Esterases metabolism

Following oral administration of radiolabeled fosinopril to humans, approximately 75% of the dose in plasma and urine was present as fosino-prilat. The remainder was a P-glucuronide (15-20%) and a monohydrox-ylated metabolite of fosinoprilat (148). In dogs, esterase metabolism was observed mainly in the gut wall and to a lesser extent in the liver (149). When given orally to humans in capsules, the oral absorption of fosinopril sodium averaged 36% and that of fosinoprilat 29% (148). 

FIG. 4. Metabolic. scheme for the oxidative and B-esterase metabolism of carbaryl to the ring and side chain hydroxylaied methyl carbamates and the major metabolite a-naphthol. 

Esmolol is iv adrninistered. Maximal P-adrenoceptor blockade occurs in 1 min. Its elimination half-life is about 9 min. EuU recovery from P-adrenoceptor blockade is within 30 min after stopping the infusion. The therapeutic plasma concentrations are 0.4—1.2 lg/mL. It is metabolized by hydrolysis in whole blood by red blood cell esterases resulting in the formation of a primary acid metabohte and free methanol. The metabohte is pharmacologically inactive. The resulting methanol levels are not toxic. Esmolol is 55% bound to plasma protein, the acid metabohte only 10%. Less than 2% of parent dmg and the acid metabohte are excreted by the kidneys. Plasma levels may be elevated and elimination half-hves prolonged in patients with renal disease (41). 

The microsomal fraction consists mainly of vesicles (microsomes) derived from the endoplasmic reticulum (smooth and rough). It contains cytochrome P450 and NADPH/cytochrome P450 reductase (collectively the microsomal monooxygenase system), carboxylesterases, A-esterases, epoxide hydrolases, glucuronyl transferases, and other enzymes that metabolize xenobiotics. The 105,000 g supernatant contains soluble enzymes such as glutathione-5-trans-ferases, sulfotransferases, and certain esterases. The 11,000 g supernatant contains all of the types of enzyme listed earlier. 

The organophosphorons insecticides dimethoate and diazinon are mnch more toxic to insects (e.g., housefly) than they are to the rat or other mammals. A major factor responsible for this is rapid detoxication of the active oxon forms of these insecticides by A-esterases of mammals. Insects in general appear to have no A-esterase activity or, at best, low A-esterase activity (some earlier stndies confnsed A-esterase activity with B-esterase activity) (Walker 1994b). Diazinon also shows marked selectivity between birds and mammals, which has been explained on the gronnds of rapid detoxication by A-esterase in mammals, an activity that is absent from the blood of most species of birds (see Section 23.23). The related OP insecticides pirimiphos methyl and pirimiphos ethyl show similar selectivity between birds and mammals. Pyrethroid insecticides are highly selective between insects and mammals, and this has been attributed to faster metabolic detoxication by mammals and greater sensitivity of target (Na+ channel) in insects. 

Emphasis is given to the critical role of metabolism, both detoxication and activation, in determining toxicity. The principal enzymes involved are described, including monooxygenases, esterases, epoxide hydrolases, glutathione-5 -transferases, and glucuronyl transferases. Attention is given to the influence of enzyme induction and enzyme inhibition on toxicity. 

The metabolism of permethrin will be taken more generally as an example of the metabolism of pyrethroids (Figure 12.2). The two types of primary metabolic attack are by microsomal monooxygenases and esterases. Monooxygenase attack involves... 

The growth requirements outlined above express themselves in growth itself through the less tangible but fundamental necessity of energy which is provided by metabolism. Not all metabolic reactions, however, provide energy esterase activity is an example of one that does not. 

In media selective for enterobacteria a surface-active agent is the main selector, whereas in staphylococcal medium sodium and lithium chlorides are the selectors staphylococci are tolerant of salt concentrations to around 7.5%. Mannitol salt, Baird-Parker (BP) and Vogel-Johnson (VJ) media are three examples of selective staphyloccocal media. Beside salt concentration the other principles are the use of a selective carbon source, mannitol or sodium pyruvate together with a buffer plus acid-base indicator for visualizing metabolic activity and, by inference, growth. BP medium also contains egg yolk the lecithin (phospholipid) in this is hydrolysed by staphylococcal (esterase) activity so that organisms are surrounded by a cleared zone in the otherwise opaque medium. The United States Pharmacopeia (1990) includes a test for staphylococci in pharmaceutical products, whereas the British Pharmacopoeia (1993) does not. 

Pharmaeokinetie properties of the cephalosporins depend to a considerable extent on their ehemieal nature, e.g. the substituent R. The 3-acetoxymethyl compounds such as cephalothin, cephapirin and cephacetrile are converted in vivo by esterases to the antibaeterially less aetive 3-hydroxymethyl derivatives and are excreted partly as such. The rapid exeretion means that such cephalosporins have a short half-life in the body. Replaeement of the 3-acetoxymethyl group by a variety of groups has rendered other eephalosporins mueh less prone to esterase attack. For example, cephaloridine has an internally eompensated betaine group at position 3 (R ) and is metabolically stable. 

The above scheme satisfies much of the metabolic data however, some of it is speculative, and it is certainly incomplete. The evidence for the formation of the a-hydroxylated intermediate is circumstantial. The acetate ester of a-hydroxylated dimethylnitrosamine has been prepared (12.13) and has been found to be a potent, directly acting carcinogen (14). Other esters of a variety of a-hydroxylated nitros-amines have also been prepared (15). While it has been shown that DMN acetate is hydrolyzed to hydroxymethylmethyl-nitrosamine by an esterase enzyme, it has been pointed out that these derivatives of the a-hydroxylated nitrosamines also dissociate to N-nitrosoimmonium ions (15 16). 

The assessment of clearance is complicated by the numerous mechanisms by which compounds may be cleared from the body. These mechanisms include oxidative metabolism, most commonly by CYP enzymes, but also in some cases by other enzymes including but not limited to monoamine oxidases (MAO), flavin-containing monooxygenases (FMO), and aldehyde oxidase [45, 46], Non-oxidative metabolism such as conjugation or hydrolysis may be effected by enzymes such as glucuronyl transferases (UGT), glutathione transferases (GST), amidases, esterases, or ketone reductases, as well as other enzymes [47, 48], In addition to metabolic pathways, parent compound may be excreted directly via passive or active transport processes, most commonly into the urine or bile. 

The mechanism of OPIDN is poorly understood, but, since all organophosphate esters that produce OPIDN are either direct cholinesterase inhibitors or are metabolically converted to cholinesterase inhibitors, inhibition of an esterase of some kind has generally been thought to be involved (Baron 1981). Certain... 

Expt Intracellular diffusion/ bioconversion Esterase hydrolysis k (sec-1) Fraction metabolized Fraction not metabolized... 

The focus of this chapter is on the penetration barrier. The metabolic barrier due to esterases [39-41], aminopeptidases [38], and ketone reductase [43,51] has been reviewed elsewhere [52], The present chapter reviews and describes the... 

The enterocyte expresses many of the metabolic enzymes that are expressed in the liver. These include UDP-glucuronyltransferases, sulfotransferases, esterases and cytochromes P450. 

Esterases form a wide family of enzymes that catalyze the hydrolysis of ester bonds. They are ubiquitously expressed in all tissues including the intestine, and are found in both microsomal and cytosolic fractions. Prueksaritonont et al. [6] have studied the metabolism of both p-nitrophenol acetate and acetylsalicylic acid by esterases from human intestinal microsomal and cytosolic systems, and the activity values were 2.76 pmol min-1 mg-1 and 0.96 nmol min-1 mg-1, respectively. Thus, the activity for the hydrolysis of p-nitrophenol acetate in human intestine approaches that in the liver. 

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