Orthotopic Liver Transplantation in Glycogen Storage Disease Type 1a: Perioperative Glucose and Lactate Homeostasis

Abstract Glycogen storage disease type 1a (GSD 1a) is a rare inborn error of metabolism. It causes severe fasting intolerance and lactic acidosis due to the deficiency of glucose-6-phosphatase enzyme. Blood glucose and lactate concentrations from 2 patients with GSD 1a were retrospectively compared to a control group of patients with familial amyloid polyneuropathy. Carbohydrate intake and infusions were compared to experimental data based on stable isotope studies. Perioperative lactate concentrations were significantly higher in our 2 patients with GSD 1a (median 15.0 mmol/L; range 9.9-22.0 mmol/L) versus 8 controls. In one patient, despite normal blood glucose concentrations, lactate acidosis was probably caused by a combination of the disease itself, insufficient (par)enteral carbohydrate intake, Ringer lactate infusions, and circulatory insufficiency. Patients with GSD 1a carry an increased risk of lactic acidosis during orthotopic liver transplantation compared to non-GSD patients. Multidisciplinary perioperative care is essential to prevent significant complications.

Mechanisms by Which Metabolic Reprogramming in GSD1 Liver Generates a Favorable Tumorigenic Environment

Abstract Glycogen storage disease type 1 (GSD1) is an inherited disorder caused by impaired glucose 6-phosphatase activity. This impairment translates into the inhibition of endogenous glucose production and the subsequent accumulation of cellular glucose 6-phosphate. Excess glucose 6-phosphate enhances glycolysis, increases the production of fatty acids, uric acid, and lactate, causes hepatomegaly due to glycogen and lipid accumulation, and finally results in liver tumor development. Although the exact mechanisms of tumorigenesis in patients with GSD1 remain unclear, GSD1 hepatocytes undergo a Warburg-like metabolic switch. The consequent hyperactivation of specific metabolic pathways renders GSD1 hepatocytes susceptible to tumor development, presumably by providing the building blocks and energy required for cell proliferation. In addition to this, enhanced apoptosis in GSD1 may promote mitotic activity and hence result in DNA replication errors, thereby contributing to tumorigenesis. Increased carbohydrate responsive element-binding protein (ChREBP) and mammalian target of rapamycin (mTOR) activity and impaired AMP-activated protein kinase (AMPK) function likely play key roles in these pro-oncogenic processes.

Profile of Patients With Von Gierke Disease From India.

Molecular diagnosis of Von Gierke disease is possible by mutation analysis of G6PC gene. GSD type 1a cases account for 20 % of glycogenoses in our center. We diagnosed ten unrelated patients with glycogen storage disease based on clinical, biochemical and histopathology investigations. Mutation analysis was done by sequencing the G6PC gene. Two unrelated patients were found to be homozygous for a novel mutation c.355 C>G (p.H119D). They were born to non-consanguineous parents from Karnataka. This suggests founder effect. Mutation detection confirms the diagnosis and assists in counseling and prenatal diagnosis.

A Novel Mutation (A148V) in the Glucose 6-phosphate Translocase (SLC37A4) Gene in a Korean Patient with Glycogen Storage Disease Type 1b

We report a Korean patient with glycogen storage disease type 1b (GSD-1b) whose diagnosis was confirmed by liver biopsy and laboratory results. The patient presented with delay of puberty and short stature on admission and had typical clinical symptoms of GSD as well as chronic neutropenia and inflammatory bowel disease. Mutation analysis of the glucose 6-phosphate translocase 6-phosphate translocase (SLC37A4) gene revealed that the patient was a compound heterozygote of two different mutations including a deletion mutation (c.1042_1043delCT; L348fs) and a missense mutation (A148V). The L348fs mutation was inherited from the patient's father and has been reported in an Italian family with GSD-1b, while the A148V mutation was transmitted from the patient's mother and was a novel mutation. To the best of our knowledge, this is the first report of genetically confirmed case of GSD-1b in Korean.

Long-term Outcome of Glycogen Storage Disease Type 1; Analysis of Risk Factors for Hepatic Adenoma / 대한소아소화기영양학회지

PURPOSE: The aim of the study was to evaluate the long-term outcome of glycogen storage disease (GSD) type 1 with particular reference to hepatic adenoma and hepatocellular carcinoma, and to analyze risk factors affecting the development of hepatic adenoma in GSD type 1. METHODS: Forty-three GSD type 1 patients (31 males and 12 females, mean age 13.9+/-6.4 years) were analyzed retrospectively. Hepatic adenoma was detected on abdominal USG and diagnosed on histologic examination. Clinical profiles were compared between patients with hepatic adenoma (n=16) and age-matched controls without hepatic adenoma (n=16). RESULTS: 1) Of 43 GSD type 1 patients, 16 (37.2%) had hepatic adeoma. Hepatic adenoma was detected at the age of mean 14.2+/-4.1 years (range: 7.9~25.7 years). Fourteen (87.5%) adenomas were multiple at detection. 2) Comparison of the clinical profiles between adenoma group and non-adenoma group revealed that age at first introduction of uncooked cornstarch treatment was significantly late in adenoma group compared with non-adenoma group (9.1+/-5.2 years vs. 3.0+/-1.8 years, p=0.003). Portocaval shunt surgery was performed in 11 (68.8%) patients in adenoma group and 3 (18.8%) in non-adenoma group (p=0.004). Hepatic adenoma developed mean 5.8+/-4.2 years after shunt operation. 3) One patient was diagnosed as hepatocellular carcinoma at the age of 25.7 years. CONCLUSION: Hepatic adenoma is an important late complication of GSD type 1 with the risk of malignant transformation. Early introduction of cornstarch therapy with strict metabolic control is needed to prevent the development of hepatic adenoma in GSD type 1.