Liver carbon tetrachloride

Necrosis and fatty liver Carbon tetrachloride Ethanol... 

Hepatic Hepatic means "pertaining to the liver." For example, hepatitis is inflammation of the liver. Liver disorders are sometimes marked by jaundice, a yellowish coloration to the whites of the eyes and skin. Certain chemicals are hepatotoxins (toxic to the liver), usually as a result of chronic exposure. One example is carbon tetrachloride (CCI4). 

Carbon tetrachloride zero 0.005 Liver problems increased risk of cancer Discharge from chemical plants and other industrial activities... 

Yellow phosphorus was the first identified liver toxin. It causes accumulation of lipids in the liver. Several liver toxins such as chloroform, carbon tetrachloride, and bromobenzene have since been identified. I he forms of acute liver toxicity are accumulation of lipids in the liver, hepartxiellular necrosis, iii-trahepatic cholestasis, and a disease state that resembles viral hepatitis. The types of chrome hepatotoxicity are cirrhosis and liver cancer. 

Acute Liver Damage Several compounds (e.g., dimethyl iiitrosoamine, carbon tetrachloride, and thioacetamide) cause necrosis of hepatocytes by inhibiting pro tein syndiesis at the translational level, i.e., by inhibiting the addition of new amino adds into the protein chain being sjTithetized. This is not, however, the only mechanism. Ethioiiine is a compound which inhibits protein synthesis bur doe not induce... 

Liver cancer can also be a consequence of exposure to hepatotoxic chemicals. Natural hepatocarcinogens include fungal aflatoxins. Synthetic hepato-carcinogens include nitrosoamines, certain chlorinated hydrocarbons, polychlorinated biphenyls (PCBs), chloroform, carbon tetrachloride, dimethyl-benzanthracene, and vinyl chloride.Table 5.15 lists the chemical compounds that induce liver cancer or cirrhosis in experimental animals or... 

One type of fatty liver that has been smdied extensively in rats is due to a deficiency of choline, which has therefore been called a lipotropic factor. The antibiotic puromycin, ethionine (a-amino-y-mercaptobu-tyric acid), carbon tetrachloride, chloroform, phosphorus, lead, and arsenic all cause fatty liver and a marked reduction in concentration of VLDL in rats. Choline will not protect the organism against these agents but appears to aid in recovery. The action of carbon tetrachloride probably involves formation of free radicals... 

Unconjugated hyperbilirubinemia can result from toxin-induced liver dysfunction such as that caused by chloroform, arsphenamines, carbon tetrachloride, acetaminophen, hepatitis virus, cirrhosis, and Amanita... 

Galati, E.M. et al., Opuntia jicus indica (L.) Mill fruit juice protects liver from carbon tetrachloride-induced injury, Phytother. Res., 19, 796, 2005. 

The identification and quantification of potentially cytotoxic carbonyl compounds (e.g. aldehydes such as pentanal, hexanal, traw-2-octenal and 4-hydroxy-/mAW-2-nonenal, and ketones such as propan- and hexan-2-ones) also serves as a useful marker of the oxidative deterioration of PUFAs in isolated biological samples and chemical model systems. One method developed utilizes HPLC coupled with spectrophotometric detection and involves precolumn derivatization of peroxidized PUFA-derived aldehydes and alternative carbonyl compounds with 2,4-DNPH followed by separation of the resulting chromophoric 2,4-dinitrophenylhydrazones on a reversed-phase column and spectrophotometric detection at a wavelength of378 nm. This method has a relatively high level of sensitivity, and has been successfully applied to the analysis of such products in rat hepatocytes and rat liver microsomal suspensions stimulated with carbon tetrachloride or ADP-iron complexes (Poli etui., 1985). 

Poli, G., Dianzani, M.U., Cheeseman, K.H., Slater, T.F., Lang, J. and Esterbauer, H. (1985). Separation and characterization of the aldehydic products of lipid peroxidation stimulated by carbon tetrachloride or ADP-iron in isolated rat hepatocytes and rat liver microsomal suspensions. Biochem. J. 227, 629-638,... 

The production of free radicals has been implicated in the mechanism of liver injury due to a number of drugs and toxins. These include adtiamycin (Pritsos et al., 1992), halothane (Neuberger and Williams, 1984), phenobar-bital and thiopental (Kanazawa and Ashida, 1991), carbon tetrachloride (Williams and Burk, 1990), 1,1,2,2-tetrachloroethane (Paolini aal., 1992), and paraquat and related bipyridylium compounds (Togashi a al., 1990 De Gray etal., 1991 Kanazawa and Ashida, 1991 Petty etal., 1992). 

Williams, A.T. and Burk, R.F. (1990). Carbon tetrachloride hepatotoxicity, an example of free radical-mediated injury. Semin. Liver Dis. 10, 279-284. 

Albano, E., Lott, K.A.K., Slater, T.F., Stier, A., Symons, M.C.R.and Tomasi, A. (1982). Spin trapping studies on the free radical products formed by metabolic activation of carbon tetrachloride in rat liver microsomal fractions, isolated hepato-cytes and in vivo in the rat. Biochem. J. 204, 593-603. 

Comporti, M., Saccocci, C. and Dianzani, M.U. (1965). EfiFect of carbon tetrachloride in vitro and in vivo on lipid peroxidation of rat liver homogenates and subcellular fractions. Enzymologja 29, 185-204. 

ElSisi, A.E.D., Earnest, D.L. and Sipes, LG. (1993b). Vitamin-A potentiation of carbon tetrachloride hepatotoxicity-role of liver macroph es and active oxygen species. Toxicol. Appl. Pharmacol. 119, 295-301. 

Le Page, KN., Cheeseman, K.H., Osman, N. and Slater, T.F. (1988). Lipid peroxidation in purified plasma membrane fractions of rat liver in relation to the toxicity of carbon tetrachloride. Cell Biochem. Function 6, 87-99. 

Reynolds, E.S. (1967). Liver parenchymal cell injury IV Pattern of incorporation of carbon and chlorine atoms from carbon tetrachloride into chemical constituents of liver in vivo. J. Pharmacol. Exp. Therap. 155, 117-126. 

Slater, T.F. (1967). Stimulatory effects of carbon tetrachloride in vim on lipid peroxidation in rat liver microsomes. Proc. 4th FEBS Meeting, Oslo, abstract no. 216, 67. 

Slater, T.F. (1968). The inhibitory effects in vitro of phenothia-zines and other drugs on lipid-peroxidation systems in rat liver microsomes, and their relationship to the liver necrosis produced by carbon tetrachloride. Biochem. J. 106, 155-160. 

The most critical decision to be made is the choice of the best solvent to facilitate extraction of the drug residue while minimizing interference. A review of available solubility, logP, and pK /pKb data for the marker residue can become an important first step in the selection of the best extraction solvents to try. A selected list of solvents from the literature methods include individual solvents (n-hexane, " dichloromethane, ethyl acetate, acetone, acetonitrile, methanol, and water ) mixtures of solvents (dichloromethane-methanol-acetic acid, isooctane-ethyl acetate, methanol-water, and acetonitrile-water ), and aqueous buffer solutions (phosphate and sodium sulfate ). Hexane is a very nonpolar solvent and could be chosen as an extraction solvent if the analyte is also very nonpolar. For example, Serrano et al used n-hexane to extract the very nonpolar polychlorinated biphenyls (PCBs) from fat, liver, and kidney of whale. One advantage of using n-hexane as an extraction solvent for fat tissue is that the fat itself will be completely dissolved, but this will necessitate an additional cleanup step to remove the substantial fat matrix. The choice of chlorinated hydrocarbons such as methylene chloride, chloroform, and carbon tetrachloride should be avoided owing to safety and environmental concerns with these solvents. Diethyl ether and ethyl acetate are other relatively nonpolar solvents that are appropriate for extraction of nonpolar analytes. Diethyl ether or ethyl acetate may also be combined with hexane (or other hydrocarbon solvent) to create an extraction solvent that has a polarity intermediate between the two solvents. For example, Gerhardt et a/. used a combination of isooctane and ethyl acetate for the extraction of several ionophores from various animal tissues. 

On the other hand, microsomes may also directly oxidize or reduce various substrates. As already mentioned, microsomal oxidation of carbon tetrachloride results in the formation of trichloromethyl free radical and the initiation of lipid peroxidation. The effect of carbon tetrachloride on microsomes has been widely studied in connection with its cytotoxic activity in humans and animals. It has been shown that CCI4 is reduced by cytochrome P-450. For example, by the use of spin-trapping technique, Albani et al. [38] demonstrated the formation of the CCI3 radical in rat liver microsomal fractions and in vivo in rats. McCay et al. [39] found that carbon tetrachloride metabolism to CC13 by rat liver accompanied by the formation of lipid dienyl and lipid peroxydienyl radicals. The incubation of carbon tetrachloride with liver cells resulted in the formation of the C02 free radical (identified as the PBN-CO2 radical spin adduct) in addition to trichoromethyl radical [40]. It was found that glutathione rather than dioxygen is needed for the formation of this additional free radical. The formation of trichloromethyl radical caused the inactivation of hepatic microsomal calcium pump [41]. 

A number of early in vitro studies demonstrated a considerable role of free radicals in liver injury (see, for example, Proceedings of International Meeting on Free Radicals in Liver Injury [341]). Later on, it was shown that chronic inflammation in the liver-induced oxidative DNA damage stimulated chronic active hepatitis and increased the risk of hepatocarcinogenesis [342,343]. Farinati et al. [344] showed that 8-OHdG content increased in circulating leukocytes of patients with chronic hepatitis C virus (HCV) infection. DNA oxidative damage is supposedly an early event of HCV-related hepatitis. The formation of isoprostanes in the liver of carbon tetrachloride-treated rats can be suppressed by the administration of vitamin E [345],... 

Chlordane interacts with other chemicals to produce additive or more-than-additive toxicity. For example, chlordane increased hepatotoxic effects of carbon tetrachloride in the rat (USEPA 1980 WHO 1984), and in combination with dimethylnitrosamine acts more than additively in producing liver neoplasms in mice (Williams and Numoto 1984). Chlordane in combination with either endrin, methoxychlor, or aldrin is additive or more-than-additive in toxicity to mice (Klaassen et al. 1986). Protein deficiency doubles the acute toxicity of chlordane to rats (WHO 1984). In contrast, chlordane exerts a protective effect against several organophosphorus and carbamate insecticides (WHO 1984), protects mouse embryos against influenza virus infection, and mouse newborns against oxazolone delayed hypersensitivity response (Barnett et al. 1985). More research seems warranted on interactions of chlordane with other agricultural chemicals. 

Panduro, A., et al., Transcriptional switch from albumin to alpha-fetoprotein and changes in transcription of other genes during carbon tetrachloride induced liver regeneration, Biochemistry, 25, 1986. 

The hexachloroethane that enters your bloodstream will go to your liver where it is turned into other compounds. Some of these compounds are harmful and will affect your health in almost the same way hexachloroethane does. If you are exposed to carbon tetrachloride, your liver can make hexachloroethane from it. 

Hexachloroethane distributes preferentially to the adipose tissue. Relatively high concentrations are also found in male rat kidneys. Moderate concentrations of hexachloroethane are found in the liver, female kidney, and blood and small amounts in muscle, lungs, and brain. If the hexachloroethane is generated endogenously from carbon tetrachloride, the concentration in the rat liver exceeds that in the kidneys. 

No other studies of interactions of hexachloroethane with other chemicals were identified in the published literature. However, the primary metabolites of hexachloroethane (tetrachloroethene and pentachloroethane) are themselves toxic and would be expected to exacerbate hexachloroethane toxicity if they were present in a mixture with hexachloroethane. Concurrent carbon tetrachloride exposure would also be expected to exacerbate hexachloroethane toxicity. Both hexachloroethane and carbon tetrachloride are processed by microsomes to generate free radicals, and carbon tetrachloride also forms endogenous hexachloroethane in the liver (Fowler 1969a). 

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