Absorption, distribution, metabolism toxicity

Historically, drug absorption, distribution, metabolism, excretion, and toxicity ADMET) studies in animal models were performed after the identification of a lead compound. In order to avoid costs, nowadays pharmaceutical companies evaluate the ADMET profiles of potential leads at an earlier stage of the development... 

Absorption, Distribution, Metabolism, and Excretion. Evidence of absorption comes from the occurrence of toxic effects following exposure to methyl parathion by all three routes (Fazekas 1971 Miyamoto et al. 1963b Nemec et al. 1968 Skiimer and Kilgore 1982b). These data indicate that the compound is absorbed by both humans and animals. No information is available to assess the relative rates and extent of absorption following inhalation and dermal exposure in humans or inhalation in animals. A dermal study in rats indicates that methyl parathion is rapidly absorbed through the skin (Abu-Qare et al. 2000). Additional data further indicate that methyl parathion is absorbed extensively and rapidly in humans and animals via oral and dermal routes of exposure (Braeckman et al. 1983 Flollingworth et al. 1967 Ware et al. 1973). However, additional toxicokinetic studies are needed to elucidate or further examine the efficiency and kinetics of absorption by all three exposure routes. 

The Basic Concept of the QSAR Technique. The QSAR technique has been widely employed in modeling biological activities as well as ADME/Tox (absorption, distribution, metabolism, excretion, toxicity) properties. This approach was first introduced by Flansch et al. in 1963, on the basis of linear... 

Ekins S, Nikolsky Y, Nikolskaya T. Techniques application of systems biology to absorption, distribution, metabolism, excretion and toxicity. Trends Pharmacol Sci 2005 Apr 26(4) 202-9. 

ADMET absorption, distribution, metabolism, excretion and toxicity... 

Absorption, Distribution, Metabolism, Excretion and Toxicity (ADMET)... 

Repeating for emphasis - not aU poorly water-soluble compounds are equally solubilized by DMSO. The greaseball compounds will be much better solubilized than the brickdust compounds. The most common range of compound in DMSO stock concentrations in compound storage repositories is 2-20 mM. At conferences, organizations employing 2mM compound in DMSO stock solutions report fewer solubility problems. The downside is that the lower stock concentrations are more Hmited in utility in some absorption, distribution, metabolism, excretion and toxicity assays that require higher compound concentration. 

ADMET absorption, distribution, metabolism, excretion and toxicity BLW-ED block-localized wave function energy decomposition hERG human ether-a-go-go-related gene QSAR quantitative structure-activity relationship... 

Hansch and Leo [13] described the impact of Hpophihdty on pharmacodynamic events in detailed chapters on QSAR studies of proteins and enzymes, of antitumor drugs, of central nervous system agents as well as microbial and pesticide QSAR studies. Furthermore, many reviews document the prime importance of log P as descriptors of absorption, distribution, metabolism, excretion and toxicity (ADMET) properties [5-18]. Increased lipophilicity was shown to correlate with poorer aqueous solubility, increased plasma protein binding, increased storage in tissues, and more rapid metabolism and elimination. Lipophilicity is also a highly important descriptor of blood-brain barrier (BBB) permeability [19, 20]. Last, but not least, lipophilicity plays a dominant role in toxicity prediction [21]. 

Absorption, Distribution, Metabolism, and Excretion. There are no data available on the absorption, distribution, metabolism, or excretion of diisopropyl methylphosphonate in humans. Limited animal data suggest that diisopropyl methylphosphonate is absorbed following oral and dermal exposure. Fat tissues do not appear to concentrate diisopropyl methylphosphonate or its metabolites to any significant extent. Nearly complete metabolism of diisopropyl methylphosphonate can be inferred based on the identification and quantification of its urinary metabolites however, at high doses the metabolism of diisopropyl methylphosphonate appears to be saturated. Animal studies have indicated that the urine is the principal excretory route for removal of diisopropyl methylphosphonate after oral and dermal administration. Because in most of the animal toxicity studies administration of diisopropyl methylphosphonate is in food, a pharmacokinetic study with the compound in food would be especially useful. It could help determine if the metabolism of diisopropyl methylphosphonate becomes saturated when given in the diet and if the levels of saturation are similar to those that result in significant adverse effects. 

Second, meanwhile, no international guidelines have been provided for the manufacture, marketing, and distribution of household insecticides on such a level as those of agricultural chemicals, and not even manufacturing registration is required in some countries. Of course, the minimal required toxicity studies are conducted with synthetic pyrethroids for household insecticides to examine absorption, distribution, metabolism, and genotoxicity in animals. 

Comparative Toxicokinetics. The toxicokinetic studies available indicate that the rat is a good model for human neurotoxicity observed after occupational exposure to 77-hexane. Mild signs can be produced in chickens and mice, but these do not progress to the serious neurotoxicity observed in humans and rats. Toxicokinetic data from other species (absorption, distribution, metabolism, excretion) could provide insight on the molecular mechanism(s) of the species specificity of 77-hexane toxicity and would be valuable for predicting toxic effects in humans. 

The study of the kinetics of absorption, distribution, metabolism and excretion of toxic or potentially toxic chemicals. 

In the above-mentioned examples, the prediction of CYP-mediated compound interactions is a starting point in any metabolic pathway prediction or enzyme inactivation. This chapter presents an evolution of a standard method [1], widely used in pharmaceutical research in the early-ADMET (absorption, distribution, metabolism, excretion and toxicity) field, which provides information on the biotransformations produced by CYP-mediated substrate interactions. The methodology can be applied automatically to all the cytochromes whose 3 D structure can be modeled or is known, including plants as well as phase II enzymes. It can be used by chemists to detect molecular positions that should be protected to avoid metabolic degradation, or to check the suitability of a new scaffold or prodrug. The fully automated procedure is also a valuable new tool in early-ADMET where metabolite- or mechanism based inhibition (MBI) must be evaluated as early as possible. 

Among chemical-physics properties, lipophilicity is certainly a key parameter to understand and predict absorption, distribution, metabolism, excretion, and toxicity (ADMET) of NCE furthermore, it contributes to model ligand-target interactions underlying the pharmacodynamic phase [15],... 

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