A 4.5-year-old boy received a combined liver and kidney transplant for correction of hyperoxaluria type 1. Both organs were from the same donor and functioned primarily. Three months after transplantation, urine oxalate excretion reached a maximum of 10,500 mumol/24 h and remained above 2300 mumol/24 h for the next 2 months. Two months later, oxalate excretion decreased to about 565 mumol/24 h, indicating exhaustion of a large oxalate pool. Six months after transplantation plasma oxalate is near normal (4.9 mumol/l). With the exception of one episode of acute rejection of the renal transplant, both organs were tolerated well and continue to have a unimpaired function 9 months after transplantation. However, there is increased echogenity on renal ultrasound, indicating oxalate deposits in the grafted kidney. This case illustrates that successful combined transplantation of both liver and kidney can be performed in infants, resulting in cure of the metabolic defect. The prolonged or acute excretion of oxalate may lead to oxalate deposition in the grafted kidney without impaired graft function or early graft loss.
The high-Mr isoenzyme of alkaline phosphatase (AP, EC 3.1.3.1), a highly sensitive index to cholestasis, was measured by liquid chromatography in 45 patients with cystic fibrosis. Results of serum tests for liver dysfunction--including gamma-glutamyltransferase, aspartate aminotransferase, alanine aminotransferase, total AP, bilirubin, and bile acids--were compared with those for high-Mr AP. Values for high-Mr AP were increased in 44.4% of our patient population, with activities ranging from 0.4 to 17.3 U/L. The upper limit in the control group was 2.5 U/L. We find increased high-Mr AP to be a more sensitive indicator of liver dysfunction in patients with cystic fibrosis than are other tests.
In five patients with benign transient hyperphosphatasaemia (THP), high activities of so-called "atypical" alkaline phosphatase or fragment isoenzymes were detected. One case occurred after rotavirus infection. Incubation with neuraminidase suggested that "atypical" alkaline phosphatase originated from highly glycosylated bone and liver isoenzymes. This may have been due to virus-induced low isoenzyme clearance from serum. The course of isoenzyme activities in THP following rotavirus infection was followed. Determination of atypical alkaline phosphatase may be useful in the diagnosis of THP.
A new method for the Separation of alkaline phosphatase isoenzymes by means of high performance liquid chromatography (HPLC) is presented. One isoenzyme was identified in homogenate of small intestine, two were identified in bone, and two in liver, and fragment and biliary isoenzymes were identified in bile. Sera from 32 patients with different diseases of the skeletal System or the liver were analysed. High activities of the bone isoenzymes were detected in bone diseases, of the second liver isoenzyme in acute hepatitis and of the first liver and biliary isoenzymes in biliary obstruction. There are indications that the first liver isoenzyme is derived from the cell membrane and the second liver isoenzyme from the cytosol. The biliary isoenzyme is considered to be a highly sensitive and specific indicator for cholestasis.
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