Orthotopic liver transplantation for ornithine transcarbamylase deficiency with hyperammonemic encephalopathy

Evaluation of living donors for hereditary liver disease (siblings, heterozygotes)

Living donor liver transplantation (LDLT) is recognised as an alternative treatment modality to reduce waiting list mortality and expand the donor pool. Over recent decades, there have been an increasing number of reports on the use of LT and specifically LDLT for familial hereditary liver diseases. There are marginal indications and contraindications that should be considered for a living donor in paediatric parental LDLT. No mortality or morbidity related to recurrence of metabolic diseases has been observed with heterozygous donors, except for certain relevant cases, such as ornithine transcarbamylase deficiency, protein C deficiency, hypercholesterolemia, protoporphyria, and Alagille syndrome, while donor human leukocyte antigen homozygosity also poses a risk. It is not always essential to perform preoperative genetic assays for possible heterozygous carriers; however, genetic and enzymatic assays must hereafter be included in the parental donor selection criteria in the aforementioned circumstances.

Liver transplantation in rare late-onset ornithine transcarbamylase deficiency with central nervous system injury: A case report and review of the literature

BACKGROUND

Ornithine transcarbamylase deficiency (OTCD) is a genetic metabolic disease. Its clinical manifestations are mainly central nervous system dysfunction caused by high blood ammonia. Late-onset OTCD combined with central nervous system injury has a poor therapeutic response, which is one of the main factors affecting the prognosis and quality of life of patients. liver transplantation (LT) has gradually become a radical treatment for OTCD, which has achieved good results. However, there is no consensus on the timing of LT and problems of nervous system damage and repair.

METHODS

We report the development of late-onset OTCD with central nervous system injury in an 11-year-old child who received liver transplantation at our transplant center. His first symptoms were nonprojectile vomiting, followed by irritability and disturbance of consciousness, after which the disease progressed rapidly and finally resulted in a coma. After liver transplantation, the child's consciousness returned to normal, muscle strength of the limbs gradually recovered from grade 0 to grade 4, and muscle tone gradually recovered from grade 4 to grade 1, suggesting that the motor nerves had gradually recovered. However, the child is currently mentally retarded, and the language center has not yet fully recovered.At the same time, we made a literature review of OTCD.

CONCLUSION

For OTCD patients with central nervous system injury, liver transplantation can fundamentally solve the problem of ammonia metabolism in the liver and avoids further damage to the central nervous system caused by hyperammonemia. At the same time, children's nervous systems are in the developmental stage when neuroplasticity is greatest. If liver transplantation is performed as soon as possible, nerve repair is still possible.

Mutation Study of Malaysian Patients with Ornithine Transcarbamylase Deficiency: Clinical, Molecular, and Bioinformatics Analyses of Two Novel Missense Mutations of the OTC Gene

Ornithine transcarbamylase deficiency (OTCD), an X-linked disorder that results from mutations in the OTC gene, causes hyperammonemia and leads to various clinical manifestations. Mutations occurring close to the catalytic site of OTCase can cause severe OTCD phenotypes compared with those caused by mutations occurring on the surface of this protein. In this study, we report two novel OTC missense mutations, Q171H and N199H, found in Malaysian patients. Q171H and N199H caused neonatal onset OTCD in a male and late OTCD in a female, respectively. In silico predictions and molecular docking were performed to examine the effect of these novel mutations, and the results were compared with other 30 known OTC mutations. In silico servers predicted that Q171H and N199H, as well as 30 known missense mutations, led to the development of OTCD. Docking analysis indicated that N-(phosphonoacetyl)-L-ornithine (PALO) was bound to the catalytic site of OTCase mutant structure with minimal conformational changes. However, the mutations disrupted interatomic interactions in the catalytic site. Therefore, depending on the severity of disruption occurring at the catalytic site, the mutation may affect the efficiency of mechanism and functions of OTCase.

Prenatal treatment of ornithine transcarbamylase deficiency

PURPOSE OF STUDY

Patients with neonatal urea cycle defects (UCDs) typically experience severe hyperammonemia during the first days of life, which results in serious neurological injury or death. Long-term prognosis despite optimal pharmacological and dietary therapy is still poor. The combination of intravenous sodium phenylacetate and sodium benzoate (Ammonul®) can eliminate nitrogen waste independent of the urea cycle. We report attempts to improve outcomes for males with severe ornithine transcarbamylase deficiency (OTCD), a severe X-linked condition, via prenatal intravenous administration of Ammonul and arginine to heterozygous carrier females of OTCD during labor.

METHODS USED

Two heterozygote OTCD mothers carrying male fetuses with a prenatal diagnosis of OTCD received intravenous Ammonul, arginine and dextrose-containing fluids shortly before birth. Maintenance Ammonul and arginine infusions and high-caloric enteral nutrition were started immediately after birth. Ammonul metabolites were measured in umbilical cord blood and the blood of the newborn immediately after delivery. Serial ammonia and biochemical analyses were performed following delivery.

SUMMARY OF RESULTS

Therapeutic concentrations of Ammonul metabolites were detected in umbilical cord and neonatal blood samples. Plasma ammonia and glutamine levels in the postnatal period were within the normal range. Peak ammonia levels in the first 24-48h were 53mcmol/l and 62mcmol/l respectively. The boys did not experience neurological sequelae secondary to hyperammonemia and received liver transplantation at ages 3months and 5months. The patients show normal development at ages 7 and 3years.

CONCLUSION

Prenatal treatment of mothers who harbor severe OTCD mutations and carry affected male fetuses with intravenous Ammonul and arginine, followed by immediate institution of maintenance infusions after delivery, results in therapeutic levels of benzoate and phenylacetate in the newborn at delivery and, in conjunction with high-caloric enteral nutrition, prevents acute hyperammonemia and neurological decompensation. Following initial medical management, early liver transplantation may improve developmental outcome.

Liver transplantation for pediatric inherited metabolic disorders: Considerations for indications, complications, and perioperative management

LT is an effective therapeutic option for a variety of IEM. This approach can significantly improve the quality of life of patients who suffer from severe disease manifestations and/or life-threatening metabolic decompensations despite medical/dietary management. Due to the significant risks for systemic complications from surgical stressors, careful perioperative management is vital. Even after LT, some disorders require long-term dietary restriction, medical management, and monitoring of metabolites. Successful liver transplant for these complex disorders can be achieved with disease- and patient-specific strategies using a multidisciplinary approach. In this article, we review indications, complications, perioperative management, and long-term follow-up recommendations for IEM that are treatable with LT.

Curative Treatment of Ornithine Transcarbamylase Deficiency With a Liver Transplant: A Case Report

One of the X chromosome-linked disorders is ornithine transcarbamylase deficiency in the urea cycle. This disorder results in increased ammonia and glutamine in the blood. Accumulation of these metabolites without treatment causes brain edema, which often progresses to coma and death. This study describes a 5-year-old girl with ornithine transcarbamylase deficiency who presented with hyperammonemic encephalopathy that was successfully treated with an orthotropic liver transplant. Recently, liver transplant has been introduced as an alternative treatment for patients with ornithine transcarbamylase deficiency.

Liver transplantation for urea cycle disorders in pediatric patients: a single-center experience

LT has emerged as a surgical treatment for UCDs. We hypothesize that LT can be safely and broadly utilized in the pediatric population to effectively prevent hyperammonemic crises and potentially improve neurocognitive outcomes. To determine the long-term outcomes of LT for UCDs, charts of children with UCD who underwent LT were retrospectively reviewed at an academic institution between July 2001 and May 2012. A total of 23 patients with UCD underwent LT at a mean age of 3.4 yr. Fifteen (65%) patients received a whole-liver graft, seven patients (30%) received a reduced-size graft, and one patient received a living donor graft. Mean five-yr patient survival was 100%, and allograft survival was 96%. Mean peak blood ammonia (NH(3) ) at presentation was 772 μmol/L (median 500, range 178-2969, normal <30-50). After transplantation, there were no episodes of hyperammonemia. Eleven patients were diagnosed with some degree of developmental delay before transplantation, which remained stable or improved after transplantation. Patients without developmental delay before transplantation maintained their cognitive abilities at long-term follow-up. LT was associated with the eradication of hyperammonemia, removal of dietary restrictions, and potentially improved neurocognitive development. Long-term follow-up is underway to evaluate whether LT at an early age (<1 yr) will attain improved neurodevelopmental outcomes.

Living donor liver transplantation from an asymptomatic mother who was a carrier for ornithine transcarbamylase deficiency

Liver transplantation (LT) has been adopted as a radical treatment for ornithine transcarbamylase deficiency (OTCD), yielding favorable outcomes. Despite the fact that it is an inheritable disease, a blood relative who is heterozygous for the disorder must sometimes be used as a liver donor for living donor LT. There is ongoing discussion regarding the use of heterozygous donors, however, to our knowledge, no cases where donation was determined based on the Ornithine transcarbamylase (OTC) activity before LT have been reported. Between May 2001 and April 2011, 17 patients were indicated for living donor LT because of OTCD at our facility. There were three cases with heterozygous donor candidate (17.6%). All heterozygous candidates underwent a liver biopsy to measure their OTC activity before LT and made efforts to secure the safety of the both donor and recipient. Two of 3 candidates had headaches sometimes, and their activity was less than 40%, and thus they were not employed as the donor. One candidate with 104.4% activity was employed, yielding favorable outcomes. Our current experience supported the effectiveness of our donation criteria, however it is necessary to collect sufficient data on a large number of patients to confirm the safety of the procedure.

Impact of enzyme activity assay on indication in liver transplantation for ornithine transcarbamylase deficiency

There are no objective and concrete guidelines for the management of Ornithine transcarbamylase deficiency (OTCD). Based on previous findings, we hypothesized that patients with OTCD have a low Ornithine transcarbamylase (OTC) activity in the liver, and therefore it would be better to determine the appropriate indications and optimal timing for liver transplantation (LT) based on the OTC activity. However, few data have so far been accumulated on the OTC activity in cases that are indicated for LT. The purpose of the present study was to clarify the OTC activity in cases that were indicated for LT. This study involved thirteen children with OTCD (8 males and 5 females) who underwent LT, and two females with OTCD who did not require LT. The OTC activity of the neonatal onset type ranged from 0% to 7.2%, while that of the late onset type who underwent LT ranged from 4.4% to 18.7%. The OTC activity of the late onset type which did not require LT was 33-38% based on a preoperative needle liver biopsy. Some late onset patients that underwent LT, showed an activity that was as low as that observed in the neonatal onset cases. This is the first report to show the results of measuring the OTC activity for serial OTCD cases indicated for LT. OTC activity might be an indicator to determine the indications for and the timing of LT in the late onset type, however, further investigations are necessary.

High urgency liver transplantation in ornithine transcarbamylase deficiency presenting with acute liver failure

OTCD can present with ALF at any age. Under adequate therapy symptoms resolve quickly. We report a three-yr-old girl with the manifestation of an OTCD as ALF. Despite adequate pharmacotherapy and protein restriction, the patient deteriorated and developed hepatic encephalopathy. A high urgency liver transplantation was performed and the patient recovered completely. We conclude that in patients with ALF urea cycle defects in general and OTCD in particular should be considered as differential diagnosis. Patients should be managed in a center that has the capacity for an emergency liver transplantation.

Living donor liver transplantation for ornithine transcarbamylase deficiency

Ornithine transcarbamylase deficiency, the most common urea cycle disorder, causes hyperammonemic encephalopathy and has a poor prognosis. Recently, LT was introduced as a radical OTCD treatment, yielding favorable outcomes. We retrospectively analyzed LT results for OTCD at our facility. Twelve children with OTCD (six boys and six girls) accounted for 7.1% of the 170 children who underwent LDLT at our department between May 2001 and April 2010. Ages at LT ranged from nine months to 11 yr seven months. Post-operative follow-up period was 3-97 months. The post-operative survival rate was 91.7%. One patient died. Two patients who had neurological impairment preoperatively showed no alleviation after LT. All patients other than those who died or failed to show recovery from impairment achieved satisfactory quality-of-life improvement after LT. The outcomes of LDLT as a radical OTCD treatment have been satisfactory. However, neurological impairment associated with hyperammonemia is unlikely to subside even after LT. It is desirable henceforth that more objective and concrete guidelines for OTCD management be established to facilitate LDLT with optimal timing while avoiding the risk of hyperammonemic episodes.

Anesthetic implications of ornithine transcarbamylase deficiency

BACKGROUND

Ornithine transcarbamylase deficiency (OTCD) is an X-linked urea cycle disorder associated with potentially fatal episodes of hyperammonemia. Children with OTCD often require anesthesia. There is insufficient information regarding perioperative complications and optimal management of anesthesia in these patients.

AIM

To retrospectively review the medical records of children with OTCD to ascertain the nature and frequency of peri-procedural complications.

METHODS/MATERIALS

The electronic medical records of Mayo Clinic patients with OTCD who underwent anesthesia between the dates of January 2003 and September 2009 were reviewed.

RESULTS

Nine patients with OTCD underwent 25 anesthetics using a variety of anesthetic techniques, including four major surgeries. Eleven procedures were performed prior to OTCD diagnosis and those patients were not receiving therapy for a urea cycle disorder. In the other cases, patients were on a variety of therapies for OTCD. Fourteen patients were outpatient procedures. Clinical signs of postoperative metabolic decompensation did not occur.

CONCLUSIONS

In this series, patients with OTCD tolerated anesthesia well. Choice of perioperative management of OTCD and the choice of anesthetic technique should be individualized and based on clinical circumstances, but should have the underlying aim of minimizing protein catabolism. It appears patients with stable OTCD may undergo minor procedures as outpatients safely.

Long-term outcome following pediatric liver transplantation for metabolic disorders

In order to determine long-term outcome, including survival, growth and development, following liver transplantation in children with metabolic disorders, we retrospectively reviewed charts of 54 children with metabolic disorders evaluated from 1989-2005 for presenting symptoms, transplantation timing and indications, survival, metabolic parameters, growth, and development. Thirty-three patients underwent liver transplantation (12 received combined liver-kidney transplants) at a median age of 21 months. At a median follow-up of 3.6 yr, patient survival was 100%, and liver and kidney allograft survival was 92%, and 100%, respectively. For the group as a whole, weight Z scores improved and body mass index at follow-up was in the normal range. Two yr post-transplantation, psychomotor development improved significantly (p < 0.01), but mental skills did not; however, both indices were in the low-normal range of development. When compared to patients with biliary atresia, children with metabolic disorders showed significantly lower mental developmental scores at one and two yr post-transplantation (p < 0.05), but psychomotor developmental scores were not significantly different. We conclude that, in patients with metabolic disorders meeting indications for transplantation, liver transplantation or combined liver-kidney transplantation (for those with accompanying renal failure) is associated with excellent long-term survival, improved growth, and improved psychomotor development.

Early orthotopic liver transplantation in urea cycle defects: follow up of a developmental outcome study

Patients with neonatal urea cycle defects (UCDs) typically have high mortality and poor neurological outcome unless they receive liver transplantation. Neurologic outcome may be better with liver transplantation before age one year. We report on a follow up on an initial prospective study performed to assess developmental outcome after early liver transplant using the Griffiths Scales. Developmental testing up to 7years after transplantation showed average developmental quotients (DQs) of 69 for four children who underwent transplantation before one year of age (latest DQs were 47, 63, 95 and 96), and 80 for a patient who underwent transplantation at 3years of age (latest DQ was 88). We conclude that a combination of early liver transplantation, aggressive metabolic management and early childhood intervention improve the neurologic outcome of children with UCDs.

Current role of liver transplantation for the treatment of urea cycle disorders: a review of the worldwide English literature and 13 cases at Kyoto University

To address the current role of liver transplantation (LT) for urea cycle disorders (UCDs), we reviewed the worldwide English literature on the outcomes of LT for UCD as well as 13 of our own cases of living donor liver transplantation (LDLT) for UCD. The total number of cases was 51, including our 13 cases. The overall cumulative patient survival rate is presumed to be more than 90% at 5 years. Most of the surviving patients under consideration are currently doing well with satisfactory quality of life. One advantage of LDLT over deceased donor liver transplantation (DDLT) is the opportunity to schedule surgery, which beneficially affects neurological consequences. Auxiliary partial orthotopic liver transplantation (APOLT) is no longer considered significant for the establishment of gene therapies or hepatocyte transplantation but plays a significant role in improving living liver donor safety; this is achieved by reducing the extent of the hepatectomy, which avoids right liver donation. Employing heterozygous carriers of the UCDs as donors in LDLT was generally acceptable. However, male hemizygotes with ornithine transcarbamylase deficiency (OTCD) must be excluded from donor candidacy because of the potential risk of sudden-onset fatal hyperammonemia. Given this possibility as well as the necessity of identifying heterozygotes for other disorders, enzymatic and/or genetic assays of the liver tissues in cases of UCDs are essential to elucidate the impact of using heterozygous carrier donors on the risk or safety of LDLT donor-recipient pairs. In conclusion, LT should be considered to be the definitive treatment for UCDs at this stage, although some issues remain unresolved.

Management and outcome of neonatal-onset ornithine transcarbamylase deficiency following liver transplantation at 60 days of life

Neonatal hyperammonemia secondary to X-linked ornithine transcarbamylase (OTC) deficiency carries a high risk of morbidity and mortality. Results of medical therapy are less than satisfactory. Experience with liver transplantation in very young affected infants is limited. We report a male newborn with severe OTC deficiency who underwent successful orthotopic, cadaveric liver transplantation at the age of 60 days. Although technically challenging in the neonatal period, liver transplantation should be considered early as the most promising treatment approach currently available.

Developmental outcomes with early orthotopic liver transplantation for infants with neonatal-onset urea cycle defects and a female patient with late-onset ornithine transcarbamylase deficiency

Urea cycle defects (UCDs) typically present with hyperammonemia, the duration and peak levels of which are directly related to the neurologic outcome. Liver transplantation can cure the underlying defect for some conditions, but the preexisting neurologic status is a major factor in the final outcome. Multicenter data indicate that most of the children who receive transplants remain significantly neurologically impaired. We wanted to determine whether aggressive metabolic management of ammonia levels after early referral/transfer to a metabolism center and early liver transplantation would result in better neurologic outcomes. We report on 5 children with UCDs, ie, 2 male patients with X-linked ornithine transcarbamylase deficiency and 2 male patients with carbamoyl phosphate synthase deficiency, all of whom had neonatal presentations and underwent orthotopic liver transplantation before 1 year of age, and 1 female patient with partial X-linked ornithine transcarbamylase deficiency that was intractable to medical therapy, who underwent transplantation at 35 months of age. Developmental testing with the Griffiths scale was performed on 3 occasions each, 12 months apart, up to 45 months after transplantation. Full-scale indices for 3 children who underwent early transplantation showed average developmental quotients of 67. All 5 children had metabolic cures. There were no deaths (30-month survival rate: 100%). One child is currently listed for repeat transplantation because of bile duct stenosis and cirrhosis. We conclude that early liver transplantation and aggressive metabolic management improve early neurologic outcomes for children with UCDs, but longer follow-up monitoring is needed.

The role of liver transplantation in urea cycle disorders

Liver transplantation has an important role in the management of patients with urea cycle disorders, particularly those with severe variants, progressive liver disease, and some patients who have proved very difficult to control with conventional therapy. As a result of technical advances in liver transplantation, the outlook, both morbidity and mortality, is better and continues to improve. Patients can almost always have a normal diet and the quality of life for survivors is generally excellent.

Isolated hepatocyte transplantation in an infant with a severe urea cycle disorder

OBJECTIVE

Transplantation of isolated hepatocytes in animal models has been shown to correct inborn errors of metabolism. Based on these studies and our experience with hepatocyte transplantation in a child with Crigler-Najjar syndrome, isolated hepatocyte transplantation was performed to attempt metabolic reconstitution in a male infant with severe ornithine transcarbamylase (OTC) deficiency.

METHODS

An infant with an antenatal diagnosis of OTC deficiency was managed intensively to prevent hyperammonemia. Isolated hepatocytes were obtained by collagenase perfusion of donated livers not used for transplantation. Hepatocytes were infused in batches over the first 4 weeks of life via an umbilical venous catheter positioned in the portal vein. Immunosuppression consisted of tacrolimus and corticosteroids.

RESULTS

Over 4 billion viable hepatocytes were transplanted during the first 3.5 weeks of life. A period of metabolic stability was achieved between days 20 and 31 during which normal protein intake was tolerated while phenylbutyrate was weaned. During this time, plasma ammonia and glutamine remained within normal limits. Hyperammonemia reappeared abruptly on day 31 of life. Protein tolerance diminished to baseline; metabolic stability was subsequently reattained only following successful liver transplantation at 6 months of age.

CONCLUSIONS

Isolated hepatocyte transplantation appeared to result in temporary relief of hyperammonemia and protein intolerance attributable to OTC deficiency. The metabolic stability achieved was lost after 11 days presumably because of rejection of the transplanted cells because of insufficient immunosuppression. Future attempts at isolated hepatocyte transplantation for inborn errors of metabolism in humans should include adequate immunosuppression and a liver biopsy as a means of proving hepatocyte engraftment and function.

An integrated approach to the diagnosis and prospective management of partial ornithine transcarbamylase deficiency

Ornithine transcarbamylase deficiency (OTCD) is the most common inherited urea cycle disorder, and is transmitted as an X-linked trait. Female OTCD heterozygotes exhibit wide clinical severities, ranging from being apparently asymptomatic to having the profound neurologic impairment observed in affected males. However, clinical and laboratory diagnosis of partial OTCD during asymptomatic periods is difficult, and correlation of phenotypic severity with either DNA mutation and/or in vitro enzyme activity is imprecise. Provocative testing, including protein load and allopurinol challenge used in the diagnosis of OTCD females, is not without risk and subject to both false positives and negatives. Although definitive when successful, DNA-based diagnosis is unable to detect mutations in all cases. We have previously used the ratio of isotopic enrichments of [(15)N]urea/[(15)N]glutamine ((15)N-U/G) derived from physiologic measurements of ureagenesis by stable isotope infusion as a sensitive index of in vivo urea cycle activity. We have now applied this method in combination with traditional biochemical testing to aid in the diagnosis of a symptomatic OTCD female in whom mutation in the ornithine transcarbamylase (OTC) gene was not found. The (15)N-U/G ratio in this patient showed that she had severe reduction of in vivo urea cycle activity on par with affected male subjects. This was correlated with partially deficient OTC activity in her liver, degree of orotic aciduria, and history of suspected recurrent hyperammonemic episodes before age 3. The measurement of in vivo urea cycle activity in combination with traditional biochemical indices optimizes a diagnostic approach to the at-risk partial OTCD patient, especially in those in whom molecular testing is unproductive. Together they contribute to the risk versus benefit considerations regarding the pursuit of medical therapy versus surgical, ie, orthotopic liver transplantation (OLT) therapy. The decision to resort to OLT in females with partial OTC activity is controversial, requiring consideration of phenotypic severity, failure of medical therapy, access to tertiary care centers experienced in the management of acute hyperammonemia, and social factors. In this patient, the use of in vivo and in vitro measures of urea cycle activity in conjunction with a consideration of her clinical history and medical-social situation led to a decision for OLT.

Hyperammonemia in urea cycle disorders: role of the nephrologist

Hyperammonemia associated with inherited disorders of amino acid and organic acid metabolism is usually manifested by irritability, somnolence, vomiting, seizures, and coma. Although the majority of these patients present in the newborn period, they may also present in childhood, adolescence, and adulthood with failure to thrive, persistent vomiting, developmental delay, or behavioral changes. Persistent hyperammonemia, if not treated rapidly, may cause irreversible neuronal damage. After the diagnosis of hyperammonemia is established in an acutely ill patient, certain diagnostic tests should be performed to differentiate between urea cycle defects and other causes of hyperammonemic encephalopathy. In a patient with a presumed inherited metabolic disorder, the aim of therapy should be to normalize blood ammonia levels. Recent experience has provided treatment guidelines that include minimizing endogenous ammonia production and protein catabolism, restricting nitrogen intake, administering substrates of the urea cycle, administering compounds that facilitate the removal of ammonia through alternative pathways, and, in severe cases, dialysis therapy. Initiation of dialysis in the encephalopathic patient with hyperammonemia is indicated if the ammonia blood level is greater than three to four times the upper limit of normal. Hemodialysis is the most effective treatment for rapidly reducing blood ammonia levels. Continuous hemofiltration and peritoneal dialysis are also effective modalities for reducing blood ammonia levels. An improved understanding of the metabolism of ammonia and neurological consequences of hyperammonemia will assist the nephrologist in providing optimal care for this high-risk patient population.

Long-term correction of urea cycle disorders

Long-term correction of urea cycle disorders is achieved by correction of the enzymatic defect in hepatocytes. Currently, orthotopic liver transplantation is the primary means of achieving this correction. In the United States most liver transplantations for urea cycle disorders have been restricted to patients with ornithine transcarbamylase deficiency and argininosuccinic aciduria. However, patients with citrullinemia have also received transplants, but more so in Europe and Japan. Recent advances in organ procurement, surgical technique, and immunosuppression have significantly decreased morbidity and mortality. However, unique short-term complications associated with surgery and long-term complications associated with chronic immunosuppression have spurred continued efforts to develop gene replacement therapies for management of acute metabolic decompensations as intercurrent therapy until liver transplantation, and ultimately, for long-term correction. The pathophysiology of urea cycle disorders requires gene vector delivery systems that are highly efficient for liver transduction and transgene expression. To date, adenoviral vectors are unique in fulfilling these criteria, and significant data have been gained in both animal and human studies with early versions of adenoviral vectors. Ultimately, the development of helper-dependent adenoviral vectors may offer the long-term expression and increased margin of safety necessary for adjunctive therapies.

Genotype spectrum of ornithine transcarbamylase deficiency: correlation with the clinical and biochemical phenotype

Ornithine transcarbamylase (OTC) deficiency, a partially dominant X-linked disorder, is the most common inherited defect of the urea cycle. Previous reports suggested a variable phenotypic spectrum, and several studies documented different "private" mutations in the OTC genes of patients. Our laboratory identified disease-causing mutations in 157 families with OTC deficiency, 100 of which came to medical attention through a hemizygous propositus and in 57 the index case was a heterozygous female. We correlated the genotype with age of onset, liver OTC activity, incorporation of nitrogen into urea, and peak plasma ammonia levels. The "neonatal onset" group has a homogeneous clinical and biochemical phenotype, whereas the "late onset" group shows an extremely wide phenotype; 60% of the mutations are associated exclusively with acute neonatal hyperammonemic coma. The remaining mutations caused a nonuniform phenotype ranging from severe disease to no symptoms; 31% of the mutations in the OTC gene occur in CpG dinucleotides (methylation-mediated deamination), and none of them accounted for more than 4% of the total. Eighty-six percent of the mutations represented single-base substitutions and 68% of the substitutions were transitions. G-to-A and C-to-T transitions were the most frequent substitutions (34 and 21%, respectively) whereas C-to-A, A-to-C, C-to-G, and T-to-A transversions were the least common (1.5-3%). Twenty percent of propositi and 77% of propositae carried new mutations. Forty percent of female germinal mutations were in CpG dinucleotides whereas this number appears much smaller in male germinal mutations. These data allow classification of patients with OTC deficiency into at least two groups who have discordant disease course and prognoses. In addition, they improve our understanding on the origin of mutations in the OTC gene and allow better counseling of affected families.

Evidence for forebrain cholinergic neuronal loss in congenital ornithine transcarbamylase deficiency

Congenital ornithine transcarbamylase (OTC) deficiency in humans results in failure to thrive, hypotonia, seizures and mental retardation. Neuropathologic evaluation reveals significant cerebral cortical atrophy, delayed myelination and Alzheimer type II astrocytosis. Using an animal model of congenital OTC deficiency, the sparse fur (spf) mouse, studies reveal convincing evidence of a loss of forebrain cholinergic neurons in this condition. Evidence includes (i) reduced activities of the cholinergic nerve terminal enzyme choline acetyltransferase (ChAT), (ii) a 25% loss of ChAT immunostaining, (iii) reduced high affinity transport of [3H]choline by cortical synaptosomes and (iv) a selective reduction in densities of presynaptic muscarinic M2 binding sites, in spf mouse brain compared to controls. A partial correction of the cholinergic deficit was observed following treatment with acetyl-L-carnitine. Possible mechanisms responsible for cholinergic neuronal loss in congenital OTC deficiency include decreased synthesis of the ChAT substrate acetyl CoA, impaired cerebral energy metabolism and NMDA receptor-mediated excitotoxicity. Loss of forebrain cholinergic neurons is consistent with the severe cognitive impairment characteristic of congenital OTC deficiency.

Directing portal flow is essential for graft survival in auxiliary partial heterotopic liver transplantation in the dog

BACKGROUND/PURPOSE

Auxiliary liver transplantation is an attractive alternative for orthotopic liver transplantation in patients with certain inborn errors of metabolism of the liver in which complete resection of the liver is unnecessary or even contraindicated. Because in these diseases portal hypertension is mostly absent, finding a balance in portal blood distribution between native liver and graft is complicated. The objective of this study was to investigate requirements for long-term (180 days) graft survival in auxiliary partial heterotopic liver transplantation (APHLT) in a dog model.

METHODS

A metabolic defect was corrected in 26 dalmation dogs with a 60% beagle heterotopic auxiliary liver graft. Four groups of different portal inflow were studied. In the ligation group the portal vein to the host liver was ligated. In the split-flow group graft and host liver received separate portal inflow. In the banding group the distribution of the portal flow was regulated with an adjustable strapband and in the free-flow group the portal blood was allowed to flow randomly to host or graft liver.

RESULTS

Metabolic correction increased in all groups after transplantation from 0.19 +/- 0.02 to 0.70 +/- 0.05 (P< .0001) but remained significantly better in the ligation and split-flow groups (graft survival, 135 +/- 27 and 144 +/- 31 days). In the banding group metabolic correction decreased significantly after 70 days, and although the grafts kept some function for 155 +/- 14 days, in 4 of 6 dogs portal thrombosis was found. In the free-flow group, competition for the portal blood led to reduced correction within 12 days and total loss of function in 96 +/- 14 days. Graft function also was assessed with technetium (Tc) 99m dimethyl-iminodiacetic acid uptake. A good linear association between HIDA uptake and metabolic correction was observed (r = 0.74; P < .0005). Grafts that contributed more than 15% to the total uptake of HIDA showed biochemical correction. This indicates a critical graft mass of about 15% to 20% of the hepatocyte volume to correct this metabolic defect.

CONCLUSION

Auxiliary partial heterotopic liver transplantation can be a valuable alternative treatment for inborn errors of hepatic metabolism if the native liver and the graft receive separate portal blood inflow.

Treatment of ornithine transcarbamylase deficiency in girls by auxiliary liver transplantation: conceptual changes in a living-donor program

BACKGROUND/PURPOSE

Ornithine transcarbamylase (OTC) deficiency is an X-chromosome-linked genetic disorder resulting in hyperammonemia hepatic dysfunction, coma, and serious neurological sequelae. This report describes an experience in treating this condition with living-related liver transplantation.

METHODS

Three children with OTC were treated with a living-related liver transplantation. Potential donors were evaluated with the allopurinol loading test to exclude heterozygotes. FK506 and low-dose steroids were used for immunosuppression. Auxiliary partial orthotopic transplantation (APOLT) was used in two of the cases.

RESULTS

All three children survived and are doing well without protein restriction.

CONCLUSIONS

These observations suggest that in OTC removal of the native liver is not necessary because (1) a partial liver segment with normal enzyme activity corrects the hyperammonemia, (2) in case of graft failure the native liver is an available backup, and (3) the native liver has the ability to recover function. As long as living-related donors serve as the main source of donor organs, APOLT is a safer approach to liver transplantation in OTC.

Liver transplantation for the treatment of urea cycle disorders

The principal goal of therapy when liver transplantation is used for the treatment of metabolic disease is to correct the metabolic error. By doing so, liver transplantation eliminates the hepatic and peripheral consequences of the error. Inborn errors involving the urea cycle appear on theoretical grounds to be amenable to treatment using liver transplantation and, indeed, published data demonstrate that this approach to therapy can be successful. The purpose of this study is to examine the outcome of liver transplantation done for the indication of urea cycle defects in a large group of patients. The first goal of the study is to determine with certainty that liver transplantation corrects hyperammonaemia and halts the progress of disease. A second goal is to determine the extent of neurological recovery in children previously injured by hyperammonaemia. The final goal is to understand whether the quality of life is improved and medical expense is reduced by transplantation. The study involved a survey of major transplantation centres. Four centres provided data about 16 patients, 14 of whom were alive 11 months to 6 years after transplantation. The results demonstrate that liver transplantation resulted in correction of hyperammonaemia in all patients. The neurological outcome after transplantation correlated closely with the condition prior to transplantation. This population of patients has had relatively few problems in the long term related to the liver transplant itself. The quality of life seems to be much improved, but further study will be needed to confirm this. Limited data involving two patients show a reduction in the cost of care. We conclude from our experience that liver transplantation can be an effective treatment for children with urea cycle defects.

Liver transplantation for hemochromatosis, Wilson's disease, and other metabolic disorders

Liver transplantation provides an effective means for replacing a failing liver, in addition to correcting the underlying abnormality in many metabolic disorders. Results of liver transplantation for metabolic diseases have been generally encouraging, with the exception of hereditary hemochromatosis, in which infectious and cardiac complications appear to increase post-transplant mortality. Better pretransplant diagnosis of hemochromatosis, utilizing the recently identified putative gene, may help reduce post-transplant complications. In metabolic diseases, improved understanding of the underlying genetic and molecular defects will lead to advances in medical therapy and perhaps a decreased need for liver transplantation. NTBC therapy for hereditary tyrosinemia and purified glucocerebroside therapy for Gaucher disease are two such examples. The prospects of gene therapy are being actively pursued for many metabolic diseases, such as CF, hemophilia, and familial hypercholesterolemia. Until such investigation leads directly to clinical practice, however, liver transplantation remains an effective option for therapy for a wide range of metabolic diseases.