Your search keyword '"Meier-Wiedenbach I"' showing total 3 results

1. Anaphylatoxins in the pathogenesis of asthma

Author

Heinzmann Andrea, Bautsch W, Hoymann HG, Zhang Q, Meier-Wiedenbach I, Raschke U, Ames RS, Sohns B, Flemme N, Meyer zu Vilsendorf A, Grove M, Klos A, and Kohl J

Subjects

Anaphylatoxin C3a, asthma, C3a-receptor, guinea pig model of asthma, Diseases of the respiratory system, RC705-779

Published

2000

2. Clinical pharmacokinetics of everolimus.

Author

Kirchner GI, Meier-Wiedenbach I, and Manns MP

Subjects

Adult, Animals, Area Under Curve, Biological Availability, Child, Chromatography, High Pressure Liquid, Clinical Trials as Topic, Enzyme-Linked Immunosorbent Assay, Everolimus, Humans, Immunosuppressive Agents chemistry, Immunosuppressive Agents metabolism, Metabolic Clearance Rate, Sirolimus analogs & derivatives, Sirolimus chemistry, Sirolimus metabolism, Tissue Distribution, Immunosuppressive Agents pharmacokinetics, Sirolimus pharmacokinetics

Abstract

Everolimus is an immunosuppressive macrolide bearing a stable 2-hydroxyethyl chain substitution at position 40 on the sirolimus (rapamycin) structure. Everolimus, which has greater polarity than sirolimus, was developed in an attempt to improve the pharmacokinetic characteristics of sirolimus, particularly to increase its oral bioavailability. Everolimus has a mechanism of action similar to that of sirolimus. It blocks growth-driven transduction signals in the T-cell response to alloantigen and thus acts at a later stage than the calcineurin inhibitors ciclosporin and tacrolimus. Everolimus and ciclosporin show synergism in immunosuppression both in vitro and in vivo and therefore the drugs are intended to be given in combination after solid organ transplantation. The synergistic effect allows a dosage reduction that decreases adverse effects. For the quantification of the pharmacokinetics of everolimus, nine different assays using high performance liquid chromatography coupled to an electrospray mass spectrometer, and one enzyme-linked immunosorbent assay, have been developed. Oral everolimus is absorbed rapidly, and reaches peak concentration after 1.3-1.8 hours. Steady state is reached within 7 days, and steady-state peak and trough concentrations, and area under the concentration-time curve (AUC), are proportional to dosage. In adults, everolimus pharmacokinetic characteristics do not differ according to age, weight or sex, but bodyweight-adjusted dosages are necessary in children. The interindividual pharmacokinetic variability of everolimus can be explained by different activities of the drug efflux pump P-glycoprotein and of metabolism by cytochrome P450 (CYP) 3A4, 3A5 and 2C8. The critical role of the CYP3A4 system for everolimus biotransformation leads to drug-drug interactions with other drugs metabolised by this cytochrome system. In patients with hepatic impairment, the apparent clearance of everolimus is significantly lower than in healthy volunteers, and therefore the dosage of everolimus should be reduced by half in these patients. The advantage of everolimus seems to be its lower nephrotoxicity in comparison with the standard immunosuppressants ciclosporin and tacrolimus. Observed adverse effects with everolimus include hypertriglyceridaemia, hypercholesterolaemia, opportunistic infections, thrombocytopenia and leucocytopenia. Because of the variable oral bioavailability and narrow therapeutic index of everolimus, blood concentration monitoring seems to be important. The excellent correlation between steady-state trough concentration and AUC makes the former a simple and reliable index for monitoring everolimus exposure. The target trough concentration of everolimus should range between 3 and 15 microg/L in combination therapy with ciclosporin (trough concentration 100-300 microg/L) and prednisone.

Published

2004

3. Cutting edge: guinea pigs with a natural C3a-receptor defect exhibit decreased bronchoconstriction in allergic airway disease: evidence for an involvement of the C3a anaphylatoxin in the pathogenesis of asthma.

Author

Bautsch W, Hoymann HG, Zhang Q, Meier-Wiedenbach I, Raschke U, Ames RS, Sohns B, Flemme N, Meyer zu Vilsendorf A, Grove M, Klos A, and Köhl J

Subjects

Administration, Inhalation, Airway Resistance genetics, Airway Resistance immunology, Animals, Asthma etiology, Asthma pathology, Cell Line, Cell Movement immunology, Complement C3a metabolism, Eosinophils pathology, Gene Expression Regulation immunology, Genetic Markers immunology, Guinea Pigs, Humans, Injections, Intraperitoneal, Ovalbumin administration & dosage, Ovalbumin immunology, Point Mutation immunology, Receptors, Complement antagonists & inhibitors, Receptors, Complement genetics, Species Specificity, Up-Regulation genetics, Up-Regulation immunology, Asthma immunology, Bronchoconstriction immunology, Complement C3a physiology, Membrane Proteins, Receptors, Complement deficiency

Abstract

Asthma is a major cause of morbidity worldwide with prevalence and severity still increasing at an alarming pace. Hallmarks of this disease include early-phase bronchoconstriction with subsequent eosinophil infiltration, symptoms that may be mimicked in vivo by the complement-derived C3a anaphylatoxin, following its interaction with the single-copy C3aR. We analyzed the pathophysiological role of the C3a anaphylatoxin in a model of experimental OVA-induced allergic asthma, using an inbred guinea pig strain phenotypically unresponsive to C3a. Molecular analysis of this defect revealed a point mutation within the coding region of the C3aR that creates a stop codon, thereby effectively inactivating gene function. When challenged by OVA inhalation, sensitized animals of this strain exhibited a bronchoconstriction decreased by approximately 30% in comparison to the corresponding wild-type strain. These data suggest an important role of C3a in the pathogenesis of asthma and define a novel target for drug intervention strategies.

Published

2000