Ischaemia modified albumin in patients with acute coronary syndrome and negative cardiac troponin I.

BACKGROUND: Approximately 40-60% of patients with acute coronary syndrome (ACS) have normal cardiac troponin I (cTnI) concentrations on admission. Ischaemia modified albumin (IMA) has been suggested as a new biomarker of myocardial ischaemia. METHODS: A total of 43 patients presenting with symptoms suggestive of ACS but with normal (< 0.1 µg/L) cTnI concentrations and 45 healthy subjects were studied. The patients from the study group were divided into two groups: STEMI (n = 28) and NSTEMI (n = 15). All these patients were undergoing percutaneous coronary intervention (PCI) with stenting. The concentrations of cTnI, myoglobin and IMA were determined on admission and 4 h after PCI. RESULTS: Mean (SD) IMA concentrations were higher in patients with ACS (114.39 ± 25.18 U/ml) as compared to the control group (96.24 ± 6.28 U/ml, p < 0.005). IMA concentrations ≥ 104.0 U/ml demonstrated 72.1% sensitivity and 75.6% specificity for the diagnosis of ACS. The area under the receiver operator characteristic curve was 0.766 (95% CI 0.664-0.868) for ACS patients (NSTEMI + STEMI). In both groups increased median (IQR) cTnI concentration after PCI was observed (STEMI patients to 65.4 (10.9-106.9) µg/L and NSTEMI to 17.6 (0.77-84.0) µg/L). In contrast, no increase in IMA concentration was observed. CONCLUSIONS: IMA may be a useful biomarker for the identification of ACS patients presenting with typical acute chest pain and/or abnormal electrocardiograms but negative cTnI.

Differential effects of selegiline on glucose synthesis in rabbit kidney-cortex tubules and hepatocytes. In vitro and in vivo studies.

The action of selegiline, a selective and irreversible inhibitor of monoamine oxidase B, commonly applied in the therapy of Parkinson's disease, on glucose formation was investigated in isolated rabbit hepatocytes and kidney-cortex tubules, maintaining the whole body glucose homeostasis via gluconeogenic pathway activity. An intensive hepatic metabolism of selegiline resulted in formation of selegiline-N-oxide, desmethylselegiline, methamphetamine and amphetamine, whereas during slow degradation of the drug in freshly isolated renal tubules selegiline-N-oxide was mainly produced. At 100 microM concentration selegiline markedly diminished glucose synthesis in isolated renal tubules incubated with dihydroxyacetone or alanine+glycerol+octanoate (by about 60 and 30%, respectively), while at 5 microM concentration a similar degree of inhibition was achieved in renal tubules grown in primary culture under the same conditions (about 40 and 60%, respectively). Moreover, desmethylselegiline and selegiline-N-oxide considerably diminished glucose production in renal tubules whereas selegiline and its metabolites did not affect gluconeogenesis in hepatocytes. Contrary to control animals, following selegiline administration to alloxan-diabetic rabbits for 8 days (10 mg kg(-1) body wt. daily) the blood glucose and serum creatinine levels were significantly diminished, suggesting a decrease in renal gluconeogenesis and improvement of kidney functions. Since in renal tubules selegiline induced a decline in the intracellular levels of gluconeogenic intermediates and ATP content accompanied by a decrease in oxygen consumption in both kidney-cortex and hepatic mitochondria it seems possible that its inhibitory action on renal gluconeogenesis might result from an impairment of mitochondrial function, while an intensive selegiline metabolism in hepatocytes causes decrease of its concentration and in consequence no inhibition of gluconeogenesis. In view of these observations it is likely that an increased risk of selegiline-induced hypoglycemia might be expected particularly in patients exhibiting an impairment of liver function and following transdermal administration of this drug, i.e. under conditions of increased serum selegiline concentrations.