Zia Tayab scite author profile

Expert Opinion on Drug Delivery

Hochhaus

2005

Inhaled therapy with either glucocorticoids and/or beta(2)-adrenergic drugs remains the mainstay of asthma treatment. In the last few years, a number of new products have been introduced into the market with the goal of improving efficacy and safety. This review article summarises the pharmacokinetic and pharmacodynamic properties of inhaled drugs for topical delivery necessary to achieve this goal. Pharmacokinetic properties include a high pulmonary deposition, low oral bioavailability, optimised pulmonary residence time and a very high systemic clearance. Optimisation of pharmacodynamic properties, such as receptor selectivity, may also yield drugs with improved pulmonary selectivity. As existing drugs also provide high efficacy and safety profiles, future developments will represent only slight improvements and quantum leap improvements are unlikely to occur.

Pharmacokinetic/pharmacodynamic evaluation of urinary cortisol suppression after inhalation of fluticasone propionate and mometasone furoate

Fardon

Lee

et al. 2007

Brit J Clinical Pharma

What is already known about this subject • Mometasone furoate (MF) is a new inhaled glucocorticoid for which the first reports suggested a low degree of systemic side-effects and low systemic availability.• Recent studies of Fardon and colleagues have shown that MF's cortisol suppression is similar to that of fluticasone.• Pharmacokinetic/dynamic evaluations of MF's systemic side-effects, probing whether systemic side-effects can be explained by systemic availability, plasma protein binding and receptor binding affinity, are lacking in the literature. What this study adds• This study shows that the systemic availability of MF and fluticasone propionate (FP) are similar and that systemic availability is directly related to the dose. • It also shows that the metabolites of MF are present only in very low concentrations at most, contrary to results in rats.• The observed cortisol suppression of FP and MF is related to the trough plasma concentrations and seems to be in agreement with its observed systemic availability, plasma protein binding and receptor binding affinity. AimFluticasone propionate (FP) and mometasone furoate (MF) are inhaled corticosteroids that possess a high ratio of topical to systemic activity. The systemic bioavailability of MF has been claimed to be minimal (1%). FP has been shown to exhibit the same degree of systemic effects, but its systemic availability is between 13 and 17%. We hypothesize that FP and MF have comparable systemic availabilities that can explain their potential to cause systemic effects. MethodsSteady-state FP and MF trough plasma samples were determined from a clinical study by Fardon et al. in patients with persistent asthma (forced expiratory volume in 1 s = 91%). The percent plasma protein binding of FP and MF was measured using ultracentrifugation. Free FP plasma concentrations were normalized for their differences in receptor binding affinity compared with MF and linked to overnight urinary cortisol/creatinine with an inhibitory Emax. ResultsA plot of steady-state FP and MF total trough plasma concentrations vs. dose showed that both drugs exhibit dose linearity. MF has comparable bioavailability to FP based on the steady-state concentrations observed for the different doses. The free plasma concentration producing 50% of urinary cortisol suppression (IC50) for MF was not statistically different from the free, normalized IC50 for FP. ConclusionFP and MF have similar pulmonary deposition and the same potential to cause systemic side-effects due to their similar IC50 values. The observed urinary cortisol suppression of FP and MF is in agreement with their systemic availability, their differences in plasma protein binding and receptor binding affinity.

Pharmacokinetic and pharmacodynamic effects of high-dose monoclonal antibody therapy in a rat model of immune thrombocytopenia

Jin

Balthasar

2005

AAPS J

A BSTRACTIntravenous administration of pooled, polyvalent human immunoglobulin (IVIG) has been used for over 20 years as a therapy for immune thrombocytopenia (ITP). IVIG is available in limited quantities, and clinical preparations have been associated with the transfer of human pathogens. We have proposed that high-dose monoclonal antibody may be used in lieu of IVIG to achieve benefi cial effects in the treatment of ITP. The current study investigates the effects of high-dose monoclonal antibody therapy in a rat model of ITP. Hybridoma cells secreting a murine monoclonal antiplatelet antibody (7E3) and murine monoclonal anti-methotrexate IgG (AMI) were grown in serum-free media. Next, 7E3, 8 mg kg -1 , was administered intravenously to rats following pretreatment with saline or AMI (1 g kg -1 IV). AMI and 7E3 plasma concentrations were determined via enzyme-linked immunosorbent assay, and platelet count was determined with a Cell-Dyne hematology analyzer. Severe, transient thrombocytopenia was induced by 7E3. Platelet counts dropped to ~8% of initial values within 1 hour after 7E3 administration. AMI pretreatment dramatically affected 7E3-induced thrombocytopenia, signifi cantly altering the time course of thrombocytopenia ( P < .05) and signifi cantly decreasing the severity of 7E3-induced thrombocytopenia (ie, following AMI pretreatment, nadir platelet count was greater than 8-fold that of the control group, P < .05). In addition, AMI pretreatment induced a 57% increase in 7E3 clearance (1.13 ± 0.13 mL h -1 kg -1 vs 0.72 ± 0.08 mL h -1 kg -1 , P < .05). Consequently, high-dose monoclonal antibody therapy attenuated thrombocytopenia and produced a moderate increase in the clearance of antiplatelet antibodies in a rat model of ITP.

Development and Validation of Enzyme‐Linked Immunosorbent Assays for Quantification of Anti‐Methotrexate IgG and Fab in Mouse and Rat Plasma

Journal of Immunoassay and Immunochemistry

Balthasar

2004

This laboratory is investigating the use of anti-methotrexate IgG (AMI) and anti-methotrexate Fab fragments (AMF) within an inverse targeting strategy that is designed to enhance the pharmacokinetic selectivity of intraperitoneal (i.p.) chemotherapy. The goal of this study was to develop enzyme-linked immunosorbent assays (ELISAs) to determine concentrations of AMI and AMF in mouse and rat plasma. An antigen-specific ELISA was developed for AMI and AMF in mouse and rat plasma. The assay was validated with respect to precision and accuracy by evaluating the recovery of AMI and AMF from mouse and rat plasma samples. Preliminary pharmacokinetic studies of AMI and AMF were performed in Sprague-Dawley rats and Swiss Webster mice. The animals were instrumented with a jugular vein cannula and administered AMI or AMF, 15 mg kg(-1) via the cannula. Plasma samples were taken at various time points and analyzed using the ELISA, and the observed concentration vs. time profiles were subjected to non-compartmental pharmacokinetic analyses. Standard curves for the ELISAs were found to be linear over concentration ranges of 0-250 and 0-350 ng mL(-1) for AMI and AMF, respectively. Intra-assay and inter-assay recovery of AMI and AMF from plasma samples were found to be within 15% of theoretical values. Preliminary pharmacokinetic investigations of AMI allowed estimation of AMI clearance to be 0.017 mL kg(-1) min(-1) in the rat and 0.043 mL kg(-1) min(-1) in the mouse. AMF clearance was estimated to be 0.038 and 1.93 mL kg(-1) min(-1) in the mouse and rat, respectively. In conclusion, ELISAs have been developed and validated for quantitation of AMI and AMF in rat and mouse plasma. The assays will allow further investigations of AMI and AMF pharmacokinetics.