 142 children with ALF, 126 were listed, of which 40 spontaneously improved, nine died, and 77 underwent OLT (median waiting time four days). Fifty‐three children received deceased donor grafts (34 whole and 19 split grafts), and there were 24 living donor grafts. The one‐ and five‐yr patient survival was 87% and 80%, and graft survival 83% and 79%, respectively. Thirteen patients died after OLT, and there were nine retransplants in seven patients. Patient weight, length of stay, creatinine, and infection were significantly associated with death; increased weight and black ethnicity were associated with graft loss on univariate analysis, but not on multivariate analysis. There were no significant differences in patient survival (one and five yr), graft loss, or other complications between the groups. Conclusion: We report the largest single‐center study of OLT in pediatric ALF, demonstrating no difference in outcomes between different graft types. Our liberal use of segmental grafts may allow earlier OLT in this high‐risk cohort and contribute to our excellent outcomes.     

Pediatric liver transplantation for primary malignant liver tumors with a focus on hepatic epithelioid hemangioendothelioma: The UNOS experience

Guiteau JJ, Cotton RT, Karpen SJ, O’Mahony CA, Goss JA. Pediatric liver transplantation for primary malignant liver tumors with a focus on hepatic epithelioid hemangioendothelioma: The UNOS experience.
Pediatr Transplantation 2010: 14: 326–331. © 2009 John Wiley & Sons A/S. Abstract: Treatment for HEH does not follow a standardized algorithm. From clinical experience, it is assumed that pediatric patients with HEH will fare as well as other common pediatric liver tumors post‐OLT. The UNOS dataset was examined for patients with pediatric OLT between 1987 and 2007. Patients were grouped into non‐tumors, HB, HCC, HEH, and rare liver tumors. COD analysis was calculated using Fisher’s exact test. Patient, allograft, and recurrence‐free survival were compared using Kaplan–Meier curves and log‐rank tests. A total of 366 patients with pediatric OLT were identified with primary liver tumors (HB – 237, HCC – 58, HEH – 35, other – 36). HEH patient survival (five yr: 60.6%) was poorer than non‐tumor OLTpatient survival (five yr: 84.4%). Survival was worse when compared to HB (five yr: 72%) and rare liver tumors (five yr: 78.9%), but better than HCC (five yr: 53.5%). Allograft survival in HEH (five yr: 50.1%) lies between HB (five yr: 63.6%) and HCC (five yr: 42.8%). COD analysis demonstrates recurrence as a major cause in HB and HCC, but not for HEH or other liver tumors. The data suggest that patient survival may not be as high as previously believed and further investigation is warranted.     

The use of advanced-age donor hearts adversely affects survival in pediatric heart transplantation

There is a limited supply of adequate donor hearts for cardiac transplantation. The safety of using advanced-age donor hearts has been debated in adult transplantation but has not been studied previously in pediatric recipients. In this retrospective study, survival of 79 pediatric heart transplant recipients was reviewed. Pediatric recipient groups were stratified based on donor age (group 1 donor age > 40 yr, n = 5; group 2 donor age < or = 40 yr, n = 74). Survival of 267 adolescent (ages 11-17) heart transplant recipients in the United Network for Organ Sharing (UNOS) database was also reviewed. Patients were likewise divided into two groups based on donor age (> 40 yr, n = 12; < or = 40 yr, n = 255). Survival at one yr was 20% in group 1 vs. 78% in group 2 (p < 0.005). Cause of death in all group 1 patients was graft failure secondary to acute rejection. Analysis of risk of death was only significantly attributable to the age of the donor. The increased risk attributable to advanced donor age was also supported by the UNOS data. The UNOS one and two-year Kaplan-Meier survival curves were significantly lower in adolescent patients who received donor hearts > 40 yr of age. One-year survival was 58% (older donors) vs. 85% (younger donors, p < 0.005) and two-year survival was 44% (older donors) vs. 79% (younger donors, p < 0.005). Advanced-age donor hearts should be contraindicated in pediatric transplantation with the exception of critically ill patients who may not be able to wait for a younger heart.     

Regional variation in the use of 1A status exceptions for pediatric heart transplant candidates: is this equitable?

The use of status exceptions (SE) was recently publicized as a strategy to reduce waitlist times for children awaiting heart transplant (HTx). The aim of this study was to assess SE use across UNOS regions and compare survival in patients listed using a SE to those listed by standard criteria. The OPTN database was queried for all pediatric patients listed for HTx (2000–2014). SE use was compared across UNOS regions. Survival curves were generated and compared using the log‐rank test. 1A SE use is uncommon, being utilized in 108 of 4587 pediatric 1A listings (2.4%). There is significant variability in SE use across UNOS regions (0.7%–16.4% of 1A listings, P < .001). Waitlist survival is significantly higher in candidates listed using a 1A SE compared to those listed by standard criteria (P = .001) and is similar to 1B listings. Regional variation in 1A SE use has the potential to introduce bias into a system designed to be equitable. Waitlist survival in patients listed using a SE is similar to those listed status 1B, suggesting these patients may not require 1A status. Careful review of pediatric heart allocation policies is needed to optimize patient outcomes and ensure a fair and unbiased allocation system.     

Renal graft outcome after combined liver and kidney transplantation in children: UCLA and UNOS experience

de la Cerda F, Jimenez WA, Gjertson DW, Venick R, Tsai E, Ettenger R. Renal graft outcome after combined liver and kidney transplantation in children: UCLA and UNOS experience.
Pediatr Transplantation 2010: 14:459–464. © 2010 John Wiley & Sons A/S. Abstract: Although it has been described in adults that renal grafts in the context of CLKT have a lower number of AR episodes and improved renal allograft survival, this has never been examined in pediatrics. We performed a single center retrospective case–control study examining 10 patients aged 10 ± 6 yr with a CLKT that survived the post‐surgery period of six months, and compared outcomes to a group of 20 KO transplants matched for age, era, and immunosuppression. We observed a significant reduction in the incidence of AR episodes in the CLKT group. To evaluate whether or not this experience was reproducible nationally, we performed an analysis of the 1995–2005 UNOS database. As of March 2007, 111 CLKT and 3798 KO transplants were identified from the OPTN/UNOS data. There was a significant improvement in the late kidney graft survival at five yr post‐transplant in the CLKT group. These findings support the concept that liver transplantation is immunologically protective of the kidney allograft in CLKT.     

High‐risk age window for mortality in children with cystic fibrosis after lung transplantation

LTx in children with CF remains controversial. The UNOS database was queried from 1987 to 2013 for CF patients <18 yr of age at time of transplant. PCHR model was used to quantify hazard of mortality. 489 recipients were included in the survival analysis. The hazard function of post‐transplant mortality was plotted over attained age to identify age window of highest risk, which was 16–20 yr. Unadjusted PCHR model revealed ages immediately after the high‐risk window were characterized by lower hazard of mortality (HR = 0.472; 95% CI = 0.302, 0.738; p = 0.001). After adjusting for potential confounders, the decline in mortality hazard immediately after the high‐risk window remained statistically significant (HR = 0.394; 95% CI: 0.211, 0.737; p = 0.004). Hazard of mortality in children with CF after LTx was highest between 16 and 20 yr of attained age and declined thereafter.     

Pretransplant six‐minute walk test predicts peri‐ and post‐operative outcomes after pediatric lung transplantation

The purpose of the pretransplant assessment in lung transplantation is to determine a patient's need for transplant as well as their potential survival post‐procedure. In 2005, the UNOS introduced the LAS, a calculation based on multiple physiologic measures to determine need and likelihood for survival. Measures include NYHA class and the 6‐MWT. Some adult studies indicate a positive correlation with 6‐MWT and waiting list survival. In pediatric/adolescent patients, there are minimal data regarding the predictive value of physiologic markers in either wait list survival or post‐transplant outcome. A retrospective cohort study of 60 consecutive lung transplantations from 1990 to 2008 was performed at a pediatric tertiary care facility. Functional pretransplant assessments were abstracted from the medical record and compared with outcomes after transplantation. Results: a 6‐MWT of >1000 ft (305 m) prior to transplantation correlated with a shorter ICU stay (7 vs. 11 days, p = 0.046) and fewer days of mechanical ventilation (2 vs. 4, p = 0.04). A pretransplant 6‐MWT greater than 750 ft (229 m) correlated with shorter overall hospitalization (37 vs. 20 days, p = 0.03). Measuring pretransplant 6‐MWT tests for pediatric patients is valuable in predicting peri‐operative outcomes after lung transplantation.     

Survival in children on extracorporeal membrane oxygenation at the time of lung transplantation

Limited data exist on ECMO at the time of LTx in children. The UNOS database was queried from 2000 to 2013 for pediatric lung transplant recipients (<18 yr) to assess post‐transplant survival of patients on ECMO at the time of LTx. Of 587 pediatric recipients with 17 on ECMO, 585 were used for univariate and Kaplan–Meier function analysis, 535 for multivariate Cox models, and 24 for propensity score matching. Univariate Cox (HR = 1.777; 95% CI: 0.658, 4.803; p = 0.257) and Kaplan–Meier function (log‐rank test: chi‐square (df = 1): 1.32, p = 0.250) analyses did not identify a survival difference between ECMO and non‐ECMO, while multivariate Cox models (HR = 1.821; 95% CI: 0.654, 5.065; p = 0.251) did not demonstrate an increased risk for death. Propensity score matching analysis (HR = 1.500; 95% CI: 0.251, 8.977; p = 0.657) also failed to demonstrate a significantly increased hazard ratio. Using a contemporary cohort of pediatric lung transplant recipients, the use of ECMO at the time of lung transplantation did not negatively impact survival.     

Impact of donor cardiopulmonary resuscitation on pediatric heart transplant outcome

Mortality is the highest of any solid organ in pediatric patients awaiting heart transplantation. Strategies to increase the donor pool are needed if survival to transplant is to improve. There can be reluctance to accept pediatric hearts for transplantation if the donor has received cardiopulmonary resuscitation (CPR). This study asked if donor CPR impacts the survival of pediatric heart transplant recipients. Analysis of the UNOS database was performed for all cardiac transplants performed in patients aged 0-18 yr, with donors classified as to whether they received CPR (CPR+) or not (CPR-). We compared overall survival and survival at 30 days, one yr, and five yr between groups. Within the CPR+ group, the impact of duration of CPR on survival was compared. The need for inotropic support and ejection fraction was compared between donor groups as a measure of organ function. Overall survival and survival at 30 days, one yr, and five yr did not differ in the CPR+ compared to the CPR- group. Within the CPR+ group, duration of CPR was unrelated to post-transplant survival. The need for inotropic support at procurement was similar, and ejection fraction did not differ between the CPR+ and CPR- groups. Donor CPR does not have a negative impact on pediatric heart transplant survival.     

Combined liver and kidney transplantation and kidney after liver transplantation in children: Indication,postoperative outcome,and long‐term results

CLKT and sequential KALT are decided on a case‐by‐case basis in children for special indications such as ARPKD or PH1. We report on 21 children who underwent CLKT or KALT at our hospital between 1998 and 2013. Eleven children were diagnosed with PH1 and six with ARPKD. Other diagnosis were Joubert syndrome (n = 1), nephronophthisis (n = 1), CF (n = 1), and hepatocellular carcinoma (n = 1). Children (12 males, nine females) were aged 7.8 ± 6.2 yr (range, 10 months to 18 yr) at time of transplantation. Average wait time was 1.9 ± 0.9 yr (range, four months to 2.3 yr). Fifteen patients received dialysis prior to transplantation. In PH1 patients, four children received CLKT, five received KALT, and two infants have received only an LTx, whereas all six patients with ARPKD received CLKT. In patients with other indications, CLKT was performed in three cases and KALT in one girl. Cumulative 10‐yr survival of all 21 patients was 78.4%. At the time of transfer into adult care, 13 patients retained stable liver and kidney function. Regardless the underlying diagnosis, CLKT and KALT can be performed in children with good surgical outcomes and long‐term survival.     

Outcomes in pediatric hepatitis C transplant recipients: Analysis of the UNOS database

HCV may lead to the development of ESLD in late childhood and, consequently, contributes to the need for liver transplantation. The aim of this study was to examine post‐transplant outcomes in HCV‐positive pediatric patients with ESLD from any cause and to determine the impact of the PELD scoring system, introduced in February 2002, on post‐transplant patient and graft survival. A retrospective analysis of the UNOS database from 1994 to 2010 was performed to assess graft and patient survival in pediatric HCV‐seropositive liver transplant recipients. Graft survival and patient survival comparing subjects in the pre‐PELD era and post‐PELD era were analyzed using Kaplan–Meier statistics. Factors associated with survival were identified using Cox regression analysis. Of 120 pediatric HCV transplant recipients, 80 were transplanted in the pre‐PELD era and 40 were transplanted post‐PELD. Median serum total bilirubin, INR, and creatinine were 4.8 mg/dL, 1.6, and 0.7 mg/dL in the pre‐PELD era vs. 5.5 mg/dL, 1.7, and 0.6 mg/mL, respectively, in the post‐PELD era (p NS). One‐yr graft survival in the pre‐PELD vs. post‐PELD era was 65.0% and 89.7%, respectively (p < 0.01); corresponding three‐yr graft survival was 57.3% vs. 76.2% (p = 0.04). One‐yr patient survival in the pre‐PELD vs. post‐PELD era was 79.0% and 97.5%, respectively (p < 0.01); corresponding three‐yr survival was 79.0% vs. 89.4% (p = 0.17). Twenty‐eight patients (23.3%) were retransplanted: 24 (30%) in the pre‐PELD era (median time to retransplant 272 days) and four (10%) in the post‐PELD era (median time to retransplant 586 days). Early follow‐up demonstrates a trend toward improved pediatric HCV liver transplant graft and patient survival in the post‐PELD era. Superior outcomes may be attributed to pretransplant factors, improved surgical technique and better treatment options for HCV infection.     

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.     

Impact of congenital heart disease on outcomes of pediatric heart‐lung transplantation

HLT is reserved for children with cardiopulmonary disease not amendable to alternative therapies. Children with CHD with or without ES may be considered for HLT. Outcomes of HLT in this population are not well described. To test the hypothesis that CHD without ES is associated with worse graft survival and identify factors associated with poor outcome, a retrospective analysis of the UNOS database was performed. One hundred and seventy‐eight pediatric HLTs were performed between 1987 and 2011. CHD was the diagnosis in 65 patients, of which 34 had CHD without ES. Patients with CHD without ES had decreased patient survival (median 1.31 yr) compared with CHD with ES (4.80 yr, p = 0.05). On multivariable analysis, the following were associated with graft failure: CHD without ES (adjusted HR 1.69, 95% CI 1.09–2.62), younger age (1.04, 1.01–1.08), pretransplant mechanical ventilation (1.75, 1.01–3.06), pretransplant ECMO (3.07, 1.32–7.12), pretransplant PRAs (1.53, 1.06–2.20), and transplant era (1.85, 1.16–2.94). In children with CHD who require HLT, underlying physiology influences outcomes. Those without ES have a worse prognosis. The diagnosis of CHD without ES and preoperative factors may inform decisions in a complex patient population.     

Intra‐operative extracorporeal membrane oxygenation use in pediatric lung transplantation – The Zurich experience

There is a lack of data regarding use of ECMO in children undergoing lung transplantation. We evaluated our experience of ECMO in pediatric lung transplant recipients. All patients (<18 yr) who underwent lung transplants between 1997 and 2011 were included (17 children; nine males; median age 16 yr), and the use of intra‐operative ECMO evaluated. Transplant procedures were carried out with intra‐operative ECMO in seven children (all bilateral lung transplants). Demographics of ECMO and non‐ECMO patients were comparable. One child was already on ECMO pre‐operative. Lung graft size reduction was undertaken in five ECMO and four non‐ECMO cases, respectively. Five patients were taken off ECMO intra‐operatively; the other patients were weaned off ECMO within 48 h post‐operatively. Three‐months survival was 100%. By 12 months post‐transplantation, one patient each died in the ECMO and in the non‐ECMO group. At the end of the study, six of seven ECMO cases were still alive (median survival 48.5 months); one patient required a retransplant at 53 months. Our small case series suggests that lung transplant procedures can be safely carried out in selected children on intra‐operative ECMO support; however, our pediatric experience regarding this scenario is very limited but probably almost unique.     

Liver and combined lung and liver transplantation for cystic fibrosis: analysis of the UNOS database

A proportion of patients with CF develop cirrhosis and portal hypertension. LT and combined LLT are rarely performed in patients with CF. To determine the outcome of LT and LLT in patients with CF. Patients with CF who had LT or LLT between 10/1987 and 5/2008 were identified from UNOS database. A total of 182 children (<18 yr) and 48 adults underwent isolated LT for CF. Seven more children and eight adults with CF underwent combined LLT. One- and five-yr patient and graft survival were not significantly different in patients who underwent LT in comparison with patients who underwent LLT (patient survival: LT; 83.9%, 75.7%, LLT; 80%, 80%; graft survival: LT; 76.1%, 67.0%, LLT; 80.0%, 80.0%, respectively). The two major causes of death after LT were pulmonary disease (15 patients, 22.7%) and hemorrhage (12 patients, 18.2%). Bilirubin was identified as a risk factor for death, and previous liver transplant and prolonged cold ischemic time were identified as risk factors for graft loss in LT patients. LT is a viable option for children and young adults with CF and end-stage liver disease. Outcome of LLT patients with CF was comparable to the outcome of patients with CF who underwent isolated LT.     

Size‐reduced lung transplantation in children – an option worth to consider!

Benden C, Inci I, Weder W, Boehler A. Size‐reduced lung transplantation in children – an option worth to consider!
Pediatr Transplantation 2010: 14:529–533. © 2009 John Wiley & Sons A/S. Abstract: Lung transplantation is an accepted therapy for pediatric end‐stage lung disease. However, there is a shortage of suitable donor organs. Therefore, the use of downsized lung allografts seems a valuable option. We report our experience of downsized pediatric lung transplantation in comparison with standard full‐size pediatric lung transplantation over one decade. Pediatric recipients undergoing downsized or standard lung transplantation were included (January 1997–December 2006). We compared pretransplant clinical data and surgical and post‐operative complications and post‐transplant outcome. Ten pediatric lung transplants were performed (median patient age 15.6 yr [12.3–17.8]). Nine of 10 patients had CF. Five patients underwent standard full‐size lung transplantation; five had downsized lung transplants. “Downsized” recipients had significantly lower median height and weight Z‐scores. Donor/recipient length difference was significantly greater in the “Downsized” Group (p < 0.05). All patients had comparable post‐transplant functional outcome without additional surgical complications or morbidities in “downsized” recipients. Median post‐transplant survival was 65 months (5–77) in the “Standard” Group compared to 86 months (64–121) in the “Downsized” Group (p = 0.1). Our data suggest that downsized lung transplantation in pediatric recipients may have post‐transplant outcomes comparable to full‐size lung transplantation without significant complications.     

Clostridium difficile colitis in children following lung transplantation

Rosen JB, Schecter MG, Heinle JS, McKenzie ED, Morales DL, Dishop MK, Danziger‐Isakov L, Mallory GB, Elidemir O. Clostridium difficile colitis in children following lung transplantation.
Pediatr Transplantation 2010: 14:651–656. © 2010 John Wiley & Sons A/S. Abstract: Risk factors for Clostridium difficile diarrhea are antibiotic exposure, hospitalization, extreme ages, and immunodeficiency. Patients with CF have a high rate of colonization with C. difficile. We performed a retrospective chart review of patients at Texas Children’s Hospital who underwent lung transplantation since the inception of our program in October 2002 until October 2008. There were 78 pediatric lung transplants performed at our institution during the study period. Four patients developed six total episodes of CDC for an overall incidence of 5.4%. CF was the underlying diagnosis in all four patients, leading to an incidence of 8.9% in patients with CF. Two patients developed colitis within the first four months following transplant, and the other two patients developed colitis more than three yr after transplantation. All four patients required hospitalization, and three patients were managed medically while one patient underwent diverting ileostomy. One experienced renal insufficiency and subsequently expired. Overall survival was 75% among patients with CDC following lung transplantation. CDC causes significant morbidity and mortality in children with CF who have undergone lung transplantation.     

Kidney and liver transplantation in children with fibrocystic liver–kidney disease: Data from the US Scientific Registry of Transplant Recipients: 1990–2010

The natural history and survival of children with fibrocystic liver–kidney disease undergoing solid organ transplantation have infrequently been described. We report outcomes in a cohort of US children with fibrocystic liver–kidney disease receiving solid organ transplants over 20 yr. Retrospective cohort study of pediatric transplant recipients with diagnoses of fibrocystic liver–kidney disease from 1/1990 to 3/2010, using data from the SRTR. Subjects were categorized by the first transplanted organ: LT, KT, or SLK. Primary outcomes were death, re‐transplant, transplant of the alternate organ, or initiation of dialysis. Seven hundred and sixteen subjects were transplanted in this period. Median age at first transplant was 9.7 yr. Of the LT, 14 (19%) required a second liver transplant at median of 0.2 yr, and five (7%) required kidney transplant or dialysis at a median of 9.0 yr. Of the KT, 188 (31%) required a second kidney transplant or dialysis at a median of 5.9 yr. Twenty‐nine (5%) subsequently received liver transplant at a median of 6.0 yr. Among patients in this registry, far more children underwent kidney than liver transplants. The risk of subsequently needing transplantation of an alternate organ was low.     

Impact of center volume and the adoption of laparoscopic donor nephrectomy on outcomes in pediatric kidney transplantation

Reports for pediatric kidney transplant recipients suggested better outcomes for ODN compared to LDN. Contemporary outcomes stratified by donor type and center volume have not been evaluated in a national dataset. UNOS data (2000‐2014) were analyzed for pediatric living donor kidney transplant recipients. The primary outcome was GF; secondary outcomes were DGF, rejection, and patient survival. Live donor nephrectomies for pediatric recipients decreased 30% and transitioned from ODN to LDN. GF rates did not differ for ODN vs LDN (P = .24). GF was lowest at high volume centers (P < .01). Donor operative approach did not contribute to GF. LDN was associated with less rejection than ODN (OR 0.66, CI 0.5‐0.87, P < .01). Analysis of the 0‐ to 5‐yr recipient group showed no effect of ODN vs LDN on GF or rejection. For the contemporary era, there was no association between DGF and LDN in the 0‐ to 5‐yr group (OR 1.12, CI 0.67‐1.89, P = .67). Outcomes of kidney transplants in pediatric recipients following LDN have improved since its introduction and LDN should be the approach for live donor nephrectomy regardless of recipient age. The association between case volume and improved outcomes highlights future challenges in organ transplantation.