From the bench to clinical practice: understanding the challenges and uncertainties in immunogenicity testing for biopharmaceuticals.

Unlike conventional chemical drugs where immunogenicity typically does not occur, the development of anti-drug antibodies following treatment with biologics has led to concerns about their impact on clinical safety and efficacy. Hence the elucidation of the immunogenicity of biologics is required for drug approval by health regulatory authorities worldwide. Published ADA 'incidence' rates can vary greatly between same-class products and different patient populations. Such differences are due to disparate bioanalytical methods and interpretation approaches, as well as a plethora of product-specific and patient-specific factors that are not fully understood. Therefore, the incidence of ADA and their association with clinical consequences cannot be generalized across products. In this context, the intent of this review article is to discuss the complex nature of ADA and key nuances of the methodologies used for immunogenicity assessments, and to dispel some fallacies and myths.

Human Ontogeny of Drug Transporters: Review and Recommendations of the Pediatric Transporter Working Group.

The critical importance of membrane-bound transporters in pharmacotherapy is widely recognized, but little is known about drug transporter activity in children. In this white paper, the Pediatric Transporter Working Group presents a systematic review of the ontogeny of clinically relevant membrane transporters (e.g., SLC, ABC superfamilies) in intestine, liver, and kidney. Different developmental patterns for individual transporters emerge, but much remains unknown. Recommendations to increase our understanding of membrane transporters in pediatric pharmacotherapy are presented.

Pharmacokinetic profile of spectinomycin in rats.

Following intravenous (IV) administration, the pharmacokinetics of spectinomycin in rats was found to be on par with its profile in other mammalian species including humans with respect to its overall excretion and half-life at effective concentrations. This study, however, indicates that a small fraction of the spectinomycin dose is retained in peripheral tissues for a prolonged period of time at low concentrations.

Evaluation of regional limb perfusion with amikacin using the saphenous, cephalic, and palmar digital veins in standing horses.

Previous studies have shown that regional limb perfusion (RLP) using the palmar digital (PD) vein delivers therapeutic concentration of amikacin to the distal limb. Our hypothesis was that using the cephalic and saphenous veins for RLP will enable delivery of therapeutic concentrations of amikacin to the distal limb. Nineteen healthy horses participated in the study. The cephalic, saphenous, or PD vein was used to perfuse the limb with amikacin. Two grams of amikacin was used for RLP using the saphenous and the cephalic veins, and one gram was used in the PD vein. Synovial samples were collected from the metacarpo-/metatarsophalangeal (MCP/MTP) joint, and blood samples were collected from the jugular vein. Maximum concentration (Cmax) of amikacin in the MCP/MTP joint using the cephalic and the saphenous vein was 277 and 363 mg/L, respectively. The amikacin concentrations achieved in the synovial fluid of the MCP/MTP joint in the current study were between 69 and 91 times the minimally inhibitory concentration of common susceptible bacterial pathogens causing orthopedic infections in horses. To conclude, this study shows that use of the proximal veins for RLP to treat distal limb infections is a viable alternative to using the palmar or plantar digital vein.

Physiologically based pharmacokinetic (PBPK) modeling in children.

This review summarizes the present status of physiologically based pharmacokinetic (PBPK) modeling and simulation (M&S) and its application in support of pediatric drug research. We address the reasons that PBPK is suited to the current needs of pediatric drug development and pharmacotherapy in light of the evolution in pediatric PBPK methodologies and approaches, which were originally developed for the purpose of toxicologic evaluation. Also discussed is the current degree of confidence in using PBPK to support pediatric drug development and registration and the key factors essential for robust results and broader adoption of pediatric PBPK M&S.

Transrepression and transactivation potencies of inhaled glucocorticoids.

The anti-inflammatory activity of inhaled glucocorticoids is primarily mediated through transrepression of pro-inflammatory transcription factors such as AP-1 and NF-kappaB, while systemic side effects are largely attributed to transactivation via glucocorticoid response elements (GRE) in the promoter region of responsive genes. The objective of this study is to investigate whether inhaled corticosteroids exhibit differences in their transactivation and transrepression potencies. A549 human alveolar epithelial type II like cells, stably transfected with a reporter plasmid containing an AP-1, NF-kappaB or GRE induced secreted alkaline phosphatase reporter gene (SEAP), were exposed to a panel of concentrations of the six inhaled and three systemic glucocorticoids. Glucocorticoid-induced changes in SEAP expression were quantified by chemiluminescence. For eight glucocorticoids (budesonide, desisobutyryl-cicle-sonide, dexamethasone, flunisolide, fluocortolone, fluticasone propionate, mometasone furoate, prednisolone) the EC50 for NF-kappaB mediated transrepression was significantly larger than that for both transactivation and transrepression via AP-1. For the remaining glucocorticoid (triamcinolone acetonide), it was greater than that for transactivation. It is concluded that, within the studied cell system, inhaled corticosteroids did not exhibit preferential transrepression, but had higher potencies for transactivation than for transrepression via NF-kappaB and had differential potencies for the two transrepression pathways.

The role of pharmacokinetics and pharmacodynamics in phosphodiesterase-5 inhibitor therapy.

Differences in clinical pharmacology of the currently marketed phosphodiesterase (PDE)5 inhibitors sildenafil, vardenafil and tadalafil are largely determined by their pharmacokinetic (PK) properties and their PDE5 inhibitory activity profile. This review outlines the basic concepts of pharmacokinetics and pharmacokinetic pharmacodynamic (PK/PD) relationships and their relevance to dose selection and applied pharmacotherapy. It is followed by a detailed comparative discussion on the pharmacokinetics and exposure-response relationship of the currently available PDE5 inhibitors, including known drug-drug interactions and dosage adjustments in special populations. The review is aimed at providing a critical assessment of the pharmacokinetics of PDE5 inhibitors, which may assist clinicians in tailoring drug and/or treatment regimens to the unique needs of each individual patient with erectile dysfunction.

A modern view of excipient effects on bioequivalence: case study of sorbitol.

PURPOSE: To examine the effect of common excipients such as sugars (sorbitol versus sucrose) on bioequivalence between pharmaceutical formulations, using ranitidine and metoprolol as model drugs. METHODS: Two single-dose, replicated, crossover studies were first conducted in healthy volunteers (N=20 each) to compare the effect of 5 Gm of sorbitol and sucrose on bioequivalence of 150 mg ranitidine or 50 mg metoprolol in aqueous solution, followed by a single-dose, nonreplicated, crossover study (N=24) to determine the threshold of sorbitol effect on bioequivalence of 150 mg ranitidine in solution. RESULTS: Ranitidine Cmax and AUC0-infinity were decreased by approximately 50% and 45%, respectively, in the presence of sorbitol versus sucrose. Similarly, sorbitol reduced metoprolol Cmax by 23% but had no significant effect on AUC0-infinity. An appreciable subject-by-formulation interaction was found for ranitidine Cmax and AUC0-infinity, as well as metoprolol Cmax. Sorbitol decreased the systemic exposure of ranitidine in a dose-dependent manner and affected bioequivalence at a level of 1.25 Gm or greater. CONCLUSIONS: As exemplified by sorbitol, some common excipients have unexpected effect on bioavailability/bioequivalence, depending on the pharmacokinetic characteristics of the drug, as well as the type and amount of the excipient present in the formulation. More research is warranted to examine other 'common' excipients that may have unintended influence on bioavailability/bioequivalence.

Pharmacokinetics of immunosuppressants: a perspective on ethnic differences.

Despite recent advancements in solid organ transplantation, African-American renal allograft recipients continue to exhibit poorer prognosis in long-term clinical outcome and graft survival compared to Caucasian patients. The role of immunosuppressants in post-transplant outcome is crucial, and associations between exposure-related pharmacokinetic parameters and clinical outcome have been made for several drugs in this class. Thus, ethnic differences in the pharmacokinetics of immunosuppressants are potentially a key factor in the observed differences in post-transplant outcome between African-Americans and Caucasians. Ethnic differences in pharmacokinetics of mycophenolate mofetil and azathioprine based on the current literature are either absent or only of minor relevance. Cyclosporine, tacrolimus, sirolimus and everolimus, however, have all been described to exhibit ethnicity-specific differences in bioavailability and/or dose-adjusted systemic exposure, although currently available reports are controversial for some of these drugs. Oral bioavailability of these drugs in African-Americans was between 20 and 50% lower than in Caucasians or Non-African-Americans, leading to higher dose requirements in African-Americans to maintain similar average concentrations of the respective immunosuppressant. Since all four drugs undergo extensive metabolism and are substrates for CYP3A isoenzymes as well as the drug transporter P-glycoprotein, interethnic variability in activity of these enzymes/transporter may provide a common mechanism for the observed ethnic differences. These ethnic differences are most likely mediated via several non-genetic as well as genetic factors, including known genetic variations that impair transporter/enzyme activity in genes such as CYP3A4, CYP3A5 and ABCB1 (MDR1). Appreciation of differences in immunosuppressant pharmacokinetics and dose requirements between African-Americans and Caucasians in clinical practice is expected to improve post-transplant immunosuppressive pharmacotherapy and may thus contribute to equalize prognostic outcome for all transplant patients.

Optimized therapeutic ratio of inhaled corticosteroids using retrometabolism.

During recent years, the treatment of pulmonary diseases could be significantly improved due to the introduction of modern retrometabolism-based corticosteroids with improved therapeutic ratio. It is the goal of all inhaled corticosteroids to produce long lasting therapeutic effects at the pulmonary target site and to minimize systemic side effects by rapid clearance of the absorbed drug and low oral bioavailability. The development of PK/PD models allows predictions of drug effects based on the administered dose. For example, the cumulative suppression of endogenous cortisol release (CCS) as one of the major systemic side effects of inhaled corticosteroid therapy can be described with an integrated Emax based PK/PD model. In order to assess the predictive power of this model, a study was conducted to compare the PK/PD-based predictions with CCS data obtained from actual clinical trials for flunisolide, fluticasone propionate, budesonide and triamcinolone acetonide. CCS was predicted for different single doses from different inhaler devices for each drug and a good correlation was observed. Thus, the presented PK/PD model proved to be a valid tool for predicting CCS of inhaled corticosteroids. By fully understanding the underlying mechanisms it will be possible to further improve their therapeutic index.

Gender differences in pharmacokinetics and pharmacodynamics.

Several years ago regulatory authorities requested to include women in all phases of clinical drug development in order to thoroughly investigate potential gender differences in the pharmacokinetics and pharmacodynamics of newly developed therapeutic agents. Since then, numerous reports have been published that evaluate the potential existence and impact of gender differences on all aspects of clinical pharmacology. With regard to pharmacokinetics, differences in absorption rate and duration have been reported for several drugs, but generally lack to have major clinical relevance. Differences in oral bioavailability, however, seem to be more important and are usually caused by sex differences in the activity of major intestinal and hepatic metabolic enzymes. Distributional differences have also been identified for numerous compounds. Although the majority of these findings were merely weight effects as women generally have a lower body weight, some of the gender-specific distribution differences persisted after normalization for weight. Possible explanations are differences in body composition between men and women and/or physiological changes during the menstrual cycle as well as differences in plasma protein binding secondary to hormonal characteristics. Frequent and sometimes clinically relevant gender differences could be identified for drug elimination processes and were predominantly linked to the sex-specific expression of metabolic enzyme systems, e.g. CYP3A4 and CYP1A2. In contrast, gender-related differences in renal elimination are generally only of minor importance. With regard to pharmacodynamics, gender differences have been observed in baseline characteristics as well as in drug response, which might both, at least in part, be the consequence of modulation by sex hormones. Some of the most striking examples identified were in pain therapy and perception, glucose management and arrhythmia susceptibility. Since clinical endpoints of efficacy and toxicity are often difficult to monitor and are frequently substituted by surrogate markers that might increase variability and thus mask gender effects, sex-specific differences in pharmacodynamic characteristics can often remain uncovered and further intensive research in this area seems imperative. For the majority of investigated drugs in the past few years, however, no or only very minor gender differences could be detected in pharmacokinetics and/or pharmacodynamics. In addition, the clinical significance of those gender differences identified seem very limited and was only very rarely linked to treatment success or failure. Hence, it is undoubtedly necessary to include women in the clinical drug development process, but it seems questionable whether women of child-bearing capability should be exposed to potential risks in early phase I clinical trials.

A pharmacokinetic/pharmacodynamic approach to predict the cumulative cortisol suppression of inhaled corticosteroids.

The suppression of endogenous cortisol release is one of the major systemic side effects of inhaled corticosteroids in the treatment of asthma. The circadian rhythm of the endogenous cortisol release and the resulting plasma concentrations as well as the release suppression during corticosteroid therapy could previously be described with an integrated PK/PD model. Based on this model, a PK/PD approach was developed to quantify and predict the cumulative cortisol suppression (CCS) as a surrogate marker for the systemic activity of inhaled corticosteroid therapy. The presented method was applied to predict CCS after single doses and during short-term multiple dosing of the inhaled corticosteroids flunisolide (FLU), fluticasone propionate (FP), and triamcinolone acetonide (TCA), and after oral methylprednisolone as systemic reference therapy. Drug-specific PK and PD parameters were obtained from previous single-dose studies and extrapolated to the multiple-dose situation. For single dosing, a similar CCS within the range of 16-21% was predicted for FP 250 micrograms, FLU 500 micrograms, and TCA 1000 micrograms. For multiple dosing, a respective CCS of 28-33% was calculated for FLU 500 micrograms bid, FP 250 micrograms, bid, and TCA 1000 micrograms bid. Higher cortisol suppression compared to these single and multiple dosing regimens of the inhaled corticosteroids was predicted after oral doses of only 1 mg and 2 mg methylprednisolone, respectively. The predictive power of the approach was evaluated by comparing the PK/PD-based simulations with data reported previously in clinical studies. The predicted CCS values were in good correlation with the clinically observed results. Hence, the presented PK/PD approach allows valid predictions of CCS for single and short-term multiple dosing of inhaled corticosteroids and facilitates comparisons between different dosing regimens and steroids.

Mechanism-based PK/PD model for the lymphocytopenia induced by endogenous and exogenous corticosteroids.

OBJECTIVE: Lymphocytopenia is a sensitive surrogate marker for the immunological effects of corticosteroids. This pharmacokinetic/pharmacodynamic (PK/PD) study investigated whether the circadian variation of blood lymphocytes observed after placebo is secondary to the circadian rhythm of endogenous cortisol, and developed based on this relationship an improved PK/PD model for a more sensitive description of the effect of low-dose corticosteroid therapy on blood lymphocytes considering the net activity of the exogenous corticosteroid budesonide and endogenous cortisol. METHODS: In an open, parallel study design, 3 mg oral budesonide or placebo were given at 8.00 a.m., 4.00 p.m. and midnight to two groups of 12 volunteers. Lymphocyte counts and serum concentrations of budesonide and cortisol were monitored for 24 hours. A mechanism-based PK/PD model which considered the non-linear protein binding of cortisol and the budesonide-induced cortisol suppression was employed to relate changes in blood lymphocytes to free cortisol levels after placebo and to the net activity of free budesonide and free endogenous cortisol after active treatment. RESULTS: The circadian rhythm of blood lymphocytes observed after placebo could inversely be related to the circadian rhythm of serum cortisol. After budesonide administration, lymphocyte counts could accurately be linked to the net activity of budesonide and endogenous cortisol. The resulting EC50 values for the effect of budesonide on cortisol, budesonide on lymphocytes and cortisol on lymphocytes were 0.063 +/- 0.034, 0.22 +/- 0.13 and 26.3 +/- 15.0 ng/ml (placebo group 15.4 +/- 3.4 ng/ml), respectively. CONCLUSIONS: The presented mechanism-based PK/PD model suggests that blood lymphocytes are under physiological control of cortisol. It further indicates that endogenous and exogenous corticosteroids and their pharmacological interaction need to be considered for modeling the effects of low doses of exogenous corticosteroids on the immune system.

Modeling of pharmacokinetic/pharmacodynamic (PK/PD) relationships: concepts and perspectives.

Pharmacokinetic/pharmacodynamic (PK/PD)-modeling links dose-concentration relationships (PK) and concentration-effect relationships (PD), thereby facilitating the description and prediction of the time course of drug effects resulting from a certain dosing regimen. PK/PD-modeling approaches can basically be distinguished by four major attributes. The first characterizes the link between measured drug concentration and the response system, direct link versus indirect link. The second considers how the response system relates effect site concentration to the observed outcome, direct versus indirect response. The third regards what clinically or experimentally assessed information is used to establish the link between concentration and effect, hard link versus soft link. And the fourth considers the time dependency of pharmacodynamic model parameters, distinguishing between time-variant versus time-invariant. Application of PK/PD-modeling concepts has been identified as potentially beneficial in all phases of preclinical and clinical drug development. Although today predominantly limited to research, broader application of PK/PD-concepts in clinical therapy will provide a more rational basis for patient-specific dosage individualization and may thus guide applied pharmacotherapy to a higher level of performance.

Pharmacokinetics and pharmacodynamics of inhaled corticosteroids.

There are significant differences in the pharmacokinetic properties of inhaled corticosteroids currently used in medical practice. All are rapidly cleared from the body but they show varying levels of oral bioavailability and more importantly variation in the rate of absorption after inhalation. Oral bioavailability is lowest for fluticasone propionate, indicating a low potential for unwanted systemic corticosteroid effects. Mathematical modeling has shown pulmonary residence times to be longest for fluticasone propionate and triamcinolone acetonide but shortest for budesonide and flunisolide. These properties appear to relate to pulmonary solubility, which appears to be the rate-limiting step in the absorption process.

Pharmacokinetic and pharmacodynamic evaluation of fluticasone propionate after inhaled administration.

OBJECTIVE: To evaluate the pharmacokinetic and systemic pharmacodynamic properties of inhaled fluticasone propionate (FP). METHODS: Single doses of 0.25, 0.5, 1.0 and 3.0 mg FP were administered to groups of six healthy subjects. Serum concentration profiles of FP were monitored over 24 h by means of high-performance liquid chromatography/mass spectrometry (HPLC/MS-MS). Systemic pharmacodynamic effects were evaluated by measuring endogenous serum cortisol and circulating white blood cells, and analyzed with previously developed integrated pharmacokinetic/pharmacodynamic (PK/PD) models. RESULTS: FP showed a dose-independent terminal half-life with a mean (SD) of 6.0 (0.7) h. Maximum serum concentrations occurred 1.0 (0.5) h after administration, ranging from 90 pg.ml(-1) for the 0.25 mg dose to 400 pg.ml(-1) for the 3.0 mg dose. This, together with an estimated mean absorption time of nearly 5 h and a known oral bioavailability of less than 1%, indicates prolonged residence at and slow absorption from the lungs. In the investigated dose range, the cumulative systemic effect was dose-dependent for both markers of pharmacodynamic activity. For doses of 0.25, 0.50, 1.0 and 3.0 mg FP, the PK/PD-based cumulative systemic-effect parameters were 159, 186, 257 and 372% .h for lymphocyte suppression, 107, 186, 202 and 348% .h for granulocyte induction and 23.6%, 33.8%, 51.0% and 73.6% for cortisol reduction, respectively. The time courses of lymphocytes, granulocytes and endogenous cortisol could be sufficiently characterized with the applied PK/PD models. The measured in vivo EC50 values, 30 pg.ml(-1) and 7.3 pg.ml(-1) for white blood cells and cortisol, respectively, were in good agreement with predictions based on the in vitro relative receptor affinity of FP. CONCLUSION: After inhalation, FP follows linear pharmacokinetics and exhibits dose-dependent systemic pharmacodynamic effects that can be described by PK/PD modeling.

Basic concepts of pharmacokinetic/pharmacodynamic (PK/PD) modelling.

Pharmacokinetic (PK) and pharmacodynamic (PD) information from the scientific basis of modern pharmacotherapy. Pharmacokinetics describes the drug concentration-time courses in body fluids resulting from administration of a certain drug dose, pharmacodynamics the observed effect resulting from a certain drug concentration. The rationale for PK/PD-modelling is to link pharmacokinetics and pharmacodynamics in order to establish and evaluate dose-concentration-response relationships and subsequently describe and predict the effect-time courses resulting from a drug dose. Under pharmacokinetic steady-state conditions, concentration-effect relationships can be described by several relatively simple pharmacodynamic models, which comprise the fixed effect model, the linear model, the long-linear model, the Emax-model and the sigmoid Emax-model. Under non steady-state conditions, more complex integrated PK/PD-models are necessary to link and account for a possible temporal dissociation between the plasma concentration and the observed effect. Four basic attributes may be used to characterize PK/PD-models: First, the link between measured concentration and the pharmacologic response mechanism that mediates the observed effect, direct vs. indirect link; second, the response mechanism that mediates the observed effect, direct vs. indirect response; third, the information used to establish the link between measured concentration and observed effect, hard vs. soft link; and fourth, the time dependency of the involved pharmacodynamic parameters, time-variant vs. time-invariant. In general, PK/PD-modelling based on the underlying physiological process should be preferred whenever possible. The expanded use of PK/PD-modelling is assumed to be highly beneficial for drug development as well as applied pharmacotherapy and will most likely improve the current state of applied therapeutics.