Microsomal hepatic

Intestinal absorption of digoxin is less complete compared to digitoxin. In order to improve absorption, acetylated- and methylated-digoxin derivates were developed. Digitoxin is metabolised in hepatic microsomal enzymes and can be cleared independently from renal function. The therapeutical serum level of digoxin is 0.5-2.0 ng/ml and 10-35 ng/ml of digitoxin. Steady state plateau of therapeutic plasma concentrations is reached after 4-5 half-life-times using standard daily doses [5]. 

Compounds that affect activities of hepatic microsomal enzymes can antagonize the effects of methyl parathion, presumably by decreasing metabolism of methyl parathion to methyl paraoxon or enhancing degradation to relatively nontoxic metabolites. For example, pretreatment with phenobarbital protected rats from methyl parathion s cholinergic effects (Murphy 1980) and reduced inhibition of acetylcholinesterase activity in the rat brain (Tvede et al. 1989). Phenobarbital pretreatment prevented lethality from methyl parathion in mice compared to saline-pretreated controls (Sultatos 1987). Pretreatment of rats with two other pesticides, chlordecone or mirex, also reduced inhibition of brain acetylcholinesterase activity in rats dosed with methyl parathion (2.5 mg/kg intraperitoneally), while pretreatment with the herbicide linuron decreased acetylcholine brain levels below those found with methyl parathion treatment alone (Tvede et al. 1989). 

Cimetidine, an H2 antagonist used therapeutically in patients with ulcers, inhibits activity of hepatic microsomal enzymes. When rats or mice were pretreated with cimetidine, dose-related lethality of methyl parathion was reduced, and cholinergic signs of toxicity were delayed. Simultaneous administration with methyl parathion did not reduce toxicity (Joshi and Thornburg 1986). 

FIGURE 2.8 Monooxygenase activities of mammals, birds, and fish, (a) Mammals and birds, (b) Mammals, birds, and fish. Activities are of hepatic microsomal monooxygenases to a range of substrates expressed in relation to body weight. Each point represents one species (males and females are sometimes entered separately) (from Walker et al. 2000). 

Two important examples of reductive metabolism of xenobiotics are the reductive dehalogenation of organohalogen compounds, and the reduction of nitroaromatic compounds. Examples of each are shown in Figure 2.13. Both types of reaction can take place in hepatic microsomal preparations at low oxygen tensions. Cytochrome P450 can catalyze both types of reduction. If a substrate is bound to P450 in the... 

Under anaerobic conditions, p,p -DDT is converted to p,p -DDD by reductive dechlorination, a biotransfonnation that occurs postmortem in vertebrate tissues such as liver and muscle and in certain anaerobic microorganisms (Walker and Jefferies 1978). Reductive dechlorination is carried out by reduced iron porphyrins. It is carried out by cytochrome P450 of vertebrate liver microsomes when supplied with NADPH in the absence of oxygen (Walker 1969 Walker and Jefferies 1978). Reductive dechlorination by hepatic microsomal cytochrome P450 can account for the relatively rapid conversion of p,p -DDT to p,p -DDD in avian liver immediately after death, and mirrors the reductive dechlorination of other organochlorine substrates (e.g., CCI4 and halothane) under anaerobic conditions. It is uncertain to what extent, if at all, the reductive dechlorination of DDT occurs in vivo in vertebrates (Walker 1974). 

The anticoagulant rodenticides warfarin and superwarfarins are toxic because they have high affinity for a vitamin K binding site of hepatic microsomes (Chapter 11, Section 11.2.4). In theory, an ideal biomarker would... 

Endoplasmic reticulum Membranous network of cells that contains many enzymes that metabolize xenobiotics. Hepatic microsomes consist mainly of vesicles derived from the endoplasmic reticulum of liver. 

Microsomes Vesicles obtained from homogenized tissues by ultracentrifugation. They are derived mainly from the endoplasmic reticulum in the case of the liver (hepatic microsomes). 

Fent, K. and Bucheli, T.D. (1994). Inhibitors of hepatic microsomal monooxygenase system by organotins in vitro in freshwater fish. Aquatic Toxicology 28, 107-126. 

Hosokawa, M., Maki, T., and Satoh, T. (1987). Mnltiphcity and regnlation of hepatic microsomal carboxylesterases in rats. Molecular Pharmacology 31, 579-584. 

Walker, C.H. (1980). Species variations in some hepatic microsomal enzymes that metabolise xenobiotics. Progress in Drug Metabolism 5, 118-164. 

Table VI lists several drugs Inducing hepatic microsomal enzymes (5). These enzymes can metabolize the drug as well as other substrates. Barbiturates, grlseofulvln, and glutethlmlde Induce enzymes which metabolize coumarln and phenlndlone derivatives and thus reduce their anticoagulant activity. Dlphenylhydantoln and phenylbutazone stimulate cortisol hydroxylase activity and Increase the urinary excretion of B-hydroxy cortisol and decrease the concentration of cortisol In the plasma.

The cytochrome P-450-dependent metabolism of trichloroethylene was studied in hepatic microsomal fractions from 23 different humans (Lipscomb et al. 1997). CYP2E1 was the predominant form of P-450 responsible for the metabolism of trichloroethylene in humans. Incubations of trichloroethylene with the microsomal preparations resulted in hyperbolic plots consistent with Michaelis-Menton kinetics. The values ranged from 12 to 55.7 pM, and were not normally distributed, and the values range from 490 to 3,455 pmol/min/mg protein and were normally distributed. The study authors concluded that the human variability in metabolism of trichloroethylene via P-450-dependent pathways was within a 10-fold range. 

Costa AK, Katz ID, Ivanetich KM. 1980. Trichloroethylene Its interaction with hepatic microsomal cytochrome P-450 in vitro. Biochem Pharmacol 29 433-439. 

CHOI J H, CHA B K and RHEE s J (1998) Effects of green tea catechin on hepatic microsomal phospholipase A2 activities and changes of hepatic phospholipid species in streptozotocin-induced diabetic rats , JNutr Sci Vitaminol (Tokyo), 44 (5), 673-83. 

The metabolism of NPYR is summarized in Figure 1. a-Hy-droxylation (2 or 5.position) leads to the unstable intermediates and decomposition of gives 4-hydroxybutyraldehyde [ ]. The latter, which exists predominantly as the cyclic hemiacetal 1, has been detected as a hepatic microsomal metabolite in rats, hamsters, and humans and from lung microsomes in rats (9-13). The role of 1 and as intermediates in the formation of 6 and 7 is supported by studies of the hydrolysis of 2-acetoxyNPYR and 4-(N-carbethoxy-N-nitrosamino)butanal, which both gave high yields of 7 (9,14). In microsomal incubations, can be readily quantified as its 2,4-dinitrophenylhydrazone derivative (15). The latter has also been detected in the urine of rats treated with NPYR ( ). 

The hepatic microsomal a-hydroxylase activity for NPYR is inducible in rats by pretreatment with Aroclor, and in hamsters by pretreatment with Aroclor, 3-methylcholanthrene, phenobarbi-tal, and ethanol (10,15,19). In contrast, pretreatment of rats with 3-methylcholanthrene or phenobarbital causes no change or a slight decrease in microsomal NPYR o-hydroxylase activity (19). 

Dady JM, SP Bradbury, AD Hoffman, MM Voit, DL Olson (1991) Hepatic microsomal Al-hydroxylation of aniline and 4-chloroaniline by rainbow trout (Oncorhyncus mykiss). Xenobiotica 21 1605-1620. 

Little PJ, MO James, JB Pritchard, JR Bend (1984) Benzo(a)pyrene metabolism in hepatic microsomes from feral and 3-methylcholanthrene-treated southern flounder, Paralichthys lethostigma. J Environ Pathol Toxicol Oncol 5 309-320. 

Like other xenobiotics, cannabinoids also undergo extensive metabolism in the human body to increase their hydrophihc properties for a facihtated ehmination. The metaboHsm of A9-THC has been very well investigated. More than 100 metabolites of A9-THC are known [99] and a good overview of the most important human metaboHtes is given in [100]. MetaboHsm takes place mainly in hepatic microsomes, but also in intestines, brain. 

Cheeseman, K.H., Proudfoot, K., Maddix, S.P., Collins, M.M., Milia, A. and Slater, T.F. (1985). Low rate of NADPH/ADP-iron dependent lipid peroxidation in hepatic microsomes of DBA/2 mice. FEBS Lett. 184, 343-346. 

Carbamazepine is a potent inducer of hepatic microsomal enzymes. Not only does it increase the rate of metabolism for many other drugs, it increases the rate of its own metabolism. Hepatic enzymes become maximally induced over several weeks, necessitating a small initial dose of carbamazepine that... 

As noted above, many of the AEDs induce hepatic microsomal enzyme systems and thus reduce the effectiveness of hormonal contraceptives. Women taking AEDs that may reduce the effectiveness of hormonal contraceptives should be encouraged to also use other forms of birth control. Due to induction or inhibition of sex hormone metabolism and changes in binding of hormones to sex hormone binding globulin, some AEDs may reduce fertility. For example, valproate has been associated with a drug-induced polycystic ovarian syndrome. Women who experience difficulties with fertility should seek the advice of health care professionals with expertise in fertility. 

J. Aranda, S. MacLeod, K. Renton, and N. Eade, Hepatic microsomal drug oxidation and electron transport in newborn infants, J. Pediatr, 85, 534 (1974). 

Some OC pesticides can induce the hepatic microsomal enzyme system (Kay, 1970). Tests measuring functions related to these enzymes, such as f.i. D-glucaric acid and 6-b-hydroxicortisol excretion in urine, can be applied to monitor occupational OC exposure. 

Kupfer D, Levin E and Burstein SH (1973). Studies on the effects of tetrahydrocannabinol and ddt on the hepatic microsomal metabolism of the and other compounds in the rat. Chemical-Biological Interactions, 6, 59-66. 

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