Current Drug Metabolism - Volume 10, Issue 5, 2009

Lithium is a simple cation that has been used clinically since 1950 for the treatment of bipolar disorder. However in the last decade numerous studies either using animal models or human trials suggest that this cation may delay progression of neurodegenerative diseases. One of the main challenges facing researchers in the neurosciences is to identify key molecules in neuronal apoptosis. This would facilitate the identification of targets in order to design drugs for the treatment of Alzheimer's disease, Parkinson's disease and other neurological disorders. Although enormous effort has been made in the past few years and it has been demonstrated that the mitochondria comprise a key component of the neuronal apoptotic route, it seems that in addition to the mitochondria other intracellular components are implicated in this process. It has been proposed that DNA damage and re-entry into the cell cycle or the activation of different proteases, such as calpain, could constitute a common pathway in the apoptotic process and thus death processes in neurological diseases. The hypothesis about the implication of calpain in neuronal cell death is supported by existing data on neurodegenerative disorders in the brains of patients who show an increase in proteolytic activity of calpain compared with control brains. Indeed, studies performed in neuronal cell preparations suggest that activation of this protease is accompanied by other features such as structural modifications of the cytoskeleton, cleavage of several receptors, activation of kinases, such as cdk5 or GSK3szlig;, etc. Here, we summarize the potential routes involved in neurodegenerative disorders related to calpain activation, mainly those connected with changes in calcium homeostasis machinery, activation of kinase pathways, transcription factors, and the cell cycle.

One possible origin of the type I hypersensitivity reaction is reaction of drugs such as acetylsalicylic acid and its metabolites being complexed with human serum albumin. Albumin, being transporting molecule abundant in blood plasma is able to bind large array of ligands varying from small single carbon particles to long hydrophobic tailed lipidic acids (e.g. myristic acid). This non specificity is possible because of multi domain scaffold and large flexibility of inter-domain loops, which results in serious reorientation of domains. Hypothesis that acetylsalicylic acid metabolites may play indirect role in activation of allergic reaction has been tested. Binding of acetylsalicylic acid metabolites in intra-domain space causes significant increase of liability of domains IIIA and IIIB. One of metabolites, salicyluric acid, once is bound causes distortion and partial unfolding of helices in domains IA, IIB and IIIB. Changed are both directions and amplitude of relative motions as well as intra-domain distances. In result albumin is able to cross-link of adjacent IgE receptors which subsequently starts allergic reaction.

Amphotericin B (AmB) is a well known antifungal and antiprotozoal antibiotic used in the clinic for several decades. Clinical applications of AmB, however, are limited by its nephrotoxicity and many other acute side effects which are not acceptable by patients when their life is not threaten. In order to improve the therapeutic index of this drug, lipid formulations have been introduced and many efforts have been made to obtain less toxic AmB derivatives by chemical modifications of the parent drug. This review presents concise knowledge about this fascinating compound and a critical review of the data published within last few years about the mechanism of action of this antibiotic. In particular, in the present work we discuss: i) structure and properties of AmB and its recently synthesized new derivatives; ii) antifungal and antileishmanial activity and toxicity of these compounds; and iii) mode of action of AmB and its derivatives at cellular and molecular levels, with particular attention paid to interactions of AmB and different components of cellular membranes.

Tyrosine kinase inhibitors (TKI) are effective in the targeted treatment of various malignancies. Imatinib was the first to be introduced into clinical oncology, and it was followed by drugs such as gefitinib, erlotinib, sorafenib, sunitinib, and dasatinib. Although they share the same mechanism of action, namely competitive ATP inhibition at the catalytic binding site of tyrosine kinase, they differ from each other in the spectrum of targeted kinases, their pharmacokinetics as well as substance-specific adverse effects. With variations from drug to drug, tyrosine kinase inhibitors cause skin toxicity, including folliculitis, in more than 50% of patients. Among the tyrosine kinase inhibitors that are commercially available as yet, the agents that target EGFR, erlotinib and gefitinib, display the broadest spectrum of adverse effects on skin and hair, including folliculitis, paronychia, facial hair growth, facial erythema, and varying forms of frontal alopecia. In contrast, folliculitis is not common during administration of sorafenib and sunitinib, which target VEGFR, PDGFR, FLT3, and others, whereas both agents have been associated with subungual splinter hemorrhages. Periorbital edema is a common adverse effect of imatinib. Besides the haematological side effects of most of TKIs like anemia, thrombopenia and neutropenia, the most common extraheamatologic adverse effects are edema, nausea, hypothyroidism, vomiting and diarrhea. Regarding possible long term effects, recently cardiac toxicity with congestive heart failure is under debate in patients receiving imatinib and sunitinib therapy; however, this observation was probably relate to patients selection, although, TKIs overall appear to be a very well tolerated drug class.

Drug transporters expressed on the hepatocyte membrane play an important role in hepatic drug disposition. In the last two decades, systematic research has resulted in a better understanding of the diversity, expression and substrate specificities of drug transporters in the liver. Here we review recent studies on the role of transporters in drug-drug interactions and disease states such as cirrhosis. We conclude the review by considering techniques and model systems used to study hepatic transporters, including the latest technological developments such as multiphoton microscopy.

Within the field of drug metabolism, when addressing quantitative aspects, an average value is traditionally quoted, commonly the arithmetic mean with perhaps an indication of spread. Better still a range of values may be given, thereby acknowledging that various factors may precipitate differences between individuals. A single subject, however, usually only merits a single value. Nevertheless, events such as an acute illness or concurrent drug therapy serve to alert that this value may change substantially over a relatively short time-period, although any potential effects of naturally occurring phenomena, such as the female menstrual cycle, are often overlooked or disregarded. Are the biochemical and physiological changes that occur during the menstrual cycle able to influence xenobiotic metabolism? Is the idea of a stable and unwavering baseline within a single healthy individual flawed? Is it time to reassess our thinking with regards to such aspects? This brief review explores these issues and examines information available within the literature for evidence of potential influences of menstrual cycle events upon drug metabolism, defined as the actual chemical alteration of the parent molecule into another chemical species.

Hepatocyte nuclear factor 4-alpha (HNF4α, NR2A1) is a nuclear receptor (NR) required for liver development and for controlling the expression of many hepatic-specific genes associated with important metabolic pathways. Many studies have also identified HNF4α as a direct transactivator of numerous xenobiotic-metabolizing cytochrome P450 (CYP) genes, suggesting that this factor is a global regulator which supports CYP transcription in the liver. Moreover, HNF4α expression displays a significant variability in human liver which may account for a proportion of the inter-individual variability in the expression of drug-metabolism genes and the clearance rate of a wide variety of prescribed drugs. In the last few years, a number of complex interactions and cross-talks between HNF4α and other transcription factors and coregulators have also surfaced, and the impact on CYP gene expression has been demonstrated. Thus, it is now clear that HNF4α modulates CYP expression in the liver by interacting with the xenosensor receptors (PXR and CAR), the glucocorticoid receptor (GR), the feeding-fasting cycle target PGC-1α, the sexual-dimorphism factor Stat5b, and other liver-enriched factors, such as C/EBPs. In addition to regulating drug elimination pathways, HNF4α also triggers pleiotropic effects on cholesterol and fatty acid metabolism, glucose homeostasis and inflammation. As a whole, current evidence indicates that HNF4α is a central regulator in the network of NRs that integrates drug-metabolism not only with the liver intermediate metabolism, but also with a number of patho-physiological conditions where the CYP expression is altered. The purpose of this review is to summarize and discuss these studies and their conclusions, with particular emphasis on the role of HNF4α in the regulation of drug-metabolizing CYP genes in the human liver.

Significant changes in the physiological and biotransformation processes that govern pharmacokinetics occur during pregnancy. Consequently, the disposition of many medications is altered in gestation and the efficacy and toxicity of drugs used by pregnant women can be difficult to predict or can lead to serious side effects. Gastrointestinal absorption and bioavailability of drugs vary due to changes in gastric secretion and small intestine motility. Various pregnancy-related hemodynamic changes such as an increase in cardiac output, blood volume, the volume of distribution (Vd), renal perfusion and glomerular filtration may affect drug disposition and elimination, and can cause increase or decrease in the terminal elimination half-life of drugs. Changes in maternal drug biotransformation activity also contribute to alterations in pharmacokinetics of drugs taken in pregnancy. Therefore, pregnant women may require different dosing regimens or their adjustment than both men and non-pregnant women. In addition, the prenatal pharmacotherapy is unique due to the presence of feto-placental unit. Considerations regarding transplacental pharmacokinetics and safety for the developing fetus are thus essential aspects of medication in pregnancy. The aim of this review is to summarize major physiological and biotransformation changes associated with pregnancy that affect pharmacokinetics in pregnant women. In addition, we point out the most important examples of altered kinetics of drugs administered in pregnancy with mechanistic explanation of the phenomena based on maternal adaptation in pregnancy.