"Iatrogenicity cascade": doing harm by treating harm?

An electronic survey on substance-induced epileptic crisis was conducted in order to investigate whether doctors, who recognise their own prescription errors, increase their therapeutic aggressiveness, resulting in a so-called "iatrogenicity cascade". Two pairs of clinical vignettes were constructed, in which a patient suffers from iatrogenic (original version) or non-iatrogenic (control version) epileptic crisis. Vignettes were randomised and sent to doctors at the University Hospital of Lausanne, Switzerland, at an interval of 3 weeks. The results of the present survey in the surveyed population of doctors suggest that inappropriate prescription does not increase therapeutic aggressiveness.

Protein binding of antimicrobials: methods for quantification and for investigation of its impact on bacterial killing.

Plasma protein binding of antimicrobial agents is considered to be a key characteristic of antibiotics as it affects both their pharmacokinetics and pharmacodynamics. However, up to the present, no standard methods for measuring protein binding or for quantification of the influence of protein binding on antimicrobial activity exist. This short-coming has previously led to conflicting results on antibacterial activity of highly protein-bound antibiotics. The present review, therefore, set out to summarize (1) methods for quantification of protein binding, (2) microbiological growth media used for determination of the impact of protein binding on antimicrobial activity of antibiotics, and (3) different pharmacodynamic in vitro studies that are used in this context. The advantages and disadvantages of a wide range of different approaches are discussed and compared. The urgent call for international standardization by microbiological societies and laboratories may be considered as a logical consequence of the presented data.

Ketolides--the modern relatives of macrolides : the pharmacokinetic perspective.

As with other widely used antibacterials, the abundant use of macrolides for management of ambulant infections has promoted emergence of resistance against them. Ketolides are structurally related to macrolides and were developed to overcome macrolide resistance, while sharing pharmacodynamic and pharmacokinetic characteristics. However, until now, there have been no comprehensive reviews of the comparative pharmacokinetics of macrolides and ketolides. This article reviews the pharmacokinetic parameters in plasma and relevant tissues of telithromycin, the only approved ketolide, and cethromycin, which is currently in phase III of clinical development. For comparison, the 14-membered macrolides clarithromycin and roxithromycin and the 15-membered azalide azithromycin were chosen as representatives of their class. While telithromycin achieves higher plasma concentrations than cethromycin, both antimicrobials display comparable elimination half-lives and clearance. Repeated dosing rarely influences the pharmacokinetic parameters of ketolides. Despite substantially higher maximum plasma concentrations and area under the plasma concentration-time curve (AUC) values of telithromycin, the higher antimicrobial activity of cethromycin leads to similar ratios between the AUC from 0 to 24 hours (AUC(24)) and the minimum inhibitory concentration (MIC) for relevant pathogens, suggesting comparable antimicrobial activity of both antimicrobials in plasma. Although telithromycin and cethromycin show plasma-protein binding of 90%, they have excellent tissue penetration, as indicated by volumes of distribution of about 500 L and high intracellular concentrations. Besides enhancing killing of intracellular pathogens, the high concentrations of macrolides, azalides and ketolides in leukocytes have been associated with increased delivery of the antimicrobial agent to the site of infection. Although telithromycin has been shown to accumulate in alveolar macrophages and epithelial lining fluid by 380- and 15-fold, respectively (relative to plasma concentrations), its concentration in the interstitium of soft tissues is comparable to the free fraction in plasma. Thus the pharmacokinetics of ketolides may help to explain their good activity against a wide range of respiratory tract infections, although pharmacokinetic/pharmacodynamic calculations based on plasma pharmacokinetics would indicate only minor activity against pathogens except streptococci. In contrast, AUC(24)/MIC ratios achieved in soft tissue may be considered insufficient to kill extracellular pathogens causing soft tissue infections, except for Streptococcus pyogenes. Although ketolides and macrolides share relevant pharmacokinetic properties, the pharmacokinetics of both antimicrobial classes are not considered interchangeable. With a volume of distribution similar to that of azithromycin but plasma concentrations and an elimination half-life reflecting those of clarithromycin, the pharmacokinetics of ketolides may be considered 'intermediate' between those of macrolides and azalides. Thus the pharmacokinetics of ketolides can be considered similar but not identical to those of macrolides.

Microdosing studies in humans: the role of positron emission tomography.

Positron emission tomography (PET)-microdosing comprises the administration of a carbon-11- or fluorine-18-labelled drug candidate to human subjects in order to describe the drug's concentration-time profile in body tissues targeted for treatment. As PET microdosing involves the administration of only microgram amounts of unlabelled drug, the potential toxicological risk to human subjects is very limited. Consequently, regulatory authorities require reduced preclinical safety testing as compared with conventional phase 1 studies. Microdose studies are gaining increasing importance in clinical drug research as they have the potential to shorten time-lines and cut costs along the critical path of drug development. Current applications of PET in anticancer, anti-infective and CNS system drug research are reviewed.

Positron emission tomography for use in microdosing studies.

Positron emission tomography (PET) imaging using microdoses of radiolabeled drug tracers is gaining increasing acceptance in modern clinical drug development. This approach is unique in that it allows for direct quantitative assessment of drug concentrations in the tissues targeted for treatment, thereby bridging the gap between pharmacokinetics and pharmacodynamics. Current applications of PET in anticancer, anti-infective and central nervous system drug research are reviewed herein. Situated at the interface of preclinical and clinical drug testing, PET microdosing is a powerful and highly innovative tool for pharmaceutical development.