Caco-2 Permeability Studies and In Vitro hERG Liability Assessment of Tryptanthrin and Indolinone.

Tryptanthrin and (E,Z)-3-(4-hydroxy-3,5-dimethoxybenzylidene)indolinone (indolinone) were recently isolated from Isatis tinctoria as potent anti-inflammatory and antiallergic alkaloids, and shown to inhibit COX-2, 5-LOX catalyzed leukotriene synthesis, and mast cell degranulation at low µM to nM concentrations. To assess their suitability for oral administration, we screened the compounds in an in vitro intestinal permeability assay using human colonic adenocarcinoma cells. For exact quantification of the compounds, validated UPLC-MS/MS methods were used. Tryptanthrin displayed high permeability (apparent permeability coefficient > 32.0 × 10(-6) cm/s) across the cell monolayer. The efflux ratio below 2 (< 1.12) and unchanged apparent permeability coefficient values in the presence of the P-glycoprotein inhibitor verapamil (50 µM) indicated that tryptanthrin was not involved in P-glycoprotein interactions. For indolinone, a low recovery was found in the human colon adenocarcinoma cell assay. High-resolution mass spectrometry pointed to extensive phase II metabolism of indolinone (sulfation and glucuronidation). Possible cardiotoxic liability of the compounds was assessed in vitro by measurement of an inhibitory effect on human ether-a-go-go-related gene tail currents in stably transfected HEK 293 cells using the patch clamp technique. Low human ether-a-go-go-related gene inhibition was found for tryptanthrin (IC50 > 10 µM) and indolinone (IC50 of 24.96 µM). The analysis of compounds using various in silico methods confirmed favorable pharmacokinetic properties, as well as a slight inhibition of the human ether-a-go-go-related gene potassium channel at micromolar concentrations.

Pharmacokinetics of fexofenadine: evaluation of a microdose and assessment of absolute oral bioavailability.

A human pharmacokinetic study was performed to assess the ability of a microdose to predict the pharmacokinetics of a therapeutic dose of fexofenadine and to determine its absolute oral bioavailability. Fexofenadine was chosen to represent an unmetabolized transporter substrate (P-gP and OATP). Fexofenadine was administered to 6 healthy male volunteers in a three way cross-over design. A microdose (100microg) of (14)C-drug was administered orally (period 1) and intravenously by 30min infusion (period 2). In period 3 an intravenous tracer dose (100microg) of (14)C-drug was administered simultaneously with an oral unlabelled therapeutic dose (120mg). Plasma was collected from all 3 periods and analysed for both total (14)C content and parent drug by accelerator mass spectrometry (AMS). For period 3, plasma samples were also analysed using HPLC-fluorescence to determine total drug concentration. Urine was collected and analysed for total (14)C. Good concordance between the microdose and therapeutic dose pharmacokinetics was observed. Microdose: CL 13L/h, CL(R) 4.1L/h, V(ss) 54L, t(1/2) 16h; therapeutic dose: CL 16L/h, CL(R) 6.2L/h, V(ss) 64L, t(1/2) 12h. The absolute oral bioavailability of fexofenadine was 0.35 (microdose 0.41, therapeutic dose 0.30). Despite a 1200-fold difference in dose of fexofenadine, the microdose predicted well the pharmacokinetic parameters following a therapeutic dose for this transporter dependent compound.

Anti-IgE therapy with omalizumab in asthma and allergic rhinitis.

The pharmacology, efficacy, dosage, adverse effects, and economics of anti IgE (omalizumab) are discussed. Omalizumab is the generic name for the human/murine chimeric (recombinant humanized) monoclonal IgG antibody. Anti-IgE prevents IgE from attaching to effector cells, and thereby blunts IgE-mediated inflammatory responses. After subcutaneous administration its absorption is slow, reaching peak concentration in serum after an average of 7-8 days. At recommended doses, serum free IgE levels decrease within 1 hour following the first dose and are maintained between doses. Dose and dosing frequency are adjusted according to body mass and serum total IgE concentration before the start of treatment. Omalizumab administered subcutaneously is an effective treatment for add-on therapy in patients with poorly controlled, moderate-to-severe allergic asthma and allergic rhinitis (adults and adolescents > 12 years). It reduces the requirement for inhaled corticosteroids while protecting against disease exacerbation. Omalizumab is well tolerated, but the safety profile requires long-term assessment in adults as well as in children.

Review of cetirizine hydrochloride for the treatment of allergic disorders.

Cetirizine hydrochloride is an orally-active and selective histamine (H(1))-receptor antagonist. It is a second-generation antihistamine and a human metabolite of hydroxyzine. Therefore, its principal effects are mediated via selective inhibition of peripheral H(1) receptors. The antihistaminic activity of cetirizine has been documented in a variety of animal and human models. In vivo and ex vivo animal models have shown negligible anticholinergic and antiserotonergic activity. In clinical studies, however, dry mouth has been seen more commonly with cetirizine than with placebo. In vitro receptor binding studies have shown no measurable affinity for receptors other than H(1) receptors. Auto-radiographical studies with radiolabelled cetirizine in the rat have shown negligible penetration into the brain. Ex vivo experiments in the mouse have shown that systemically administered cetirizine does not significantly occupy cerebral H(1) receptors. Impairment of CNS function is comparable to other low-sedating antihistamines at the recommended dose of 10 mg/day for adults. It has anti-inflammatory properties that may play a role in asthma management. It does not interact with concomitantly administered medications, it has no cardiac adverse effects, and it does not appear to be associated with teratogenicity. Cetirizine is predominantly eliminated by the kidneys with a mean elimination half-life is 8.3 h. It is rapidly absorbed, and significant clinical inhibition of a wheal and flare response occurs in infants, children and adults within 20 min of a single oral dose and persists for 24 h. No tolerance to the wheal and flare response occurs even after 1 month of daily treatment. The clinical efficacy of cetirizine for allergic respiratory diseases has been established in numerous trials. There is evidence that cetirizine improves symptoms of urticaria. Concomitant use of cetirizine also decreases the duration and amount of topical anti-inflammatory preparations needed for the treatment of atopic dermatitis. Interestingly, several clinical studies suggest that cetirizine may be useful in the treatment and prevention of mild asthma.

Evaluation of a Cmin and a normalized Cmin method for the confirmation of steady-state in bioequivalence studies.

PURPOSE: Two methods to confirm attainment of steady-state conditions in multiple-dose bioequivalence studies are described and evaluated: (1) the Cmin method and (2) the Area Below the Cmin plasma-concentration-versus-time-curve method (ABCM method). METHODS: Cmin Method-After repetitive drug administration to presumed steady-state, successive trough, or Cmin, values are evaluated to determine if they are equal. ABCM Method-The ABCM of successive doses from dose two to presumed steady-state [ABCM(ss)] are divided by the ABCM for the first dose, ABCM(t), to give ABCM(ss)/ ABCM(t)=R, which describes the increase in ABCM(n) with successive doses. The quantity, R, is then divided by an accumulation ratio to render the value independent of intra-subject clearance differences. Monte Carlo simulations were done to test the effects of data error and slow-clearing subpopulations on the method's performance. Data from multiple-dose bioequivalence studies were evaluated using confidence intervals for both methods to determine how well each predicted steady-state for immediate-release and controlled-release drug products. RESULTS/CONCLUSIONS: The Cmin method more accurately predicted the attainment of steady-state conditions for immediate-release formulations compared to the ABCM method. Conversely, the ABCM procedure more accurately predicted the attainment of steady-state conditions for controlled-release formulations compared to the Cmin method. The simulation results were further supported by the experimental data.