Quantitative ultrastructural analysis of hepatoprotective effects of (+)-cyanidanol-3 on alcoholic liver damage

Green tea extract alleviates arsenic-induced biochemical toxicity and lipid peroxidation in rats

The present work was undertaken to evaluate the protective effect of an aqueous extract of green tea (GT, Camellia sinensis) leaves against arsenic (NaAsO2)-induced biochemical toxicity and lipid peroxidation production in experimental rats. The treatment with arsenic exhibited a significant increase in some serum hepatic and renal biochemical parameters (alanine aminotransferase, aspartate aminotransferase, alkaline phosphatase, total protein, albumin, bilirubin, cholesterol, urea and creatinine). But the co-administration of GT has increased the level of plasmatic concentration of biochemical parameters. Exposure of rats to arsenic caused also a significant increase in liver, kidney and testicular thiobarbituric acid reactive substances compared to control. However, the co-administration of GT was effective in reducing its level. To conclude, our data suggest that arsenic exposure enhanced an oxidative stress by disturbing the tissue antioxidant defense system, but the GT co-administration alleviates the toxicity induced by arsenic exposure.

Parameters characterizing acid-base equilibria between cell membrane and solution and their application to monitoring the effect of various factors on the membrane

The cell membrane is an extremely complicated object. It participates in a large number of equilibria. For this reason, it is impossible to determine the parameters of all of them. It is the purpose of this work to define a limited number of averaged parameters in order to describe the equilibria between cell membrane components and environmental components. These parameters are the total acidic functional group concentration as well as the basic group concentration and their association constants with hydrogen or hydroxyl ions. The parameters were determined using the pH dependence of the electric surface charge density. The usefulness of these parameters was checked by studying the effect of green tea on liver cells in ethanol poisoning. Ethanol provokes an increase in concentration of functional groups, positively and negatively charged, as well as an increase in the basic groups association constant and a decrease in acidic groups association constant. Administering green tea partly compensates the changes provoked by ethanol poisoning. The parameters proposed in this work, C(TA), C(TB), K(AH) and K(BOH), are suited for monitoring the changes caused by various factors.

Green tea protects against ethanol-induced lipid peroxidation in rat organs

Ethanol metabolism is accompanied by generation of free radicals, which stimulates lipid peroxidation. Natural antioxidants are particularly useful in such a situation. The current study was designed to investigate the efficacy of green tea, as a source of water-soluble antioxidants (catechins), on lipid peroxidation in liver, brain, and blood induced by chronic (4 weeks) ethanol intoxication in rats. Feeding of ethanol led to a significant increase in lipid peroxidation, as measured by increased concentrations of lipid hydroperoxides, 4-hydroxynonenal, and malondialdehyde. Feeding of ethanol also changed the glutathione-dependent lipid hydroperoxide decomposition system, resulting in a decrease in both reduced glutathione concentration and activity of glutathione peroxidase. Observed changes were statistically significant in all examined tissues. Enhancement in lipid peroxidation was associated with disruption of hepatocyte cell membranes, as observed through electron microscopic evaluation. Green tea protects phospholipids from enhanced peroxidation and prevents changes in biochemical parameters and morphologic changes observed after ethanol consumption. These results support the suggestion that green tea protects membranes from peroxidation of lipids associated with ethanol consumption.

Stereospecificity in membrane effects of catechins

Green tea catechins consisting of catechin stereoisomers and their derivatives have been suggested to show biological activities through the interactions with cellular membranes. Their effects on membrane fluidity were comparatively studied by measuring fluorescence polarization of liposomal membranes prepared with phospholipids and cholesterol. All catechin stereoisomers reduced membrane fluidity by acting on the hydrophilic and hydrophobic regions of membrane bilayers at 20-500 microM. Both epicatechins in a cis form were more effective for reducing membrane fluidity than both catechins in a trans form. (-)-Epicatechin, (+)-epicatechin, (-)-catechin and (+)-catechin reduced membrane fluidity in increasing order of intensity. Such difference between optical isomers was increased by chiral cholesterol added to membrane lipids. In reversed-phase chromatographic evaluation, (-)-epicatechin and (+)-epicatechin were more hydrophobic than (-)-catechin and (+)-catechin, although hydrophobicity was not distinguishable between optical isomers. Stereospecificity in the membrane effects of catechin stereoisomers may be induced by the different hydrophobicity of geometrical isomers and the chirality of membrane lipid components. At lower concentrations (5-100 microM), (-)-epigallocatechin gallate and (-)-epicatechin gallate reduced membrane fluidity more significantly than (-)-epicatechin, suggesting that the intensive membrane effect contributes to the potent medicinal utility of (-)-epigallocatechin gallate.

Determination of (+)-catechin in plasma by high-performance liquid chromatography using fluorescence detection

A high-performance liquid chromatographic method, using fluorescence detection, was developed for the determination of (+)-catechin in rabbit plasma. The procedure involved the precipitation of plasma protein using acetonitrile, followed by solid-phase adsorption onto alumina. After washing with water and methanol, the residue was vortex-mixed with perchloric acid solution to release the adsorbed (+)-catechin. Separation was performed on a reversed-phase column using an eluent consisting of phosphoric acid solution with 12% acetonitrile. The excitation and emission wavelengths were set at 280 and 310 nm, respectively. The retention times for (+)-catechin and the internal standard (deoxyhigenamine) were 6.87 and 8.47 min respectively, without any interference. Validations of accuracy and precision were satisfactory in both within- and between-run assays. All coefficients of variance were less than 6% and mean relative errors were within +/- 3.75%. The average recovery was 73.77%. The limit of detection and quantitation were 1 ng and 0.02 micrograms/ml, respectively. Application of this method was successfully assessed by intravenous administration of a 15 mg/kg dose of (+)-catechin in rabbits. This new method provides a simple, specific and sensitive determination for (+)-catechin in rabbit plasma and is suitable for pharmacokinetic studies.

Alterations in mitochondrial function and morphology in chronic liver disease: pathogenesis and potential for therapeutic intervention

Studies assessing mitochondrial function and structure in livers from humans or experimental animals with chronic liver disease, including liver cirrhosis, revealed a variety of alterations in comparison with normal subjects or control animals. Depending on the etiology of chronic liver disease, the function of the electron transport chain and/or ATP synthesis was found to be impaired, leading to decreased oxidative metabolism of various substrates and to impaired recovery of the hepatic energy state after a metabolic insult. Changes in mitochondrial structure include megamitochondria with reduced cristae, dilatation of mitochondrial cristae and crystalloid inclusions in the mitochondrial matrix. The most important strategies to maintain an adequate mitochondrial function per liver are mitochondrial proliferation and increases in the activity of critical enzymes or in the content of cofactors per mitochondrion. Possibilities to assess hepatic mitochondrial function and to treat mitochondrial dysfunction in patients with chronic liver disease are discussed.

Understanding the role of oxyradicals in general and in toxic hepatic damage can help safer drug design

The existence and importance of free radicals are well established both theoretically and in in vivo experiments. Methods and techniques are now available to demonstrate the formation of free radical metabolites of natural substances and xenobiotics. Theories of the biological effects of free radicals could be unified and used for a better understanding of the complex processes of the organism. Pharmacology can gain profit from this multidisciplinary approach, which helps to design safer drugs. The theories of free radicals and the results of experiments with antioxidants could help to decrease the oxidative stress caused by pharmaceutical chemicals.

How can free radicals cause damage to hepatic cells. A multidisciplinary approach

Excessive alcohol intake is a factor in a significant percentage of all deaths. Hepatoprotective drugs aim to prevent alcoholic liver damage. Our experiments with antioxidant free radical scavengers also proved that such chemicals are hepatoprotectives. Free radical reactions play a significant role in many biological phenomena such as aging and toxic liver cell damage. Different disciplines support theories to interpret their effects. In this paper, theories are summarized as a multidisciplinary approach which can provide further explanation and challenge further investigation on alcoholic liver damage and hepatoprotection.