Nutrition in Pediatric Liver Disease.

In liver disease, there is derangement of appetite, digestion, absorption, assimilation, storage and metabolism of both macro and micronutrients. These derangements have an impact on mortality and morbidity associated with liver diseases. In infants, breast feeds should not be stopped unless there are compelling reasons such as underlying metabolic problem. Parenteral nutrition should be considered only if, oral or nasogastric feeding is not possible. The effect of malnutrition on liver disease and impact of liver failure on nutrition is vicious and nutritional intervention has to be done at the earliest to break that vicious cycle. This chapter gives an overview of nutritional management in acute and chronic liver diseases in children and also its impact on specific clinical scenarios including liver transplantation.

Managing recurrent portal steal in auxiliary liver transplantation for non-cirrhotic metabolic liver disease.

BACKGROUND: APOLT has been proposed as a treatment modality for certain types of NCMLD. While the short-term outcomes of this operation have been comparable with orthotopic LT, its long-term outcomes have sparsely been reported. We present one such case of Citrullinemia type I who underwent APOLT and developed recurrent PS. CASE REPORT: A 2-year-old male child with a diagnosis of Citrullinemia type I underwent APOLT with a left lateral segment from a split deceased donor liver, and his postoperative period was unremarkable. Ammonia-lowering agents were stopped 1 week following the operation and the child was discharged home on a normal diet. Four years following APOLT, the child presented with altered sensorium and seizures. A diagnosis of PS was made. Subsequent to an embolization of the native liver's right anterior portal vein his sensorium improved and he remained clinically stable on a normal diet. Six years following the APOLT, the child again presented with features of acute encephalopathy. Imaging was suggestive of PS. A portal vein embolization of the native portal vein was performed and the child's clinical condition improved. At 6 months' follow-up, the child remains well on a normal diet. CONCLUSIONS: While the early impediments in this technique may have been overcome, in the absence of any realistic clinical application gene therapy, the debate of long-term phenotypic metabolic correction for NCMLD by APOLT needs to be revisited.

Non-standard hepatic venous reconstruction in the setting of absent inferior vena cava in partial graft pediatric liver transplantation-A matched retrospective cohort study.

Recipient cava may be unavailable for outflow reconstruction in some children undergoing liver transplantation (PLT) due to caval agenesis, tumor, or fibrotic caval occlusion. Non-standard hepatic venous reconstruction (NHVR) with a direct veno-caval anastomosis or neo-cava reconstruction is necessary in such cases. Retrospective review of all PLT needing NHVR performed in our unit from January 2010 to September 2019 was performed. Outcomes of this group were compared to a 2:1 matched control group who underwent transplantation with standard piggyback technique. Fifteen children (4.9%) of 304 PLT recipients underwent NHVR. Caval agenesis in biliary atresia (n = 5, 33%) and hepatoblastoma infiltrating the cava (n = 4, 27%) were the commonest indications. Ten children had neo-cava reconstruction, while 5 had direct anastomosis to the supra-hepatic caval cuff or right atrium. One child had developed neo-cava thrombosis without graft venous outflow obstruction in the post-operative period. There was no significant difference in major morbidity, need for re-operation (20% vs 16.7%; P = 1.00), hospital stay (24 days, vs 21 days; P = .32), graft & patient survival among the study and control groups. Absent or inadequate recipient cava during PLT with a partial liver graft can be safely managed with technical modifications. Results equivalent to standard piggyback implantation can be achieved.

Uncommon presentation of a recurrent diaphragmatic hernia after pediatric liver transplantation.

DH is a rare but well-recognized complication of PLT. However, a recurrent DH in the setting of PLT has not been reported. We report the case of a child who had previously undergone a DH repair early after PLT and presented more than two years later with atypical findings of severe sepsis and a tender abdominal swelling.

A case report of a novel 22 bp duplication within exon 1 of the UGT1A1 in a Sudanese infant with Crigler-Najjar syndrome type I.

BACKGROUND: Crigler Najjar type 1 is a rare autosomal recessive condition caused by the absence of UDPGT enzyme due to mutations in the UGT1A1 gene. This enzyme is responsible for elimination of unconjugated bilirubin from the body by glucuronidation. Affected individuals are at risk for kernicterus and require lifelong phototherapy. Liver transplant is the only definitive treatment. CASE PRESENTATION: Here we report a case of a 6 month old Sudanese female infant with CN1 whose molecular analysis revealed a novel homozygous 22 base pair duplication (c.55_76dup) in the coding exon 1 of the UGT1A1 gene. This 22 bp duplication causes a frame shift leading to a premature stop codon. She underwent a successful liver transplant at 7 months of age and is doing well at 1 year follow-up. CONCLUSION: This study shows that molecular diagnosis helps in precise diagnosis of CN1 and in prognosis, prompt medical intervention and appropriate therapy. This particular 22 bp duplication within the coding region of UGT1A1 can be a founder mutation in the Sudanese population.

Auxiliary Partial Orthotopic Liver Transplantation for Monogenic Metabolic Liver Diseases: Single-Centre Experience.

PURPOSE: Auxiliary partial orthotopic liver transplantation (APOLT) in metabolic liver disease (MLD) has the advantage of correcting the metabolic defect, preserving the native liver for gene therapy in the future with the possibility of withdrawal of immunosuppression. METHODS: Retrospective analysis of safety and efficacy of APOLT in correcting the underlying defect and its impact on neurological status of children with MLD. RESULTS: A total of 13 APOLT procedures were performed for MLD during the study period. The underlying aetiologies being propionic acidemia (PA)-5, citrullinemia type 1 (CIT1)-3 and Crigler-Najjar syndrome type 1 (CN1)-5 cases respectively. Children with PA and CIT1 had a median of 8 and 4 episodes of decompensation per year, respectively, before APOLT and had a mean social developmental quotient (DQ) of 49 (<3 standard deviations) as assessed by Vineland Social Maturity Scale prior to liver transplantation. No metabolic decompensation occurred in patients with PA and CIT1 intraoperatively or in the immediate post-transplant period on protein-unrestricted diet. Patients with CN1 were receiving an average 8-15 h of phototherapy per day before APOLT and had normal bilirubin levels without phototherapy on follow-up. We have 100% graft and patient survival at a median follow-up of 32 months. Progressive improvement in neurodevelopment was seen in children within 6 months of therapy with a median social DQ of 90. CONCLUSIONS: APOLT is a safe procedure, which provides good metabolic control and improves the neurodevelopment in children with selected MLD.

Feasibility and Safety of Split-Liver Transplantation in a Nascent Framework of Deceased Donation.

Split-liver transplantation (SLT) is a valuable option for optimizing the use of good-quality deceased donor grafts. It is not routinely reported outside the West because of limited deceased donor numbers, technical and organizational constraints, lack of experience, and a predominant living donor liver transplantation (LDLT) practice. At our center, 20% of the liver transplantations (LTs) are from deceased donors. We report our experience of SLT and compare outcomes with pediatric and adult LDLT recipients. A prospectively maintained database of all LT recipients between September 2009 and March 2017 was analyzed. Each pediatric SLT recipient was matched to 2 pediatric LDLT recipients for age, weight, urgency, and year of transplant. Each adult SLT recipient was similarly matched to 2 adult LDLT recipients for age, Model for End-Stage Liver Disease score, and year of transplant. Intraoperative and postoperative parameters, including recovery time, morbidity (biliary and vascular complications, Clavien grade >IIIA complications), and mortality were compared. In total, 40 SLTs were performed after splitting 20 deceased donor livers (in situ, n = 11; hybrid split, n = 3; and ex vivo, n = 6). Recipients included 22 children and 18 adults. There were 18 livers that were split conventionally (extended right lobe and left lateral segment [LLS]), and 2 were right lobe-left lobe SLTs. Also, 3 LLS grafts were used as auxiliary grafts for metabolic liver disease. Perioperative mortality in SLT recipients occurred in 3 patients (2 children and 1 adult). Incidence of vascular, biliary, and Clavien grade >IIIA complications were similar between matched adult and pediatric SLT and LDLT groups. In conclusion, SLT is an effective technique with outcomes comparable to living donor grafts for adult and pediatric recipients. Using SLT techniques at centers with limited deceased donors optimizes the use of good-quality whole grafts and reduces the gap between organ demand and availability.

Hepatocarcinogenesis in multidrug-resistant P-glycoprotein 3 deficiency.

MDR3 is a hepatocyte canalicular membrane protein encoded by the ABCB4 gene located on chromosome 7. MDR3 mediates the translocation of phosphatidylcholine into bile. Severe MDR 3 deficiency typically presents during early childhood with chronic cholestasis evolving to cirrhosis and portal hypertension, requiring liver transplantation. Herein, we report a case of severe MDR3 deficiency in a male child diagnosed with negative MDR3 immunostaining in hepatic canaliculi who underwent LDLT at our centre. We also describe single incidentally detected early well-differentiated HCC in the explant liver. The patient is on regular follow-up and is doing well. Our report shows that MDR3 deficiency may be a risk factor for the development of HCC.

Auxiliary Liver Transplantation for Acute Liver Failure.

BACKGROUND: Auxiliary partial orthotopic liver transplantation is a technique where part of diseased native liver is removed and replaced with healthy donor liver so that, the left behind native liver could later regenerate. CASE CHARACTERISTICS: 2 year 6 month old girl with acute liver failure due to Hepatitis A. She underwent a successful auxiliary partial orthotopic liver transplantation. OUTCOME: Successful native liver regeneration and immunosuppression withdrawal after two and half years of surgery. MESSAGE: In selective cases of acute liver failure, auxiliary partial orthotopic liver transplantation could provide a chance for native liver regeneration and immunosuppression-free life.

Liver pathology in severe multidrug resistant 3 protein deficiency: a series of 10 pediatric cases.

Multidrug resistance protein 3 (MDR3) is a hepatocyte canalicular membrane protein encoded by the ABCB4/MDR3 gene located on chromosome 7. Several liver diseases are known to be associated with MDR3 deficiency. The basic defect is reduced secretion of biliary phospholipid causing disturbance in the primary bile composition, leading to injury to biliary epithelium inducing cell death and inflammation. Severe MDR3 deficiency typically presents during the first year of life or early childhood, often progressing to chronic liver disease with cirrhosis and portal hypertension, requiring liver transplantation. Negative MDR3 immunostaining is suggestive of MDR3 deficiency. Herein, we report the clinical and histopathologic features of 10 cases (6 male/4 female) in infants and children with severe MDR3 deficiency (age range of 8 months to 7 years) diagnosed with negative MDR3 immunostaining in hepatic canaliculi. Three cases underwent liver transplantation. The cases showed periportal bridging fibrosis to micronodular cirrhosis, ductular proliferation with bile plugs, and lobular canalicular bile stasis with rosetting. All 3 explant livers demonstrated cystically dilated large ducts with crystallization of cholesterol. One case showed well-differentiated hepatocellular carcinoma. We conclude that MDR3 immunostaining on formalin-fixed and paraffin-embedded sections is a useful tool to diagnose severe MDR3 deficiency in pediatric liver cholestatic disease cases where genetic testing is not available.

Neonatal liver failure: aetiologies and management--state of the art.

Acute liver failure in neonates is rare, but carries a high mortality. Neonatal liver failure can be defined as "failure of the synthetic function of liver within 4 weeks of birth". Encephalopathy is not essential for the diagnosis. Acute liver failure in neonates differs from children with regard to aetiology and outcome. Common causes of neonatal liver failure are neonatal hemochromatosis, haematological malignancies, viral infections and liver-based metabolic defects. Early diagnosis and referral to a paediatric liver centre is recommended as liver transplantation is the only definitive treatment when supportive or a disease-specific treatment fails.

Auxiliary liver transplantation: a form of gene therapy in selective metabolic disorders.

Auxiliary liver transplantation is an accepted form of therapy in acute liver failure and in certain metabolic disorders. We report India's first successful auxiliary liver transplantation for Crigler-Najjar syndrome type 1, showing that it is technically feasible and safe procedure. It is utmost important to select appropriate cases for auxiliary transplant for successful long-term outcome. The surgeon should also have an understanding of the portal flow dynamics, as steal phenomenon can occur, depriving blood blow to either graft or native liver. Though successful in animal models, gene therapy is still in experimental stage in humans and pace of progress has been disappointing. Auxiliary liver transplantation retains the native liver for future gene therapy. These children are young and are likely to have a long life expectancy, and withdrawal of immunosuppression would be a huge advantage.

Selective use of endoscopic retrograde cholangiopancreatography in the diagnosis of biliary atresia in infants younger than 100 days.

OBJECTIVES: We investigated the role and safety of endoscopic retrograde cholangiopancreatography (ERCP) in diagnosing biliary atresia (BA) in prolonged neonatal cholestasis, when standard workup was inconclusive. PATIENTS AND METHODS: We reviewed notes of 48 cholestatic infants younger than 100 days undergoing ERCP from 1997 to 2007. RESULTS: Amongst approximately 3300 infants evaluated for liver disease during the study, 224 (6.8%) were diagnosed with BA. Forty-eight children underwent ERCP. Findings at liver biopsy (n=47) included nonspecific cholestasis (n=19, 40%), giant-cell hepatitis (n=12, 26%), "large bile duct obstruction" (n=9, 19%) in the presence of pigmented stools, and mixed cholestatic/hepatitic features (n=7, 15%). ERCP demonstrated a patent biliary tree in 20 infants (42%). BA was confirmed at exploratory laparotomy in all 3 infants (6%) in whom cannulation failed. The remaining 25 infants (52%) also proceeded to exploratory laparotomy, in which BA was confirmed in 22 (46%). Amongst the 20 children in whom ERCP ruled out BA, 8 (17%) had normal biliary anatomy, whilst 12 (25%) had an abnormal biliary tree, including 6 (12.5%) with neonatal sclerosing cholangitis. After ERCP none developed clinical pancreatitis or peritonitis. CONCLUSIONS: ERCP is a safe procedure for diagnosing BA even in the smallest infants with high positive and negative predictive values.