Serum type III procollagen in children with type I hereditary tyrosinemia.

BACKGROUND: Type I hereditary tyrosinemia leads to hepatic dysfunction and fibrosis and is associated with a high risk of hepatic malignancy. Serum N-terminal propeptide of type III procollagen is a sensitive marker of organ fibrosis of diverse origins. The current study was conducted to determine whether analysis of serum levels of type III procollagen in hereditary tyrosinemia would be useful in the follow-up of the progressive liver disease and eventually in detecting hepatic malignancy. METHODS: Serum N-terminal propeptide of type III procollagen was sequentially studied in 10 children with type I hereditary tyrosinemia. RESULTS: At diagnosis of type I hereditary tyrosinemia, serum N-terminal propeptide of type III procollagen ranged from 0.6 to 2.9 multiples of age-related median. During follow-up, serum N-terminal propeptide of type III procollagen decreased, yet remained elevated 0.2 to 2.6 years after diagnosis. Children with the acute type of the disease tended to have higher serum N-terminal propeptide of type III procollagen than did those with the chronic type. Porphyria crises were associated with elevated serum type III procollagen. The one patient receiving 2-(2-nitro-4-trifluoromethyl-benzoyl)-1,3-cyclohexanedione (NTBC) did not differ from the other ones in serum type III procollagen levels. Serum N-terminal propeptide of type III procollagen did not increase with developing hepatocellular carcinoma. CONCLUSIONS: Serum N-terminal propeptide of type III procollagen may be useful in monitoring the hepatopathy in type I hereditary tyrosinemia but is not useful in detecting malignant transformation in the liver.     

Live donor liver transplantation for type 1 tyrosinemia: An analysis of 15 patients

Type 1 tyrosinemia is a rare metabolic disorder of the tyrosine degradation pathway. Due to the rarity of the disease, the best evidence literature offers is limited to guidelines based on expert opinions and optimal treatment is still a debate. LT serves as a definitive treatment of the defective metabolic pathway in the liver along with other serious disease manifestations such as LF and HCC. Nitisinone is a relatively new agent that is currently recommended for the medical management of the disease. Its mechanism of action is well understood, and efficacy is well established when started presymptomatically. This study aims to evaluate outcomes of 15 patients with type 1 tyrosinemia who underwent LT in nitisinone era and discuss its effect on prevention of HCC. A LT database of 1037 patients was reviewed. Data from 15 patients with type 1 tyrosinemia were retrospectively analyzed. All the patients except one were treated with nitisinone prior to LT. Most common indications for LT were LF and suspicious nodules. Seven patients had HCC. Mortality rate was 20% (n = 3). Nitisinone treatment has opened new horizons in the management of type 1 tyrosinemia, but LT still remains the only option for the patients developing LF and in the event of HCC. Neonatal screening programs utilizing blood succinyl acetone as the marker should be encouraged especially in the countries, such as Turkey, with high prevalence of consanguineous marriages.     

Favorable outcome of treatment with NTBC of acute liver insufficiency disclosing hereditary tyrosinemia type I]

BACKGROUND: Hereditary tyrosinemia type I is a disease with a severe prognosis. Main causes of death are acute liver failure, neurologic crises and hepatocarcinoma. NTBC, which acts as an inhibitor of the 4-hydroxyphenylpyruvate dioxygenase, prevents the formation of toxic metabolites involved in hepatic, renal and neurologic lesions. CASE REPORTS: Results of NTBC therapy used in three infants with type I tyrosinemia who presented with acute liver failure are reported. The diagnosis relied on the finding of high plasmatic levels of tyrosine and methionine, and abnormal urinary excretion of succinyl acetone and delta aminolevulinic acid. Treatment with NTBC was initiated within 2 to 8 days from onset of symptoms. Signs of liver failure resolved after 3 weeks therapy. After 12 to 39 months of follow-up, outcome remains favorable. CONCLUSION: The results reported here highlight the efficiency of NTBC in type I tyrosinemia with early acute onset. However, the long term outcome needs to be determined with regards to prevention of hepatocarcinoma and toxicity of the drug.     

HEREDITARY TYROSINEMIA

The clinical and biochemical findings in the case of an infant with hereditary tyrosinemia followed from birth have been reported. The child received a low protein diet from birth and a formula diet restricted in phenylalanine and tyrosine when the diagnosis was established at 54 days of age. There was a steady progress of the disease and the baby died from liver failure complicated with septicemia when he was 5½ months old. The clinical course and the biochemical findings as well as the morphological changes were typical of the acute type of the disease. A 6½ year old brother suffers from the same disease of the chronic type and the two types of hereditary tyrosinemia therefore seem to belong to the same genotype. The biochemical data from the patient with hereditary tyrosinemia have been compared with those in a healthy looking baby with longstanding and pronounced transient tyrosinemia of early infancy. The patterns of amino acids in blood and of phenolic acids in urine were similar in the two patients and it is concluded that an early laboratory differential diagnosis between hereditary tyrosinemia and transient tyrosinemia may only be made by observing the biochemical response to a diet restricted in tyrosine and phenylalanine in combination with the results of phenylalanine tolerance tests. The clinical features of hereditary tyrosinemia can apparently not be attributed to a high serum-tyrosine concentration or to the overproduction of phenolic acids; the lack of effect of early restriction in the intake of phenylalanine and tyrosine indicates a more complex pathogenesis of hereditary tyrosinemia than a primary deficiency of p-hydroxyphenylpyruvate hydroxylase.     

Tyrosinemia type 1 in Spain: Mutational analysis,treatment and long‐term outcome

Background: Tyrosinemia type 1 (HT1) is a rare but treatable disease. The aim of the present study was to review the efficacy of long‐term treatment of HT1 with nitisinone, expand knowledge about the clinical spectrum of the disease and assess a possible genotype–phenotype correlation. Methods: A retrospective multicenter study was carried out based on questionnaires on genotype, phenotype, therapy and outcome in 34 Spanish patients with HT1. Results: The main manifestations that led to the diagnosis were acute liver failure (55.8%), asymptomatic hepatomegaly (44.1%) and renal tubular dysfunction (29.4%). Laboratory analysis indicated a marked increase of α‐fetoprotein and coagulopathy. The most common mutation was IVS6‐1(G > T; 66.6% of 24/34 patients for whom mutation analysis was available) and these patients presented less nephrocalcinosis and more hepatomegaly at diagnosis; two novel mutations (c.974C>T, c.398A>T) were found. The mean duration of treatment was 6.73 years. Dietary compliance was very good in 47.1% and good in 20.6%; nitisinone treatment adherence was very good in 85.2% of cases. Mean dose of nitisinone was 0.87 mg/kg per day with average plasma levels of 45.67 µmol/L. Only one patient required liver transplantation after nitisinone and none had hepatocellular carcinoma. Conclusions: Treatment with nitisinone has improved the prognosis of HT1, and compliance is good. In Spain, screening for HT1 by plasma tyrosine and urine succinylacetone determination may be implemented with IVS6‐1(G > T) mutational analysis. A correlation between low frequency of nephrocalcinosis and IVS6‐1(G > T) mutation was observed.     

The efficacy of liver transplantation in malignant liver tumors associated with tyrosinemia: clinical and laboratory findings of five cases

To evaluate clinical and laboratory findings of these patients and the efficacy of liver transplantation in children with hepatocellular carcinoma (HCC) and hepatoblastoma (HB) associated with tyrosinemia. Among 113 children with liver tumors diagnosed between 1972 and 2004 five patients had HCC or HB associated with tyrosinemia. The age at diagnosis of the HCC or HB ranged from 9.5 to 17 yr and male:female ratio was 1:4. During regular clinic visits for tyrosinemia, elevated alpha-fetoprotein (AFP) was detected in all patients. AFP levels ranged between 13.7 and 29 340 IU/mL. Radiological studies including ultrasound, computed tomography and magnetic resonance imaging showed heterogeneous parenchyma and nodules in the liver. The patients did not have any metastatic disease. The time from diagnosis of tyrosinemia to HCC or HB ranged from 9.25 to 15.25 yr. Histopathologically, four patients have been diagnosed as HCC and one patient had HB. All patients were given chemotherapy including cisplatin and adriamycin. In three patients, living-related liver transplantation was performed. They had no treatment after transplantation. All of them are disease free. One patient was treated with chemotherapy and right hepatectomy. She had no suitable donor for living-related liver transplantation. Three months after completing chemotherapy, she had recurrent tumor in the left lobe of the liver and she died with progressive disease. The last patient whose parents were not suitable as donors for living-related liver transplantation is waiting for a deceased donor graft. All patients had limited disease to liver due to close clinical and radiological follow up for tyrosinemia. In these patients liver transplantation is curative both for liver tumor and tyrosinemia.     

Early liver transplantation is indicated for tyrosinemia type I

Liver transplantation is now accepted as the treatment of choice for tyrosinemia type I (hereditary tyrosinemia). In an effort to determine whether any factors in these patients would aid in predicting optimal timing of the transplant procedure, we evaluated several clinical, biochemical, and radiographic parameters in five successive patients undergoing liver transplant for tyrosinemia type I at the University of Minnesota. All five patients evidenced prolonged periods of clinical and metabolic stability with dietary therapy and four of five remained stable at the time of evaluation for transplantation. Nevertheless, all five suffered significant and unexpected complications of tyrosinemia prior to the time of liver transplant. Four developed renal stones, two were in liver failure, and one developed a neurologic crisis that left him completely paralyzed. Hepatocellular carcinoma was found in one of the five at transplant. We could identify no clinical, biochemical, or radiographic study that was predictive of the likelihood of significant complications of the disorder. Survival from the transplant procedure itself was 100%. The inability to predict or prevent significant complications of tyrosinemia and the favorable outcome from transplantation lead us to recommend liver transplant for all patients with tyrosinemia type I by 12 months of age.     

Liver transplantation for glycogen storage disease types I, III, and IV

Glycogen storage disease (GSD) types I, III, and IV can be associated with severe liver disease. The possible development of hepatocellular carcinoma and/or hepatic failure make these GSDs potential candidates for liver transplantation. Early diagnosis and initiation of effective dietary therapy have dramatically improved the outcome of GSD type I by reducing the incidence of liver adenoma and renal insufficiency. Nine type I and 3 type III patients have received liver transplants because of poor metabolic control, multiple liver adenomas, or progressive liver failure. Metabolic abnormalities were corrected in all GSD type I and type III patients, while catch-up growth was reported only in two patients. Whether liver transplantation results in reversal and/or prevention of renal disease remains unclear. Neutropenia persisted in both GSDIb patients post liver transplantation necessitating continuous granulocyte colony stimulating factor treatment. Thirteen GSD type IV patients were liver transplanted because of progressive liver cirrhosis and failure. All but one patient have not had neuromuscular or cardiac complications during follow-up periods for as long as 13 years. Four have died within a week and 5 years after transplantation. Caution should be taken in selecting GSD type IV candidates for liver transplantation because of the variable phenotype, which may include life-limiting extrahepatic manifestations. It remains to be evaluated, whether a genotype-phenotype correlation exists for GSD type IV, which may aid in the decision making. Conclusion Liver transplantation should be considered for patients with glycogen storage disease who have developed liver malignancy or hepatic failure, and for type IV patients with the classical and progressive hepatic form.     

Tyrosinemia: A Review

Hypertyrosinemia encompasses several entities, of which tyrosinemia type I (or hepatorenal tyrosinemia, HT1) results in the most extensive clinical and pathological manifestations involving mainly the liver, kidney, and peripheral nerves. The clinical findings range from a severe hepatopathy of early infancy to chronic liver disease and rickets in the older child; gradual refinements in the diagnosis and medical management of this disorder have greatly altered its natural course, mirroring recent advances in the field of metabolic diseases in the past quarter century. Hepatorenal tyrosinemia is the inborn error with the highest incidence of progression to hepatocellular carcinoma, likely due to profound mutagenic effects and influences on the cell cycle by accumulated metabolites. The appropriate follow-up of patients with cirrhosis, the proper timing of liver transplantation in the prevention of carcinoma, and the long-term evolution of chronic renal disease remain important unresolved issues. The introduction of a new pharmacologic agent, NTBC, holds the hope of significantly alleviating some of the burdens of this disease. Mouse models of this disease have permitted the exploration of newer treatment modalities, such as gene therapy by viral vectors, including ex vivo and in utero methods. Finally, recent observations on spontaneous genetic reversion of the mutation in HT1 livers challenge conventional concepts in human genetics. Received November 15, 2000; accepted December 7, 2000.     

Experience and Problems of Newborn Mass Screening for Inborn Errors of Metabolism in Japan

A program of newborn mass screening for inborn errors of metabolism has since 1977 been conducted by The Ministry of Health and Welfare in Japan with great success in preventing mental and physical handicaps in children and estimating the incidence of these diseases in our country as follows: phenylketonuria (PKU) 1/78,100 maple syrup urine disease (MSUD) 1/281,200 histidinemia 1/10,600 galactosemia 1/156,200 There are some genetic variants of each of these diseases, PKU, MSUD and others. Circumspection is therefore required in making a diagnosis or selecting a particular method of treatment. When MSUD is suspected, it is necessary to make a definite diagnosis promptly and take therapeutic measures including peritoneal dialysis. The efficacy of low histidine diet in histidinemia is not yet ascertained. Close inquiries should be made about the benefit of such a dietary regimen and the long term prognosis therewith. A screening test for homocystinuria by the detection of blood methionine level is difficult. In cases with high blood methionine level during the neonatal period, it is necessary to differentiate the condition from other disease with high blood methionine. Hepatorenal tyrosinemia appears to be unsuitable for mass screening because of the the unefficacy of low phenylalanine tyrosine diet in some of the patient and the difficulty to differentiate from transient tyrosinemia in normal newborn infants. However, mass-screening is recommendable for Richner-Hanhalt type tyrosinemia which responds well to dietary therapy and which is easy to differentiate from the transient tyrosinemia because of the marked elevation of blood tyrosine.     

Juvenile form of tyrosinemia type I

A 1-3/12-year-old Turkish boy born of consanguineous parents was hospitalized in poor general condition with disorientation, hepatosplenomegaly, and rickets. Laboratory tests showed pronounced symptoms of hepatic dysfunction, rickets, and Fanconi's syndrome with acidosis. The diagnosis juvenile type I tyrosinemia was based on the anamnesis, hepatorenal symptoms, and elevated tyrosine and methionine blood levels as well as the pathognomic findings of heavy succinylacetonuria and absent fumarylacetoacetase activity in the fibroblasts. Etiology, pathobiochemistry, clinical symptoms, differential diagnosis, and therapy of this rare autosomal-recessive inherited metabolic disease were discussed.     

Tyrosinemia type I: A clinico-laboratory case report

Progressive hepatocellular dysfunction in a neonate, resulting in elevated serum α-fetoprotein together with raised blood levels of tyrosine and methionine, a generalized amino aciduria and the absence of urinary δ-aminolevulinic acid and succinylacetone, suggests a diagnosis of tyrosinemia type Ib. Classical tyrosinemia type I arises from a deficiency of fumarylacetoacetate hydrolase while the variant tyrosinemia type Ib results from a deficiency of maleylacetoacetate isomerase.     

Contribution of extrahepatic tissues to biochemical abnormalities in hereditary tyrosinemia type I: study of three patients after liver transplantation

Three patients with hereditary tyrosinemia type I were examined before and after liver transplantation to assess the role of extrahepatic tissues in the biochemical disorders of this disease. Before transplantation the three patients excreted excessive amounts of succinylacetoacetate (SAA), succinylacetone (SA), tyrosyl acidic compounds, and 5-aminolevulinate (ALA). The activity of 5-aminolevulinate dehydratase (ALA-D) in red blood cells was markedly inhibited (1% to 5% of control) in the three patients. Successful liver transplantation resulted in decreased excretion of urinary SAA plus SA, tyrosyl acidic compounds, and ALA. Two of the patients continued to excrete significant amounts of SAA plus SA, whereas those compounds were undetectable in the urine of the third patient. Tyrosine loading resulted in increased excretion of SAA plus SA in two patients, but those compounds remained undetectable in the third. All three patients continued to excrete higher than normal amounts of ALA, but the activity of ALA-D in red blood cells returned to normal after transplantation, indicating marked clearance of SA from the blood. Liver transplantation may not totally correct the biochemical abnormalities of hereditary tyrosinemia. It is likely that the kidney is the source of persistent biochemical aberrations in the urine without significant effects on the blood. Our results suggest the existence of heterogeneity for renal involvement in hereditary tyrosinemia.     

Tyrosinämie Typ I

Tyrosinemia type I is an autosomal recessive inherited defect of tyrosine metabolism. The underlying cause is a defect of fumarylacetoacetate hydrolase. The disease affects the liver (acute liver failure, liver cirrhosis, hepatocellular cancer), the kidney (tubulopathy with hypophosphatemic rickets), and the peripheral nervous system (paresthesia, vegetative symptoms, progressive paralysis). Beside the hypertyrosinemia the diagnosis can be made on the basis of urinary excretion of a pathological metabolite of the tyrosine metabolism (succinylacetone). Therapeutic options are a regulated phenylalanine/tyrosine diet, a very effective drug therapy (NTBC) that has been available for several years, and in cases of acute liver failure or end-stage liver cirrhosis a liver transplantation.     

Long-term survival after liver transplantation in children with metabolic disorders

BACKGROUND: Liver transplantation for inherited metabolic disorders aims to save the patient's life when the disorder is expected to progress to organ failure, and to cure the underlying metabolic defect. METHODS: We retrospectively analyzed 146 pediatric liver transplants (28 metabolic; 118 non-metabolic) performed between 1986 and 2000. RESULTS: Twenty-eight transplants were performed in 24 children with metabolic disease (8 females; 16 males; age range 3 months to 17 yr). Indications included alpha-1-antitrypsin deficiency (n = 8), two cases each of hyperoxaluria type 1, Wilson's disease, hereditary tyrosinemia type I, citrullinemia, methylmalonic acidemia, and one case each of propionic acidemia, Crigler-Najjar syndrome type I, neonatal hemachromatosis, hemophilia B, Niemann-Pick disease type B, and cystic fibrosis. Eighteen transplants were whole organ grafts and 10 were lobar or segmental. Auxiliary liver transplants were performed in two patients and three received combined liver-kidney transplants. There were three deaths from sepsis, two from chronic rejection, and one from fulminant hepatitis. Seven of 10 patients currently of school age are within 1 yr of expected grade and three who had pretransplant developmental delay have remained in special education. Actuarial survival rates at 5 and 10 yr are 78% and 68%, respectively, with mean follow-up in excess of 5 yr. These results compare favorably to 100 pediatric patients transplanted for non-metabolic etiologies (65% and 61%, respectively) (p= NS). CONCLUSIONS: Pediatric liver transplantation for metabolic disorders results in excellent clinical and biochemical outcome with long survival and excellent quality of life for most recipients.     

Pediatric hepatocellular carcinoma in a developing country: Is the etiology changing?

HCC is the second most common malignant liver tumor of childhood. It typically affects children with a median age of 10–14 yr on background hepatitis B‐related liver disease and is often metastatic or locally advanced at diagnosis. Children below the age of five yr typically constitute <10% of all children with HCC. In these children, it occurs on a background of congenital or metabolic liver disease. The records of all children with HCC who presented to our department over a six‐yr study period were reviewed. Twelve patients with a median age of 5.9 yr (range 1.6–15.4) were diagnosed to have HCC. All patients underwent liver transplantation, and none were resected. Eleven patients had background congenital or metabolic liver disease. All five of those with hereditary tyrosinemia type 1 who presented to us were found to have HCC. No patient had hepatitis B‐related liver (HBV) disease. Eight (66.7%) patients had incidentally discovered HCC on examination of the explant. Incidentally discovered HCC were smaller, well differentiated, and did not show microvascular invasion compared to those diagnosed preoperatively. There was no recurrence with a median follow‐up of five months. The patient demographic for pediatric HCC is changing probably as a consequence of successful immunization against HBV. Younger patients with congenital and metabolic liver disease in whom liver transplantation is the ideal treatment are likely to constitute an ever‐increasing proportion of patients with pediatric HCC as HBV disease is controlled or eradicated.     

Orthotopic liver transplantation in liver-based metabolic disorders

The efficacy of orthotopic liver transplantation (OLT) in the management of more common liver-based metabolic disorders associated with severe liver damage, alpha-1-antitrypsin deficiency (PIZZ), Wilson disease and tyrosinaemia has been demonstrated and indications defined. An early mortality in excess of 15% and finite resources limit its use. Phenotypic heterogeneity make the precise indication in other disorders less certain. In disorders in which endstage liver disease is less frequent such as cystic fibrosis, haemochromatosis and galacosaemia it has been a very effective therapy. It has been used with encouraging results in disorders in which the liver is structurally normal such as Crigler-Najjar type I, primary hyperoxaluria type I and primary hypercholesterolaemia. In these it should be performed before there is permanent damage to brain, kidneys or heart. OLT in the short term prevents hyperammonaemic coma in urea cycle defects and may prevent extrahepatic disease in glycogen storage disease type IV. Its limitation in reversing all metabolic effects in these and other disorders is discussed. It is ineffective in protoporphyria or Niemann Pick disease type II (Sea Blue Histiocyte syndrome) in which the transplanted liver acquires the lesions of the initial disorder and extrahepatic features progress. Early referral provides optimum circumstances to assess the benefits of OLT as compared with those of other forms of management and to achieve transplantation at the ideal time. The place of OLT in management will require constant review as metabolic disorders are better defined, new forms of therapy evolve and as techniques of liver transplantation and modes of immunosuppression improve.     

Tyrosinemia type 1 in pediatric nephrology: Not always straightforward

The main clinical features of tyrosinemia type 1 usually appear in the first months of life, including fever, diarrhea, vomiting, liver involvement, growth failure, and renal proximal tubulopathy with subsequent hypophosphatemic rickets. An early diagnosis is crucial in order to provide specific management and to prevent complications. Here, we report on two cases referred primarily to pediatric nephrologists for the diagnosis of “neonatal tubulopathy” and management of “X-linked hypophosphatemia (XLH),” respectively. Our aim is to emphasize that (1) even a mixed tubulopathy can reveal tyrosinemia, and (2) tyrosinemia is a classic differential diagnosis of XLH that should not be forgotten, especially in the era of the anti-FGF23 burosumab.     

Histologic Features of the Liver in Type Ia Glycogen Storage Disease: Comparative Study between Different Age Groups and Consecutive Biopsies

In this report, the histologic criteria for the diagnosis of type Ia glycogen storage disease (GSD) in a wide age range were studied. Liver needle biopsies of 44 patients with type Ia GSD confirmed by enzyme analysis were re-evaluated and compared. Fatty change, nuclear hyperglycogenation (NH), and fibrosis were examined and graded. The second biopsies of 14 patients were also evaluated and compared with the first ones. The patients were grouped according to age: group I: <1 year (18 cases), group II: 1–5 years (19 cases), group III: >5 years (7 cases). A mosaic pattern was detected in all biopsies. The amount of fibrosis in group I was less than that in the other two groups. The fatty change in group I was more prominent. There was not much difference in the amount of NH between age groups. In comparing the two different biopsies of 14 patients, the amount of fibrosis was found to be increased in 7 cases. NH was also increased in a different group of 7 patients. These findings were both statistically significant. The amount of fatty change was minimal in most of the cases. Fibrosis is associated with types III, IV, VI, IX, and X GSD. Our results support previous studies stating that fibrosis may also be present and varies in extent in type I GSD. Fatty change as large lipid vacuoles and NH may not be seen in many cases of type I GSD. Therefore, histologic criteria for the diagnosis of GSD may not be specific, and enzyme analysis should be performed. Received March 14, 2001; accepted February 8, 2002.     

Enzyme defect in a case of tyrosinemia type I, acute form

We determined the activities of tyrosine aminotransferase (TAT, EC 2.6.1.5), p-hydroxyphenylpyruvate oxidase (p- HPPA oxidase, EC 1.14.2.2) and fumarylacetoacetate fumarylhydrolase ( FAH , EC 3.7.12) in cytosol of the liver and kidney tissues obtained at autopsy from a case of hereditary tyrosinemia type I. Values were compared with those from a control group of autopsied tissues from three adults and six children, who had died of other causes. In tyrosinemia, these three hepatic enzyme activities were all decreased: TAT showed approximately 35%, p- HPPA oxidase 11%, and FAH 60% of the corresponding control values. On the other hand, kidney enzymes in tyrosinemia revealed that FAH was most significantly decreased to approximately 14% of the control activity. Km values for substrate--determined for p- HPPA oxidase and FAH --were not different between the patient and controls, suggesting no altered properties of these enzymes. We conclude that in the present case of hereditary tyrosinemia type I, the activities of p- HPPA oxidase in liver and FAH in kidney were most strikingly affected. This fact may in part explain the deteriorated metabolism of tyrosine observed in this patient.