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Query: UMLS:C0042875 (
vitamin E deficiency
)
916
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
The possible aggravation of liver injury by impaired cellular antioxidant function was investigated. A vitamin E-deficient diet (0.5 mg/kg alpha-tocopherol; control 100 mg/kg) significantly reduced rat liver alpha-tocopherol concentrations after 4 weeks (1.8 +/- 1.7 micrograms/g; control 34.4 +/- 2.4 micrograms/g, p < 0.001). The effects of copper loading (Cu, 3 g/kg diet); galactosamine (GalN, 0.85 g/kg i.p.); or carbon tetrachloride (
CCl4
, 10 mmol/kg i.p.) were examined. Serum aspartate transaminase activity was elevated slightly by
vitamin E deficiency
but not by hepatic copper accumulation. In vitamin E-replete (E+) and vitamin E-deficient (E-) rats, GalN or
CCl4
caused a large and comparable elevation in serum AST and OCT activity. This effect on AST was markedly reduced by copper loading in vitamin E replete (E+) rats, but in E(-) rats copper had significantly less protective effect. Copper also diminished the OCT response to GalN in E+, though not E-, rats. A significant rise in total hepatic alpha-tocopherol content followed administration of GalN or
CCl4
in both normocupric and copper-laden E(-) rats. Thus alpha-tocopherol deficiency (a) was not hepatotoxic per se; (b) failed to potentiate the toxicity of copper, GalN or CCL4; but (c) partially abolished the protection by copper against toxin-induced liver injury. Retention of hepatic alpha-tocopherol after liver damage may partly explain low serum vitamin E levels seen in clinical liver disease.
...
PMID:Alpha-tocopherol deficiency fails to aggravate toxic liver injury but liver injury causes alpha-tocopherol retention. 148 10
Malondialdehyde (MDA) derivatives occur as normal constituents of rat and human urine. In a previous study, it was found that MDA excretion in rats is responsive to MDA intake and to certain factors that increase lipid peroxidation in vivo:
vitamin E deficiency
, iron administration and a high concentration of cod liver oil (CLO) fatty acids in the tissues. In the present study, the effect on MDA excretion of several additional dietary and endogenous factors was evaluated. The composition of dietary fatty acids had a major influence on MDA excretion in fed animals, being highest for animals fed n-3 fatty acids (20:5 and 22:6) from CLO, intermediate for those fed n-6 (18:2) acids from corn oil (CO) and lowest for those fed saturated acids from hydrogenated coconut oil (HCO). Diet was the main source of urinary MDA in all groups. Fasting produced a marked increase in urinary MDA, which tended to be higher in rats previously fed CLO. Fasting MDA excretion was not affected by the level of CO in the diet (5, 10 or 15%), indicating that feeding n-6 acids does not increase lipid peroxidation in vivo. Adrenocorticotropic hormone and epinephrine administration increased urinary MDA, further indicating that lipolysis either releases fatty acid peroxides from the tissues or increases the susceptibility of mobilized fatty acids to peroxidation. A decrease in fasting MDA excretion was observed in rats previously fed a high level of antioxidants (vitamin E + BHT + vitamin C) vs a normal level of vitamin E. MDA excretion increased following adriamycin and
CCl4
administration.(ABSTRACT TRUNCATED AT 250 WORDS)
...
PMID:Response of urinary malondialdehyde to factors that stimulate lipid peroxidation in vivo. 282 43
Interest in malondialdehyde (MDA) metabolism stems from its formation as a product of lipid peroxidation in the diet and in the tissues; its reactivity with functional groups of nucleic acid bases, proteins and phospholipids; its mutagenicity in bacteria, and its reported skin and liver carcinogenicity in animals. Administration of the Na enol salt of MDA in the drinking water of mice over a range of 0.1-10.0 micrograms/g/day for 12 mo produced dose-dependent hyperplastic and neoplastic changes in liver nuclei and increased mortality at the highest level but produced no gross hepatic tumors. Addition of MDA to the medium of rat skin fibroblasts grown in culture caused nuclear abnormalities at concentrations as low as 10(-6) M despite an uptake of only 4%. [1,3-14C]MDA was rapidly oxidized to [14C]acetate in rat liver mitochondria and to 14CO2 in vivo; however, approximately 10% of the radioactivity was recovered in the urine. Chromatographic analysis of rat urine revealed the presence of several compounds which yield MDA on acid hydrolysis. Total MDA excretion increased in response to conditions which stimulate lipid peroxidation in vivo, including
vitamin E deficiency
, Fe or
CCl4
administration, and enrichment of the tissues with PUFA. N-acetyl-e-(2-propenal)lysine was identified as a major urinary metabolite of MDA in rat and human urine. This compound is derived primarily from N-alpha-(2-propenal)lysine released in digestion as a product of reactions between MDA and the epsilon-amino groups of N-terminal lysine residues in food proteins. However, its presence in the urine of animals fasted or fed MDA-free diets indicates that it is also formed in vivo.(ABSTRACT TRUNCATED AT 250 WORDS)
...
PMID:The metabolism of malondialdehyde. 371 50
Although malondialdehyde (MDA) is extensively metabolized to CO2, small amounts are nevertheless excreted in an acid-hydrolyzable form in rat urine. In this study, urinary MDA was evaluated as an indicator of lipid peroxidation in the diet and in the tissues. MDA was released from its bound form(s) in urine by acid treatment and determined as the TBA-MA derivative by HPLC. MDA excretion by the rat was found to be responsive to oral administration of the Na enol salt and to peroxidation of dietary lipids. Urinary MDA also increased in response to the increased lipid peroxidation in vivo produced by
vitamin E deficiency
and by administration of iron nitrilotriacetate. Chronic feeding of a diet containing cod liver oil led to increases in MDA excretion which were not completely eliminated by fasting or feeding a peroxide-free diet, indicating that there was increased lipid peroxidation in vivo. MDA excretion was not responsive to Se deficiency or
CCl4
administration. DPPD, a biologically active antioxidant, but not BHA, a non-biologically active antioxidant, prevented the increase in MDA excretion in vitamin E deficient animals. The results indicate that MDA excretion can serve as an indicator of the extent of lipid peroxidation in the diet and, under conditions which preclude a dietary effect, as an index of lipid peroxidation in vivo.
...
PMID:Urinary malondialdehyde as an indicator of lipid peroxidation in the diet and in the tissues. 652 8
The effect of age and peroxidative stress on the concentration of a deoxyguanosine malondialdehyde adduct (dG-MDA) in rat tissues was investigated.
Vitamin E deficiency
had no effect on the dG-MDA content of liver DNA in rats fed a diet containing 10% corn oil. When 2% cod liver oil was added to this diet, the dG-MDA content of liver DNA doubled in the positive controls fed a high level of vitamin E (100 ppm dl-alpha-tocopherol), and there was a further increase when vitamin E was deleted. Neither iron nitrilotriacetate administration nor choline deficiency had any effect on the dG-MDA content of liver DNA.
Carbon tetrachloride
had a lowering effect. The failure of iron or carbon tetrachloride administration and of
vitamin E deficiency
to increase liver dG-MDA is consistent with their failure in previous experiments to affect the urinary excretion of dG-MDA. In contrast, these forms of peroxidative stress produce large increments in the urinary excretion of MDA adducts with lysine, reflecting increased formation and degradation of MDA-modified proteins. DNA appears to be protected from modification by MDA produced at extranuclear sites. The frequency of dG-MDA in different tissues of 4-month-old rats varied markedly: brain >> liver > kidneys and testes. Higher concentrations of dG-MDA were found in the liver and kidneys, but not the testes, of 25-month-old rats. The determinants of the concentration of dG-MDA in DNA merit further investigation.
...
PMID:Effects of peroxidative stress and age on the concentration of a deoxyguanosine-malondialdehyde adduct in rat DNA. 853 85
Vitamin E deficiency
in organism leads to microsome membrane phospholipid composition changes, oxidation, superoxide dismutase (SOD) activity decrease, accompanied with the disorders of lung and liver tissues functional state which is connected with regulation of membrane penetration. The negative effect of E-hypovitaminosis more affects the liver than lung, which is caused by their different functional purposes, peculiarities of metabolic processes as well as by the content of biomembrane structural components. Vitamin E protects phospholipids from oxidation, regulates AOS condition, SOD-activity and promotes in such way the tissue functional disturbances correction of the animals tested. New preparation "Calmophyl" is a phospholipid complex from marine organisms with surfactant-kind effect, which displays antioxidative properties and decreases toxic affect of
CCl4
, corrects functional tissue disorders, regenerates normal activity of enzymes. Preparation of natural phospholipids has been shown to be capable to stabilize cell membranes probably by means of replacing the membrane phospholipid composition and decreasing disturbances in the antioxidative system.
...
PMID:[Role of phospholipids in functionally different cell membranes under conditions of antioxidant system disturbance]. 875 1
