Growth of long-term survivors of liver transplantation

Prevalence and Associated Factors of Vertebral Fractures in Children with Chronic Liver Disease with and without Liver Transplantation

Purpose

To evaluate the prevalence of vertebral fracture (VF) in children with chronic liver disease (CLD) with and without liver transplantation (LT) and to determine the associated factors.

Methods

A cross-sectional study was conducted. Patients aged 3-21 years with CLD both before and after LT were enrolled in the study. Lateral thoracolumbar spine radiographs were obtained and assessed for VF using Mäkitie's method. Clinical and biochemical data were collected.

Results

We enrolled 147 patients (80 females; median age 8.8 years [interquartile range 6.0-11.8]; 110 [74.8%] in the LT group and 37 [25.2%] in the non-LT group). VF was identified in 21 patients (14.3%): 17/110 (15.5%) in the LT group and 4/37 (10.8%) in the non-LT group (p=0.54). Back pain was noted in only three patients with VF. In the univariate analysis, a height z-score below -2.0 (p=0.010), pre-LT hepatopulmonary syndrome (p=0.014), elevated serum direct and total bilirubin levels (p=0.037 and p=0.049, respectively), and vitamin D deficiency at 1-year post-LT (p=0.048) were associated with VF in the LT group. In multivariate analysis, height z-score below -2.0 was the only significant associated factor (odds ratio, 5.94; 95% confidence interval, 1.49-23.76; p=0.012) for VF. All VFs in the non-LT group were reported in males.

Conclusion

In children with CLD, VF is common before and after LT. Most patients with VF are asymptomatic. Screening for VF should be considered in patients with a height z-score below -2.0 after LT.

Sexual and reproductive health screening and counseling in adolescent and young adult transplant recipients

Adolescents and young adults with and without chronic illnesses partake in risk-taking behavior. Clinicians in transplant clinics should be aware of the prevalence of risk-taking behavior in their adolescent and young adult solid organ transplant patients in order to provide complete care. Creating an environment where teens and young adults feel comfortable discussing risky behavior is important and includes creating a privacy policy and increasing comfort of the healthcare provider in asking sensitive questions. This review is intended to help the providers in the transplant clinic screen for and counsel about risk-taking behaviors with their adolescent and young adult patients, specifically around sexual and reproductive health.

Long-term Catch-up Growth and Risk Factors for Short Adult Height After Pediatric Liver Transplantation: A Retrospective Study

BACKGROUND

Children requiring liver transplantation generally have severe growth retardation. Recipients experience posttransplantation catch-up growth, although some show short adult heights. We aimed to determine decades-long catch-up growth trends and risk factors for short adult height following liver transplantation.

METHODS

We analyzed long-term height Z scores and risk factors for short adult height in a single-center retrospective cohort of 117 pediatric liver transplantation recipients who survived >5 y, with 75 of them reaching adult height.

RESULTS

Median age at transplantation was 1.3 y, and the most common primary diagnosis was biliary atresia (76.9%). Mean height Z scores pretransplantation and 1, 3, and 8 y after transplantation were -2.26, -1.59, -0.91, and -0.59, respectively. The data then plateaued until 20 y posttransplantation when mean adult height Z score became -0.88, with a median follow-up of 18.6 y. Nineteen recipients did not show any catch-up growth, and one quarter of recipients had short adult height (<5th percentile of the healthy population). Multivariate analysis identified old age (odds ratio, 1.22 by 1 y; P = 0.002), low height Z scores at transplantation (odds ratio, 0.46 by 1 point; P < 0.001), and posttransplantation hospital stay ≥60 d (odds ratio, 4.95; P = 0.015) as risk factors for short adult height. In contrast, prolonged steroid use after transplantation was not considered a significant risk factor.

CONCLUSIONS

Although tremendous posttransplantation catch-up growth was observed, final adult height remained inadequate. For healthy physical growth, liver transplantation should be performed as early as possible, before growth retardation becomes severe.

Everolimus and reduced calcineurin inhibitor therapy in pediatric liver transplant recipients: Results from a multicenter, prospective study

In a 24-month, multicenter, single-arm, prospective study, 56 pediatric liver transplant patients with or without basiliximab induction were converted at 1-6 months post-transplant from standard calcineurin inhibitor (CN) therapy (± mycophenolic acid), to everolimus with reduced exposure to CNI (tacrolimus n=50, cyclosporine n=6). Steroid therapy was optional. Recruitment was stopped prematurely due to high rates of PTLD, treatment-related serious infections leading to hospitalization and premature study drug discontinuation. Subsequently, patients aged <7 years reverted to local standard-of-care immunosuppression. Mean tacrolimus concentration was above or near the upper end of the maintenance target range (2-5 ng/mL) until after month 6 post-enrollment. The primary variable, mean (SD) change in eGFR from baseline to month 12 (last observation carried forward), was +6.2 (19.5) mL/min/1.73 m² . Two patients experienced treated biopsy-proven acute rejection. No graft losses or deaths occurred. PTLD occurred in five patients (8.9%) (3/25 [12.0%] patients <2 years, 2/31 aged 2-18 years [6.5%]). Adverse events, serious adverse events, and discontinuation due to adverse events were reported in 100.0%, 76.8%, and 44.6% of patients, respectively. In conclusion, everolimus with reduced CNI improved renal function while maintaining antirejection potency in pediatric liver transplant patients but safety outcomes suggest that patients were overimmunosuppressed.

Post-transplant adjustment--the later years

As survival rates for pediatric solid organ transplantation have continued to improve, researchers and healthcare providers have increasingly focused on understanding and enhancing the HRQOL and psychosocial functioning of their patients. This manuscript reviews the psychosocial functioning of pediatric transplant recipients during the "later years," defined as more than three yr post-transplant, and focuses on the day-to-day impact of living with a transplant after the immediate period of adjustment and early years after surgery. Key topics reviewed include HRQOL, cognitive functioning, impact on the family, regimen adherence, and transition of responsibility for self-management tasks. Overall, pediatric transplant recipients evidence impairment in HRQOL, neuropsychological outcomes, and family functioning as compared to non-transplant recipients. However, the degree of impairment is influenced by a variety of factors including, disease severity, age, solid organ type, and study methodologies. Studies are limited by small samples, cross-sectional design, and the lack of universal assessment battery to allow for comparisons across solid organ populations. Areas for future research are discussed.

The role of everolimus in liver transplantation

During the last 5 decades, liver transplantation has witnessed rapid development in terms of both technical and pharmacologic advances. Since their discovery, calcineurin inhibitors (CNIs) have remained the standard of care for immunosuppression therapy in liver transplantation, improving both patient and graft survival. However, adverse events, particularly posttransplant nephrotoxicity, associated with long-term CNI use have necessitated the development of alternate treatment approaches. These include combination therapy with a CNI and the inosine monophosphate dehydrogenase inhibitor mycophenolic acid and use of mammalian target of rapamycin (mTOR) inhibitors. Everolimus, a 40-O-(2-hydroxyethyl) derivative of mTOR inhibitor sirolimus, has a distinct pharmacokinetic profile. Several studies have assessed the role of everolimus in liver transplant recipients in combination with CNI reduction or as a CNI withdrawal strategy. The efficacy of everolimus-based immunosuppressive therapy has been demonstrated in both de novo and maintenance liver transplant recipients. A pivotal study in 719 de novo liver transplant recipients formed the basis of the recent approval of everolimus in combination with steroids and reduced-dose tacrolimus in liver transplantation. In this study, everolimus introduced at 30 days posttransplantation in combination with reduced-dose tacrolimus (exposure reduced by 39%) showed comparable efficacy (composite efficacy failure rate of treated biopsy-proven acute rejection, graft loss, or death) and achieved superior renal function as early as month 1 and maintained it over 2 years versus standard exposure tacrolimus. This review provides an overview of the efficacy and safety of everolimus-based regimens in liver transplantation in the de novo and maintenance settings, as well as in special populations such as patients with hepatocellular carcinoma recurrence, hepatitis C virus-positive patients, and pediatric transplant recipients. We also provide an overview of ongoing studies and discuss potential expansion of the role for everolimus in these settings.

Long-term linear growth and puberty in pediatric liver transplant recipients

OBJECTIVE

To explore linear growth, puberty, and predictors of linear growth impairment among pubertal liver transplant recipients.

STUDY DESIGN

Review of data collected prospectively through the Studies of Pediatric Liver Transplantation registry. Thirty-one variables were tested as risk factors for linear growth impairment, and factors significant at P < .1 were included in a logistic regression model. Risk factor analysis was limited to 512 patients who had complete demographic and medical data.

RESULTS

A total of 892 patients surviving their first liver transplant by >1 year, with ≥ 1 height recorded, who were between 8 and 18 years old between the years 2005 and 2009 were included. Median follow-up was 70.2 ± 38.6 months, mean age was 12.9 ± 3.3 years, and mean height z-score (zH) was -0.5 ± 1.4 SD. Twenty percent had linear growth impairment at last follow-up. Of 353 subjects with Tanner stage data, 39% of girls and 42% of boys ages 16-18 years were not yet Tanner 5. Growth impairment rates were higher among boys than girls (30% vs 7%, P < .05) at Tanner stage 4, and occurred in 8/72 (11%) of Tanner 5 subjects. Among patients with parental height data, zH were lower than calculated mid-parental zH (P < .005). Independent predictors of growth impairment included linear growth impairment at transplant (OR 11.53, P ≤ .0001), re-transplantation (OR 4.37, P = .001), non-white race (P = .0026), and primary diagnosis other than biliary atresia (P = .0105).

CONCLUSIONS

Linear growth impairment and delayed puberty are common in pubertal liver transplant recipients, with pre-transplant growth impairment identified as a potentially modifiable risk factor. Catch-up growth by the end of puberty may be incomplete.

Long-term growth and anthropometry after childhood liver transplantation

OBJECTIVES

To describe longitudinal height, weight, and body mass index changes up to 15 years after childhood liver transplantation.

STUDY DESIGN

Retrospective chart review of patients who underwent liver transplant from 1985-2004 was performed. Subjects were age <18 years at transplant, survived ≥5 years, with at least 2 recorded measurements, of which one was ≥5 years post-transplant. Measurements were recorded pre-transplant, 1, 5, 10, and 15 years later.

RESULTS

Height and weight data were available in 98 and 104 patients, respectively; 47% were age <2 years at transplant; 58% were Australian, and the rest were from Japan. Height recovery continued for at least 10 years to reach the 26th percentile (Z-score -0.67) 15 years after transplant. Australians had better growth recovery and attained 47th percentile (Z-score -0.06) at 15 years. Weight recovery was most marked in the first year and continued for 15 years even in well-nourished children. Growth impaired and malnourished children at transplant exhibited the best growth, but remained significantly shorter and lighter even 15 years later. No effect of sex or age at transplant was noted on height or weight recovery. Post-transplant factors significantly impact growth recovery and likely caused the dichotomous growth recovery between Australian and Japanese children; 9% (9/98) of patients were overweight on body mass index calculations at 10-15 years but none were obese.

CONCLUSIONS

After liver transplant, children can expect ongoing height and weight recovery for at least 10-15 years. Growth impairment at transplant and post-transplant care significantly impact long-term growth recovery.

Endocrine and bone metabolic complications in chronic liver disease and after liver transplantation in children

With improved survival of orthotopic liver transplantation (OLT) in children, prevention and treatment of pre- and posttransplant complications have become a major focus of care. End-stage liver failure can cause endocrine complications such as growth failure and hepatic osteodystrophy, and, like other chronic illnesses, also pubertal delay, relative adrenal insufficiency, and the sick euthyroid syndrome. Drug-induced diabetes mellitus post-OLT affects approximately 10% of children. Growth failure is found in 60% of children assessed for OLT. Despite optimisation of nutrition, rarely can further stunting of growth before OLT be prevented. Catch-up growth is usually observed after steroid weaning from 18 months post-OLT. Whether growth hormone treatment would benefit the 20% of children who fail to catch up in height requires testing in randomised controlled trials. Hepatic osteodystrophy in children comprises vitamin D deficiency rickets, low bone mass, and fractures caused by malnutrition and malabsorption. Vitamin D deficiency requires aggressive treatment with ergocalciferol (D2) or cholecalciferol (D3). The active vitamin D metabolites alphacalcidol or calcitriol increase gut calcium absorption but do not replace vitamin D stores. Prevalence of fractures is increased both before OLT (10%-28% of children) and after OLT (12%-38%). Most fractures are vertebral, are associated with low spine bone mineral density, and frequently occur asymptomatically, but they may also cause chronic pain. Fracture prediction in these children is limited. OLT in children is also associated with a greater risk of developing avascular bone necrosis (4%) and scoliosis (13%-38%). This article reviews the literature on endocrine and skeletal complications of liver disease and presents preventive screening recommendations and therapeutic strategies.

Evaluation of growth after liver transplantation in Turkish children

AIMS

Currently, the main interest in childhood liver transplantation (LT) is to prevent long-term complications and optimize growth. The aim of this study is to analyze (1) nutritional status in the pretransplantation period, and (2) posttransplantation growth and associated factors in children.

PATIENTS AND METHODS

Eighty children were included in the study. Height (Z (H)) and weight (Z (W)) Z scores were calculated before transplantation and postoperatively at the 6th month and 1st, 2nd, 3rd, 4th, and 5th year.

RESULTS

Patients' Z (H) and Z (W) scores at LT were -1.6 ± 1.3 and -1.5 ± 1.4, respectively. Both Z (H) and Z (W) scores increased after LT, especially in the first 6 months, and then continued to rise gradually. Both reached beyond -1 Z score at 2nd year and -0.5 at 4th year. Age, primary diagnosis, total steroid dose (<1,000 mg), and absence of rejection episodes had positive impact on posttransplantation growth, whereas gender, immunosuppression type, surgical complications, and presence of tumor had no impact on posttransplantation growth. Age at time of LT was negatively correlated with Z (W) score at 5th year (P = 0.02, r = -0.43). Both Z (W) and Z (H) scores at time of LT were positively correlated with Z (W) and Z (H) scores and negatively correlated with ∆Z (W) and ∆Z (H) scores at 5th year.

CONCLUSIONS

LT is not only a modern, life-saving treatment technique but also an efficient method of facilitating growth, an indispensable component of childhood and the best indicator of health.

Immunosuppression in pediatric liver transplantation: are little people different?

1. Children differ from adults in the pharmacokinetics and dynamics of most immunosuppressive agents. 2. A lack of clinical trials continues to be an issue for newer agents. 3. On the basis of clinical case series, mycophenolate mofetil and sirolimus are increasingly being used as renal-sparing agents. 4. In comparison with adults, the recurrence of both viral hepatitis and hepatocellular carcinoma is less of an issue in children. 5. Particular attention should be paid to complete age-appropriate immunization to avoid vaccine-preventable diseases. 6. Paying special attention to adherence and the transition to adult services is essential for minimizing graft loss.

Approach to optimizing growth, rehabilitation, and neurodevelopmental outcomes in children after solid-organ transplantation

One of the most critical differences between the posttransplant care of children and adults is the requirement in children to maintain a state of health that supports normal physical and psychological growth and development. Most children with organ failure have some degree of growth failure and developmental delay, which is not quickly reversed after successful transplantation. The challenge for clinicians caring for these children is to use strategies that minimize these deficits before transplantation and provide maximal opportunity for recovery of normal developmental processes during posttransplant rehabilitation. The effect of chronic organ failure, frequently complicated by malnutrition, on growth potential and cognitive development is poorly understood. This review presents a summary of what is known regarding risk factors for suboptimal growth and development following solid-organ transplant and describe possible strategies to improve these outcomes.

Clinical practice: management of biliary atresia

Biliary atresia is a rare, serious and challenging disease in newborn children. Its aetiology remains unknown. Optimal management at specialist centres with resultant better overall outcomes is achieved through a multidisciplinary team approach. The Kasai portoenterostomy performed early in life remains the only surgical repair procedure. Two thirds of patients will clear their jaundice after a Kasai procedure, but only about one third will retain their livers after the first decade of life. Failure of this procedure leaves liver transplantation as the only chance for survival, and this disease is the commonest indication for liver transplantation in children. With modern medical care and refinements in surgical techniques, survival after either or both of these procedures is about 90%. Early referral to specialist centres and long-term specialist care remains the key to successful treatment of this condition.

Linear growth patterns in prepubertal children following liver transplantation

Factors impacting linear growth following pediatric liver transplantation (LT) are not well understood. This longitudinal analysis examines predictors of linear growth impairment in prepubertal children included in Studies of Pediatric Liver Transplantation. In 1143 children with serial measurements, mean height scores increased from -1.55 at LT to -0.87 and -0.68 at 24 and 36 months post LT with minimal subsequent catch up growth observed until 60 months. Subgroup analysis of height measurements at 24 months (n = 696), 33.8% were below 10th percentile at 24 months post LT. Multivariate analysis revealed linear growth impairment more likely in patients with metabolic disease (OR 4.4, CI: 1.83-10.59) and >18 months of steroids exposure (OR 3.02, CI: 1.39-6.55). Higher percentiles for weight (OR 0.80, CI: 0.65-0.99) and height (OR 0.62, CI: 0.51-0.77) at LT decreased risk. Less linear catch up was observed in patients with metabolic disease, non-Biliary atresia cholestatic diseases and lower weight and higher height percentiles prior to LT. Prolonged steroid exposure and elevated calculated glomerular filtration rate and gamma-Glutamyltransferase following LT were associated with less catch up growth. Linear growth impairment and incomplete linear catch up growth are common following LT and may improve by avoiding advanced growth failure before LT and steroid exposure minimization.

Corticosteroids usage in pediatric liver transplantation: To be or not to be!

The theoretical risks of early SW, <3 months post-LT, and complete elimination (steroid-free LT) lie in mainly three areas, namely the risks of AGR, CGR, and the development of d-AIH that has been described in SW post-LT in children. These should be balanced against the benefits of early SW mainly manifested as effects on growth post-LT. In this paper, we focused on the clinical trials that included CS therapy risks and benefits in pediatric LT. Focusing mainly on CGR and d-AIH as risks, and the beneficial effects on growth post-LT with either low-dose CS, SW, or steroid-free regimens. Main conclusions from comparing a large number of studies are: early SW or elimination from immunosuppression protocols was neither harmful to the patient nor to the graft survival rate in the short term, the overall impression is that steroids negatively affect growth in LT recipients when used in high doses and prolonged course, and that development of d-AIH is not associated with CS therapy with evidence that chronic low dose steroids post-LT have no preventative role against d-AIH.

Pediatric liver transplantation

In previous decades, pediatric liver transplantation has become a state-of-the-art operation with excellent success and limited mortality. Graft and patient survival have continued to improve as a result of improvements in medical, surgical and anesthetic management, organ availability, immunosuppression, and identification and treatment of postoperative complications. The utilization of split-liver grafts and living-related donors has provided more organs for pediatric patients. Newer immunosuppression regimens, including induction therapy, have had a significant impact on graft and patient survival. Future developments of pediatric liver transplantation will deal with long-term follow-up, with prevention of immunosuppression-related complications and promotion of as normal growth as possible. This review describes the state-of-the-art in pediatric liver transplantation.

[Nutritional risk and malnutrition determination by anthropometry in cirrhotic children and adolescents]

BACKGROUND

The malnutrition is a frequent finding in adults with cirrhosis, but the prevalence of nutritional risk and malnutrition is little known in pediatric patients.

AIM

To evaluate through anthropometry the presence of nutritional risk and malnutrition in cirrhotic pediatric patients regularly attended at the Pediatric Gastroenterology Service of "Hospital de Clínicas" of Porto Alegre, RS, Brazil.

METHODS

Cross-sectional study with 42 cirrhotic children and adolescents aged between 3 months and 18 years. The nutritional evaluation was made by the determination of the weight/age, height/age, body mass index and triceps skinfold thickness and arm muscle circumference measurements. Patients considered in nutritional risk were < or = -1,28 Z score which corresponds to < or = 10th percentile, and those under -2,0 Z and < or = 3th percentile were in malnutrition status. According to Child-Pugh criteria, 22 patients were classified as A (mild severity), 15 (moderate) B and 5 C (intense).

RESULTS

The mean weight/age, height/age and body mass index Z scores were, respectively, - 0,38 +/- 1,4 SD, - 0,83 +/- 1,16 SD and 0,17 +/- 1,3 SD. Patients in nutritional risk were 3/42 (weight/age), 8/42 (height/age), 12/37 (triceps skinfold thickness), 9/37 (arm muscle circumference), 2/38 (body mass index); in malnutrition status were 6/42 (weight/age), 7/42 (height/age), 4/37 (triceps skinfold thickness) and 4/37 (arm muscle circumference) and 3/38 (body mass index).

CONCLUSION

The prevalence of nutritional risk was 32.4% and chronic malnutrition was 16.7%. The index which better reflected the nutritional risk in these patients was triceps skinfold thickness. Chronic malnutrition status occurrence was greater in the height/age index.

Outcomes of 5-year survivors of pediatric liver transplantation: report on 461 children from a north american multicenter registry

OBJECTIVES

Although liver transplantation has been the standard of care therapy for life-threatening liver diseases for >20 years, data on the long-term impact of liver transplantation in children have been primarily limited to single-center experiences. The objective of this study was to characterize and evaluate the clinical course of children who have survived >or=5 years after pediatric liver transplantation in multiple centers across North America.

PATIENTS AND METHODS

Patients enrolled in the Studies of Pediatric Liver Transplantation database registry who had undergone liver transplantation at 1 of 45 pediatric centers between 1996 and 2001 and survived >5 years from liver transplantation were identified and their clinical courses retrospectively reviewed.

RESULTS

The first graft survival for 461 five-year survivors was 88%, with 55 (12%) and 10 (2%) children undergoing a second and third liver transplantation. At the 5-year anniversary clinic visit, liver function was preserved in the majority with daily use of immunosuppression therapy, including a calcineurin inhibitor and oral prednisone, reported by 97% and 25% of children, respectively. The probability of an episode of acute cellular rejection occurring within 5 years after liver transplantation was 60%. Chronic rejection occurred in 5% patients. Posttransplant lymphoproliferative disease was diagnosed in 6% children. Calculated glomerular filtration rate was <90 mL/minute per 1.73 m2 in 13% of 5-year survivors. Age- and gender-adjusted BMI>95th percentile was noted in 12%, with height below the 10th percentile in 29%.

CONCLUSIONS

Children who are 5-year survivors of liver transplantation have good graft function, but chronic medical conditions and posttransplantation complications affect extrahepatic organs. A comprehensive approach to the management of these patients' multiple unique needs requires the expertise and commitment of health care providers both beyond and within transplant centers to further optimize long-term outcomes for pediatric liver transplant recipients.

Downward percentile crossing as an indicator of an adverse prenatal environment

BACKGROUND

Postnatal health sequelae of low birth weight have been attributed to 'poor fetal growth' from inferred adverse prenatal environments; risks augmented by infant growth rates. Identifying prenatal growth-restricting events is essential to clarify pathways and mechanisms of fetal growth.

AIM

The specific aim of this investigation was to examine whether an episode of preterm labor may compromise fetal growth.

SUBJECTS AND METHODS

Fetal size at the end of the second trimester and birth were compared among women with uncomplicated pregnancies (n = 3167) and those who experienced an episode of preterm labor (<37 weeks) and subsequently delivered at term (> or =37 weeks, n = 147). Fetal weight estimated from ultrasound measures, and changes in weight standard scores across the third trimester investigated significant centile crossing (>0.67 standard deviation score change).

RESULTS

Fetuses delivered at term after an episode of preterm labor were smaller at birth relative to their peers than at the end of the second trimester, and were 47% more likely to experience clinically significant downward centile crossing (p < 0.05) than their peers (OR 1.47, 95% CI 1.04-2.07).

CONCLUSION

An episode of preterm labor may signal an adverse prenatal environment for term-delivered neonates. Epidemiologically silent events in the natural history of pregnancy are an understudied source of fetal growth compromise as inferred by small birth size among peers.

Growth and final height after liver transplantation during childhood

OBJECTIVE

To evaluate the effect of end-stage pediatric liver disease and liver transplantation on growth and final height.

PATIENTS AND METHODS

We evaluated growth at 2 years (n = 101) and 5 years (n = 63) after pediatric liver transplantation (LTx). Twenty-three children reached final height. Height was expressed as a standard deviation score of the target height (zTH score) of each patient.

RESULTS

At the first 2 years after LTx, the zTH score was significantly increased from -1.7 to -1.3 SD (P < 0.05). Growth at 2 or 5 years after LTx, expressed as DeltazTH score, was positively correlated with pretransplant growth retardation (P < 0.05). In comparison with patients with noncholestatic primary liver disease, patients with cholestatic primary liver disease were more severely growth retarded before LTx (zTH score -2.0 vs -1.2 SD, P < 0.05) and had better growth in the first 2 years after LTx (DeltazTH score +0.6 vs -0.1 SD, P < 0.05). Twelve of the 23 patients had a final height below -1.3 SD of their target height.

CONCLUSIONS

Growth retardation is common in children before LTx, particularly in children with an underlying cholestatic disease. After LTx, catch-up growth was partial and was prominent only in cholestatic children who had been severely growth retarded before LTx. After LTx during childhood, approximately 50% of patients reach a final height lower than -1.3 SD of their genetic potential.

Fertility and reproductive disorders in female solid organ transplant recipients

Solid organ transplantation can prolong the life of individuals with end-stage diseases that affect the kidney, liver, lung, heart, and pancreas. The improved survival of transplant recipients has led to increased attention on quality of life issues, including controlling fertility and having children. Perturbations of the hypothalamic-pituitary-ovarian axis in women with chronic renal failure or severe hepatic dysfunction result in anovulation and reduced fertility. Most often, fertility is restored with successful organ transplantation and good overall health. Although there are case reports of children born subsequent to assisted reproductive technologies (ART) in female transplant recipients, the approach to infertility in this population has not been described. Recognizing the unique medical, ethical, and psycho-social concerns involved in treating infertile female transplant recipients, reproductive endocrinologists must work with a multi-disciplinary team to ensure a successful pregnancy outcome without compromising graft function or maternal health. The primary goal of ART is a singleton pregnancy without complications, such as ovarian hyperstimulation syndrome, that pose greater risks in transplant recipients.

Developmental and reproductive health issues in adolescent solid organ transplant recipients

The improved survival of pediatric recipients of solid organ transplants has prompted increased attention to quality of life issues. In adolescents these include attainment of normal growth and development, and involvement in romantic and sexual relationships. This review focuses on the reproductive health care needs of adolescent solid organ transplant recipients, including issues related to puberty, menstruation, and fertility. Contraceptive options, and the implications of their use by transplant recipients, are described. With close clinical follow up, most currently available hormonal contraceptive methods can be considered, and the impact of drug interactions with immunosuppressants can be minimized by eliminating hormone-free intervals. Monitoring for sexually transmitted infections, including oncogenic Human Papilloma Virus and its sequelae, is especially important for transplant recipients. Comprehensive reproductive health care visits are recommended for all sexually active adolescent solid organ transplant recipients.

Randomized trial of basiliximab induction versus steroid therapy in pediatric liver allograft recipients under tacrolimus immunosuppression

Avoidance of corticosteroids could be beneficial after pediatric liver transplantation (LTx). To test this hypothesis, we performed a randomized prospective study to compare immunosuppression with tacrolimus (TAC) and steroids versus TAC and basiliximab (BAS) after pediatric LTx. Seventy-two patients were recruited, 36 receiving TAC and steroids and 36 TAC and BAS. The primary endpoint was the occurrence of the first rejection episode. Secondary endpoints were the cumulative incidence and severity of rejection, patient and graft survival, and incidence of adverse events. Overall 1-year patient and graft survival rates were 91.4% and 85.5% in the steroid group, and 88.6% and 80% in the BAS group (p = NS). Patients free from rejection were 87.7% in the BAS group and 67.7% in the steroid group (p = 0.036). The use of BAS was associated with a 63.6% reduction in incidence of acute rejection episodes. Overall incidence of infection was 72.3% in the steroid group and 50% in the BAS group (p = 0.035). We conclude that the combination of TAC with BAS is an alternative to TAC and steroid immunosuppression in pediatric LTx, which allows for a significant reduction in the incidence of acute rejection and infectious complications.

Liver transplantation in children: part 2--long-term issues

This two-part review provides a comprehensive summary of clinical and research literature on paediatric liver transplantation. Part 2 focuses on the long-term physical consequences and psychological impact of transplantation and critically examines neurobehavioural, sexual development, psychosocial function and overall impact on children's quality of life. This review highlights the implications for clinical practice in specialist and local services and suggests areas where research is required to improve the lives of children after liver transplantation.

Long-term growth of pediatric patients following living-donor liver transplantation

In order to determine the influence of living donor liver transplantation (LDLT) on long-term growth, we studied the progress of 36 children who had survived more than 5 yr after LDLT from 1994 to 1999. The median age at the transplantation was 1.5 yr (range: 6 months-15 yr) and the median follow-up period was 6.5 yr (range: 5-9 yr). A height standard deviation score (zH) was analyzed for each patient according to medical records. Significant catch-up growth occurred within 2 yr after LDLT with a mean zH changing from -1.2 to 0.0 and was maintained for up to 7 yr post-transplantation (zH-0.1). Younger children (<2 yr) were more growth-retarded at the time of LDLT, but showed higher catch-up growth rates and their final zH was greater than that of older children. Children with liver cirrhosis were more growth-retarded at the time of LDLT, but showed significant catch-up growth and their final height was similar to children with fulminant hepatitis. Growth in children who experienced significant hepatic dysfunction after LDLT was not significantly different from those without graft dysfunction. There was no difference between the types of immunosuppressants used. Our finding suggests that LDLT can result in adequate catchup linear growth, and this effect can persist even after 7 yr post-transplantation.

Post-transplantation growth among pediatric recipients of liver transplantation

Improving a patient's quality-of-life (QOL) post-liver transplantation is of great importance. An aspect of improved QOL is the restoration of normal growth patterns in pediatric patients. To describe the post-transplantation growth patterns of 72 children included in the National Institute of Diabetes and Digestive and Kidney Diseases - Liver Transplantation Database (NIDDK-LTD), multilevel models were used, according to which children who waited more than a year for transplantation were smaller, compared with age and sex matched peers, at transplantation than children who waited less than a year while children who were growth retarded at transplantation experienced a larger yearly comparison height increase than children who were not growth retarded. The analysis also showed that boys older than 2 yr and younger than 13 yr at transplantation and girls older than 2 yr and younger than 11 yr at transplantation were significantly less growth retarded at transplantation than boys and girls under the age of 2 yr at transplantation.

Gynecologic health care for the adolescent solid organ transplant recipient

The improved survival of pediatric recipients of solid organ transplants has prompted increased attention to quality of life issues. These include attainment of normal growth, involvement in romantic relationships, and the desire to control fertility. As an increasing number of adolescent transplant recipients are involved in normal social and sexual relationships, they require careful attention to their gynecologic and reproductive health care needs. Anticipating the onset of sexual activity before it occurs may help to prevent a mistimed pregnancy by providing or prescribing condoms and emergency contraception in advance. In addition, many transplant recipients can safely use the currently available methods of hormonal contraception provided there is careful attention to organ function, other medical problems, and concurrently prescribed medications. In adolescent patients, issues such as pubertal development and menstruation, contraception, and routine gynecologic health care are typically addressed by the patient's primary care provider. However, the complexity of the adolescent transplant recipient's medical care necessitates close collaboration among all health care providers caring for the patient. This review is intended to help the transplant team better understand the gynecologic health care needs and treatment options of their adolescent patients.

Osseous complications of pediatric transplantation

Adult stature and peak bone mass are achieved through childhood growth and development. Multiple factors impair this process in children undergoing solid organ transplantation, including chronic illness, pretransplant osteodystrophy, use of medications with negative impact on bone, and post-transplant renal dysfunction. While growth delay and short stature remain common, the most severe forms of transplant-related bone disease, fracture and avascular necrosis, appear to have become less common in the pediatric age group. Osteopenia is very prevalent in adult transplant recipients and probably also in pediatrics, but its occurrence and sequelae are difficult to study in these groups due to methodological shortfalls of planar densitometry related to short stature and altered patterns of growth and development. Although the effect on lifetime peak bone mass is not clear, data from adult populations suggest an elevated long-term risk of bone disease in children receiving transplants. Optimal management of pretransplantation osteodystrophy, attention to post-transplant renal insufficiency among both renal and non-renal transplant patients, reduction of steroid dose in select patients, and supplementation with calcium plus vitamin D during expected periods of maximal bone loss may improve bone health. Careful research is required to determine the role of bisphosphonate therapy in pediatric transplantation.

Factors affecting catch-up growth after liver transplantation

BACKGROUND

The reported incidence of catch-up growth following orthotopic liver transplantation (OLT) ranges widely, from 0% to 97%.

OBJECTIVE

We undertook bivariate analysis of multiple factors that might affect post-OLT growth in children undergoing OLT, and described the results with different parameters used to determine catch-up growth.

METHODS

Eighty patients met the inclusion criteria.

RESULTS

Catch-up growth occurred in 14% during the first 6 months, 15% at 1 year, 39% at 2 years, 16% between 3 and 6 years, and 16% after 6 years post-OLT. The earlier catch-up growth was shown in metabolic diagnosis, patients over 10 years old and those without steroids at 1 year post-OLT.

CONCLUSIONS

It is difficult to determine an acceptable definition of catch-up growth. We suggest that Zvel score > or =0 is the best parameter to evaluate catch-up growth, since the results are more normally distributed. Patients with prednisone withdrawal later than 1 year post-OLT and those with diagnosis of hepatitis and cirrhosis showed the slowest catch-up growth.

Evaluation of catch-up growth after liver transplantation in children with biliary atresia

Orthotopic liver transplantation (Tx) has improved survival in infants with extrahepatic biliary atresia (BA) when portoenteroanastomosis fails. Symptoms leading to Tx include liver failure, poor quality of life and growth failure. The objective of the study was to determine catch-up growth in children with BA. Medical records and growth data of 36 patients (24 girls) who received a Tx due to BA were analyzed. Thirty-two patients completed 3 yr and 15 patients 7 yr of follow-up after Tx. At Tx, the median age was 2.7 yr (range 0.7-12.6) and mean height Z score (+/-s.d.) was -1.56 (+/-1.3). Patients were divided in two groups according to age at Tx: group I (n = 10), younger than 1.0 yr, and group II (n = 26) older than 1.0 yr. Median age (range) at Tx in group I was 0.8 yr (0.7-1.0) and in group II it was 3.35 yr (1.25-12.6). Thirteen patients (nine in group I) were receptors of living related donors. We evaluated linear growth, liver and renal function, immunosuppressive regimen and allograft rejection episodes. We did not find any significant differences in allograft or renal function, immunosuppressive therapy and number of acute rejection episodes or height Z score at Tx, second and third year post-Tx between both groups. The mean height Z score at Tx in group I was -1.61 and in group II -1.54; at the second year, group I -0.66 and group II -1.08; at the third year, group I -0.17 and group II -0.85; and at the seventh year (total group) -0.3. However, the height gain at the third year was better in group I than in group II (p < 0.01, t-test). Height Z score at the third year improved more than 1 SDS in seven out of eight patients in group I and in only nine out of 24 in group II (odds ratio 11.6). We also found a correlation between height gain at the third year and age at Tx (r-0.65) and between height gain at the third year and height Z score at Tx (r-0.54) (Pearson, p < 0.05). Children with BA who are transplanted before 12 months of age presented better catch-up growth without change survival and morbidity. Orthotopic liver Tx improves survival and also enables height gain in these children.

Growth and skeletal maturation after pediatric cardiac transplantation

To examine the effects of cardiac transplantation on skeletal maturation and linear growth, we retrospectively evaluated annual bone age determinations and growth parameters of pediatric cardiac transplant recipients followed at our center. Included in the analysis were records of 86 patients (32 females) who had received a cardiac transplant at our institution between 1984 and 1998. Bone age delay of > or =12 months was apparent in 38.5% at the time of transplantation. At some point in their post-transplant course, 23 patients (29%) had one or more bone age measurements that were > or =36 months delayed with respect to chronological age. Children transplanted before age seven and those with a pretransplantation diagnosis of cardiomyopathy experienced the most significant decrement in skeletal maturation after transplantation. High cyclosporin A levels and low body mass index were the only parameters found to be associated with delayed bone age. Although the majority of children grew at a normal rate after transplantation, height Z scores and height age were adversely affected regardless of the type of heart disease or the age at transplantation. The pathogenesis of both delayed skeletal maturation and growth retardation in this population warrant further investigation.

Pediatric transplantation of the kidney, liver and heart: summary report

The following is a summary report of an extensive review of the literature from 1966 to 2001 on growth and development in children receiving kidney, liver and heart transplants. The literature was assessed for relevancy to current clinical practice and for reliability and generalizability of the inferences based on the study design, controls, sample size, age distribution, confounding factors, use of standardized instruments, and consistency with other findings. While studies on growth are included in the review, the main emphasis is on research in cognitive and psychosocial development since these areas have been far less thoroughly studied and contain various methodological deficiencies. On the basis of the literature review both general methodological recommendations and specific recommendations for future research studies are made. Access to the full is provided on the World Wide Web at http://light.emmes.com/pedstransplantation/.

Gynecologic issues of the adolescent female solid organ transplant recipient

Advances in the field of transplant medicine are providing adolescent recipients with continual improvements in health and quality of life. With expanding opportunities for normal social and sexual relationships, adolescents require careful attention to their gynecologic and reproductive health (Box 1). Medical considerations vary depending on the type of organ transplanted, underlying and comorbid conditions, and current medication use. Most adolescent girls achieve menarche, however, and irregular cycles should be evaluated and managed with the same considerations applied to healthy young women. The management of menstrual disorders frequently uses hormonal contraceptive methods. Many transplant recipients also are sexually active and require a contraceptive method to prevent a mistimed pregnancy. With careful attention to organ function, other medical problems, and concurrently prescribed medications, many transplant recipients can use safely the currently available methods of hormonal contraception.

Steroid withdrawal after pediatric liver transplantation: a long-term follow-up study in 109 recipients

BACKGROUND

Steroids remain an important component of maintenance immunosuppression in liver transplantation, but when administered for a long period they may be associated with multiple severe side effects, particularly growth suppression in children. This study was conducted to clarify the balance of potential benefits and risks of steroid withdrawal (SW) in pediatric liver transplantation.

METHODS

Between April 1984 and July 2000, 109 pediatric recipients with SW and at least 12 months of follow-up after SW were retrospectively reviewed and divided into three groups according to the type of anticalcineurin at SW: group I (cyclosporine, n=25), group II (cyclosporine microemulsion, n=25), and group III (tacrolimus, n=59). Steroids were withdrawn after a three-step reduction of steroid dosage (taper down to the substitution dose of 0.25 mg/kg/day, switch to alternate-day therapy, progressive SW). Patients were regularly followed up for clinical and biochemical monitoring.

RESULTS

Median follow-up was 8.1 (range, 1.6-16.8) years. After SW, neither chronic rejection nor graft nor patient loss occurred. A trend toward lower anticalcineurin trough levels was observed in all groups. Glomerular filtration rate and fasting cholesterol were significantly better in group III (P<0.05). Median height z-score in all patients was -1.1 SD on alternate-day steroids versus -0.2 SD at the time of SW. Height z-score was slightly better in group III (NS). Early SW within 2 years after transplantation allowed a slightly better gain in growth.

CONCLUSIONS

SW in pediatric liver transplantation is safe and may be beneficial to height outcome. Tacrolimus seems to offer several advantages in the long-term outcome.

Delayed puberty in chronic illness

Delayed puberty can be defined as the lack of pubertal development at an age of 2 SD above the mean, which corresponds to an age of approximately 14 years for males and 13 years for females, taking both sex and ethnic origin into consideration. Its incidence associated with chronic illnesses is unknown; however, its clinical importance is relevant due to the larger percentage of patients with chronic disorders surviving until the age of puberty. Virtually every child with any chronic disease could present with delayed puberty (due to recurrent infections, immunodeficiency, gastrointestinal disease, renal disturbances, respiratory illnesses, chronic anaemia, endocrine disease, eating disorders, exercise and a number of miscellaneous abnormalities). Pubertal delay associated with chronic illness is accompanied by a delay in growth and the pubertal growth spurt. The degree to which growth and pubertal development are affected in chronic illness depends upon the type of disease and individual factors, as well as on the age at illness onset, its duration and severity. The earlier its onset and the longer and more severe the illness, the greater the repercussions on growth and pubertal development. The mechanism that trigger the start of physiological puberty remain unknown. Although malnutrition is probably the most important mechanism responsible for delayed puberty, emotional deprivation, toxic substances, stress and the side effects of chronic therapy, among others, have been implicated in the pathophysiology of delayed puberty. Therefore, early diagnosis is essential and appropriate and specific therapy fundamental.

Recent advances in pediatric liver transplantation

Pediatric liver transplantation has matured into a well-established, highly successful treatment for advanced pediatric liver disease. Recent 1-year success rates range from 85% to 95%. This unprecedented achievement is the result of careful selection criteria and optimal timing of transplantation, technical advances in surgical technique, and improved treatment following transplant. This report highlights many recent published findings representing advances that have led to current successful approaches.

Growth following solid-organ transplantation

One of the ultimate goals of successful transplantation (Tx) in pediatric solid-organ transplant recipients is the attainment of optimal final adult height. Except for kidney Tx there are limited data to address this issue. Remarkably similar factors impact on growth in pediatric kidney, liver, and heart recipients. Age is a primary factor, with younger recipients exhibiting the greatest immediate catch-up growth. Graft function is a significant contributory factor: a reduction in glomerular filtration rate (GFR) correlates with poor growth in kidney recipients, and the need for re-Tx is associated with impaired growth in liver recipients. The known adverse impact of corticosteroids on growth has led transplant physicians/surgeons to either modify the dose or attempt steroid withdrawal. In kidney and liver recipients this is associated with the development of acute rejection episodes. In infant heart transplant recipients the avoidance of maintenance corticosteroid immunosuppression is associated with normal growth velocity in the majority of recipients. With the marked improvement in patient and graft survival rates in pediatric solid-organ graft recipients, it is timely that the quality-of-life issues receive paramount attention. In children, normal growth following solid-organ Tx should be an achievable goal that results in normal final adult height.

Studies of Pediatric Liver Transplantation (SPLIT): year 2000 outcomes

BACKGROUND

Initiated in 1995, the Studies of Pediatric Liver Transplantation (SPLIT) registry database is a cooperative research network of pediatric transplantation centers in the United States and Canada. The primary objectives are to characterize and follow trends in transplant indications, transplantation techniques, and outcomes (e.g., patient/graft survival, rejection, growth parameters, and immunosuppressive therapy.)

METHODS

As of June 15, 2000, 29 centers registered 1144 patients, 640 of whom received their first liver-only transplant while registered in SPLIT. Patients are followed every 6 months for 2 years and yearly thereafter. Data are submitted to a central coordinating center.

RESULTS

One/two-year patient survival and graft loss estimates are 0.85/0.82 and 0.77/0.72, respectively. Risk factors for death include: in ICU at transplant (relative risk (RR)=2.63, P<0.05) and height/weight deficits of two or more standard deviations (RR=1.67, P<0.05). Risk factors for graft loss include: in ICU at transplant (RR=1.77, P<0.05) and receiving a cadaveric split organ compared with a whole organ (RR=2.3, P<0.05). The percentage of patients diagnosed with hepatic a. and portal v. thrombosis were 9.7% and 7%, respectively; 15% had biliary complications within 30 days. At least one re-operation was required in 45%. One/two-year rejection probability estimates are 0.60/0.66. Tacrolimus, as primary therapy posttransplant, reduces first rejection risk (RR=0.70, P<0.05). Eighty-nine percent of school-aged children are in school full-time, 18 months posttransplant.

CONCLUSIONS

This report provides one of the first descriptions of characteristics and clinical courses of a multicenter pediatric transplant population. Observations are subject to patient selection biases but are useful for generating hypothesis for future studies.

Liver transplantation. The pediatric challenge

Successful liver transplantation in a child is often a hard-won victory, requiring all the combined expertise of a dedicated pediatric transplant team. This article outlines the considerable challenges still facing pediatric liver transplant physicians and surgeons. In looking to the future, where should priorities lie to enhance the success already achieved? First, solutions to the donor shortage must be sought aggressively by increasing the use of from split-liver transplants, judicious application of living-donor programs, and increasing the donation rate, perhaps by innovative means. The major immunologic barriers, to successful xenotransplantation make it unlikely that this option will be tenable in the near future. Second, current immunosuppression is nonspecific, toxic, and unable to be individually adjusted to the patient's immune response. The goal of achieving donor-specific tolerance will require new consideration of induction protocols. Developing a clinically applicable method to measure the recipient's immunoreactivity is of paramount importance, for future studies of new immunosuppressive strategies and to address the immediate concern of long-term over-immunosuppression. The inclusion of pediatric patients in new protocols will require the ongoing insistence of pediatric transplant investigators. Third, the current immunosuppressive drugs have a long-term morbidity and mortality of their own. These long-term effects are particularly important in children who may well have decades of exposure to these therapies. There is now some understanding of their long-term renal toxicity and the risk of malignancy. New drugs may obviate renal toxicity, whereas the risk of malignancy is inherent in any nonspecific immunosuppressive regimen. Although progress is being made in preventing and recognizing PTLD, this entity remains an important ongoing concern. The global effect of long-term immunosuppression on the child's growth, development, and intellectual potential is unknown. Of particular concern is the potential for neurotoxicity from the calcineurin inhibitors. Fourth, recurrent disease and new diseases, perhaps potentiated by immunosuppressive drugs, must be considered. Already the recurrence of autoimmune disease and cryptogenic cirrhosis have been documented in pediatric patients. Now, a new lesion, a nonspecific hepatitis, sometimes with positive autoimmune markers, that may progress to cirrhosis has been recognized. It is not known whether this entity is an unusual form of rejection, an unrecognized viral infection, or a response to immunosuppressive drugs themselves. Finally, pediatric transplant recipients, like any other children, must be protected and nourished physically and mentally if they are to fulfill their potential. After liver transplantation the child's growth, intellectual functioning, and psychologic adaptation may all require special attention from parents, teachers, and physicians alike. There is limited understanding of how the enormous physical intervention of a liver transplantation affects a child's cognitive and psychologic function as the child progresses through life. The persons caring for these children have the difficult responsibility of providing services to evaluate these essential measures of children's health over the long term and to intervene if necessary. Part of the transplant physician's our duty to protect and advocate for children is to fight for equal access to health care. In most of the developing world, economic pressures make it impossible to consider liver transplantation a health care priority. In the United States and in other countries with the medical infrastructure to support liver transplantation, however, health care professionals must strive to be sure that the policies governing candidacy for transplantation and allocation of organs are applied justly and uniformly to all children whose lives are threatened by liver disease. In the current regulatory climate that increasingly takes medical decisions out of the hands of physicians, pediatricians must be even more prepared to protect the unique and often complicated needs of children both before and after transplantation. Only in this way can the challenges of the present and the future be met.

Steroid withdrawal in liver transplantation: benefits, risks, and unanswered questions

Since the early days of clinical liver transplantation, steroid therapy has constituted the mainstay of maintenance immunosuppression and is still currently combined with cyclosporine or tacrolimus worldwide. Nevertheless, the side effects of long-term steroid administration, particularly diabetes, hypercholesterolemia, arterial hypertension, infections, and bone diseases, including growth retardation in children, have focused the interest on the feasibility of steroid-free immunosuppression. The benefits and the risks of steroid withdrawal (SW) after liver transplantation are overviewed. In adults, early (3 months after transplantation) SW has been validated by several studies, whereas in pediatric recipients, the timing and selection criteria to optimize the risk/benefit ratio of SW still constitute a matter of debate. The identification of the unanswered questions in this field may serve as a framework for future studies to better assess steroid-free immunosuppression after liver transplantation.

Long-term nutritional and neurodevelopmental outcome of liver transplantation in infants aged less than 12 months

BACKGROUND

Liver transplantation is established treatment for children with end-stage liver disease and has a 5-year survival rate of 80% to 85%, even in infants under 12 months. Long-term outcome in nutritional rehabilitation and normal development is unknown. This study aimed to prospectively evaluate growth and psychoneurologic performance of children who undergo liver transplantation in infancy.

METHODS

Twenty-five infants (18 girls, 7 boys) who underwent liver transplantation at less than 12 months of age (median age, 9 months) were evaluated for 4 years. Growth measurements were expressed as standard deviation scores (SDSs; mean +/- SEM), and psychoneurologic performance was assessed with the unrevised Griffiths Mental Ability Scales (normal range, 80-120).

RESULTS

Four children died during the study (4-year survival, 84%). The children were malnourished before transplantation (SDSs: weight, -1.9 +/- 0.2; midarm muscle area, -0.93 +/- 0.3; midarm fat area, -1.52 +/- 0.3; and height, -0.95 +/- 0.3). Nutritional rehabilitation for all parameters occurred within 12 to 24 months after transplantation, which was most significant for weight (-1.1 +/- 0.2, P = 0.001), midarm muscle area (0.74 +/- 0.3, P = 0.001), and midarm fat area (-0.44 +/- 0.3, P = 0.01). There was some improvement in height (-0.72 +/- 0.3, P = 0.14), which was not significant, although infants who were severely stunted before transplantation (mean height standard deviation score [SDS] -2.46) showed significant catch-up at 1 year after transplantation (mean height SDS -1.2, P = 0.003). Psychoneurologic scores were within normal limits before transplantation and were maintained for the 4-year follow-up period, although individual scores varied during this period. Improved nutritional status was associated with increased muscle bulk and subsequent improvement in motor scores from 90.6 at initial assessment to 97.3 at 4 years (P = 0.28). There was a temporary reduction in social skills and eye-hand coordination in the first year, which may have been an effect of the hospital environment or cyclosporine immunosuppression. Language abilities also regressed during the first year, possibly related to the effect of nasogastric tube feeding in delaying normal speech development.

CONCLUSIONS

Liver transplantation in infancy has not only a successful outcome but is also associated with long-term catch-up growth and nutrition and maintenance of normal development.