Semir Ozdemir

Protective effect of selenium treatment on diabetes-induced myocardial structural alterations

One of the main causes leading to mortality in diabetes is myocardial disease. Using streptozotocin (STZ)-induced diabetic animals, it has been possible to characterize diabetes-induced myocardial abnormalities. Interstitial and microvascular disorders are known to be a characteristic part of the diabetic cardiomyopathy and partly resist insulin therapy. Because diabetic damage is partly attributed to oxidative stress, antioxidant treatment may be able to reduce this damage. The aim of this study was to investigate the cardioprotective effect of sodium selenite, known as an antioxidant agent. The diabetes was induced by ip injection of 50 mg/kg body wt STZ. The duration of diabetes was 5 wk. The protected group received (ip) 5 µmol/kg body wt/d sodium selenite (Na2SeO3) over 4 wk following diabetes induction. Electron and light microscopic morphometry of heart samples revealed typical diabetic alterations consisting in an increase in collagen content, vacuolation, diminishing of the cardiomyocyte diameter, alteration in myofilaments and Z-lines of myofibers, and myofibrillary degeneration. Sodium selenite treatment could prevent the loss of myofibrills and reduction of myocyte diameter. In the sodium-selenite-treated diabetic rat heart, alterations of the discus intercalaris and nucleus were corrected, and degenerations seen in myofilaments and Z-lines were reversed by this treatment. Under these findings, one can suggest that sodium selenite treatment may alleviate late diabetic complications when it is used under control conditions.

Effect of selenite treatment on ultrastructural changes in experimental diabetic rat bones

It is known that streptozotocin (STZ)-induced diabetes causes functional and structural alterations in some types of tissue and organ. A number of methods have been used to characterize the properties of diabetic tissues and their diagnosis. Selenium compounds, playing an antioxidant role, can restore some altered metabolic parameters and diminished functions in experimental diabetes. The first aim of the present study was to investigate the effects of STZ-induced diabetes on structural properties of rat long bones. Electron and light microscopic observations showed deleterious alterations in the structure of the diabetic rat long bones, the most prominent effect being in osteocytic cells. Fine cytoplasmic processes of the osteocytes seemed to be shortened, and diabetes affected the normal cytoplasmic processes in a negative manner. The second aim of the present study was to evaluate the effects of sodium selenite treatment for 4 wk on the long bones of the diabetic rats. Electron and light microscopic observations demonstrated that sodium selenite treatment prevented the STZ-induced structural as well as ultrastructural changes in the long bones of the rats. In conclusion, this study first showed that a period of 5-wk diabetes was enough to cause some important and degenerative changes in the structure of the bone tissues, and, second, it demonstrated that sodium selenite treatment of the diabetic rats could normalize these alterations.

EFFECT OF IMMOBILIZATION AND COLD STRESS ON VISUAL EVOKED POTENTIALS

The main aim of our research was to study the effects of immobilization and/or cold stress on amplitudes and latencies of visual evoked potentials (VEPs) and thiobarbituric acid reactive substances (TBARS). Forty healthy male albino rats, aged three months, were used. The rats were equally divided into four groups: Control group (C), the group exposed to cold stress (CS), the group exposed to immobilization stress (IS), and the group exposed to both cold and immobilization stress (CIS). Plasma corticosterone concentrations were significantly increased in all stress groups. Lipid peroxidation was increased in brain and retina of all stress groups as indicated by the significant increase in TBARS levels compared to the C group. Glutathione peroxidase (GSH-Px) activity in brain and retina increased in the CS group, but decreased in the IS group relative to the C group. GSH-Px activity also increased in the brain, but not in the retina in the CIS group with respect to the C group. The mean latencies of P1, N1, P2, N2, and P3 components were significantly prolonged in all stress groups compared with the C group. The results suggest that stress induced lipid peroxidation may influence VEPs.

Toxic concentrations of selenite shortens repolarization phase of action potential in rat papillary muscle

Selenium (Se) has long been recognized as both an essential mammalian nutrient and a hazardous element. Sodium selenite is commonly used as a dietary supplement for the treatment of Se deficiency. On the other hand, chronic Se toxicity has been demonstrated to affect the major organs, including the heart, in experimental animals.This study examines the effects of high concentrations of extracellular selenite (in the range of 0.001–1 mM) application into the recording bath on the electrical properties of rat papillary muscles. Conventional glass semifloating microelectrodes were used to record intracellular action potentials (APs) in isolated rat papillary muscles. The amplitude of APs and the resting membrane potential of papillary muscles were not changed following a 20-min selenite (1 mM) application compared to the first minute of its application. Freshly isolated ventricular myocytes by an enzymatic method were used to determine the selenite-induced alterations in Na+ currents. Na+ currents, measured at 22°C, by the whole-cell patch-clamp technique, decreased by 38±8% in the presence of 1 mM selenite for 5 min. These selenite-induced effects were not reversed, but are restored by dithiothreitol (1 mM).These results demonstrated that toxic concentrations of selenite induced a significant shortening in AP duration as a result of an increase in the rate of repolarization. Our findings also suggest that a decrease in Na+ currents, in addition to Ca2+ currents, may play a role in the shortening of AP duration in rat papillary muscles.