1. Nerve Function and Oxidative Stress in Diabetic and Vitamin E-Deficient Ratsfn1fn1Grant support: Diabetes Fonds Nederland
- Author
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J. J. M. Marx, P. S. Van Dam, W.H. Gispen, Bert Bravenboer, B. S. Van Asbeck, and J. F. L. M. Van Oirschot
- Subjects
Vitamin ,medicine.medical_specialty ,Antioxidant ,Vitamin E ,medicine.medical_treatment ,medicine.disease_cause ,Malondialdehyde ,Biochemistry ,Lipid peroxidation ,chemistry.chemical_compound ,Endocrinology ,chemistry ,Physiology (medical) ,Internal medicine ,medicine ,Vitamin E deficiency ,Sciatic nerve ,Oxidative stress - Abstract
Nerve dysfunction in diabetes is associated with increased oxidative stress. Vitamin E depletion also leads to enhanced presence of reactive oxygen species (ROS). We compared systemic and endoneurial ROS activity and nerve conduction in vitamin E-depleted control and streptozotocin-diabetic rats (CE− and DE−), and in normally fed control and diabetic animals (CE+ and DE+). Nerve conduction was reduced in both diabetic groups. Vitamin E depletion caused a small further nerve conduction deficit in the diabetic, but not in the control animals. The combination of vitamin E deficiency and streptozotocin-diabetes (group DE−) appeared to be lethal. In the remaining groups, an important rise in sciatic nerve malondialdehyde (MDA) was observed in the vitamin E-depleted control rats. In contrast, plasma MDA levels were elevated in group DE+ only, whereas hydrogen peroxide levels were increased in group CE−. Endoneurial total and oxidized glutathione and catalase were predominantly elevated in group DE+. These data show that nerve lipid peroxidation induced by vitamin E depletion does not lead to reduced nerve conduction or changes in antioxidant concentrations as observed in STZ-diabetes. The marked systemic changes in MDA and antioxidants suggest that nerve dysfunction in experimental hyperglycemia is rather a consequence of systemic than direct nerve damage.
- Published
- 1998
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