Selecting antibacterials for outpatient parenteral antimicrobial therapy : pharmacokinetic-pharmacodynamic considerations

Some infectious diseases require management with parenteral therapy, although the patient may not need hospitalisation. Consequently, the administration of intravenous antimicrobials in a home or infusion clinic setting has now become commonplace. Outpatient parenteral antimicrobial therapy (OPAT) is considered safe, therapeutically effective and economical. A broad range of infections can be successfully managed with OPAT, although this form of treatment is unnecessary when oral therapy can be used. Many antimicrobials can be employed for OPAT and the choice of agent(s) and regimen should be based upon sound clinical and microbiological evidence. Assessments of cost and convenience should be made subsequent to these primary treatment outcome determinants. When designing an OPAT treatment regimen, the pharmacokinetic and pharmacodynamic characteristics of the individual agents should also be considered. Pharmacokinetics (PK) is the study of the time course of absorption, distribution, metabolism and elimination of drugs (what the body does to the drug). Clinical pharmacokinetic monitoring has been used to overcome the pharmacokinetic variability of antimicrobials and enable individualised dosing regimens that attain desirable antimicrobial serum concentrations. Pharmacodynamics (PD) is the study of the relationship between the serum concentration of a drug and the clinical response observed in a patient (what the drug does to the body). By combining pharmacokinetic properties (peak [C(max)] or trough [C(min)] serum concentrations, half-life, area under the curve) and pharmacodynamic properties (susceptibility results, minimum inhibitory concentrations [MIC] or minimum bactericidal concentrations [MBC], bactericidal or bacteriostatic killing, post-antibiotic effects), unique PK/PD parameters or indices (t > MIC, C(max)/MIC, AUC(24)/MIC) can be defined. Depending on the killing characteristics of a given class of antimicrobials (concentration-dependent or time-dependent), specific PK/PD parameters may predict in vitro bacterial eradication rates and correlate with in vivo microbiologic and clinical cures. An understanding of these principles will enable the clinician to vary dosing schemes and design individualised dosing regimens to achieve optimal PK/PD parameters and potentially improve patient outcomes. This paper will review basic principles of useful PK/PD parameters for various classes of antimicrobials as they may relate to OPAT. In summary, OPAT has become an important treatment option for the management of infectious diseases in the community setting. To optimise treatment course outcomes, pharmacokinetic and pharmacodynamic properties of the individual agents should be carefully considered when designing OPAT treatment regimens.     

The integration of pharmacokinetics and pathogen susceptibility data in the design of rational dosing regimens

The integration of pharmacokinetic and pathogen susceptibility data has had an increasing impact on the design of dosage regimens. Pathogen susceptibility is often described by the minimum inhibitory concentration (MIC). While the MIC is an indicator of drug potency, it does not predict pharmacologic response in vivo when drug concentrations are fluctuating. To this end, three pharmacokinetic/pharmacodynamic (PK/PD) parameters that result from indexing pharmacokinetics to MIC have proven quite useful. A number of experimental models of infection have determined the magnitude of each parameter, AUC/MIC, Cmax/MIC and %T>MIC, required for the optimal treatment of specific pathogens. These measurements have proven to be predictive of clinical outcomes as well. As a result, PK/PD breakpoints have been determined based on the likelihood that the pharmacokinetic profile of a given dose will achieve a target PK/PD parameter value. These breakpoints correlate well with treatment success or failure, particularly evident in infections conducive to microbiologic sampling such as otitis media. Therefore, PK/PD assessments have fostered a much more targeted approach to the treatment of patients with infectious diseases, and have proven useful in the selection of antimicrobial therapy and the development of novel dosing strategies.     

Integration of pharmacokinetic/pharmacodynamic modeling and simulation in the development of new anti-infective agents – minimum inhibitory concentration versus time-kill curves

The selection of appropriate doses and dosing regimens is extremely important in antimicrobial therapy in order to increase the chances of clinical success and decrease the likelihood of toxic side effects and the development of resistance. Therefore, empirical treatment of bacterial infections is not reliable enough and more rational approaches are needed. Pharmacokinetic/pharmacodynamic (PK/PD) modeling provides a powerful tool to systematically link PK and PD properties in order to predict antimicrobial efficacy. However, commonly used minimum inhibitory concentration (MIC) based PK/PD indices, although easy to obtain, have a number of limitations. Thus, more reliable PK/PD indices need to be developed. The following article provides an overview of the present PK/PD approaches used in anti-infective therapy and discusses their role in improving drug therapy.     

Pharmacokinetic and pharmacodynamic aspects of oral moxifloxacin 400 mg/day in elderly patients with acute exacerbation of chronic bronchitis

OBJECTIVE: To assess the pharmacokinetic and pharmacodynamic behaviour of moxifloxacin in 15 consecutive elderly patients with acute exacerbation of chronic bronchitis (AECB) treated with the fixed oral moxifloxacin 400 mg/day regimen with the intent of verifying which degree of exposure may be ensured by this standard regimen against AECB pathogens. METHODS: This was an open-label, observational, pharmacokinetic-pharmacodynamic study. Blood samples were collected at steady state at appropriate intervals. Moxifloxacin plasma concentrations were analysed by means of high-performance liquid chromatography. Standard pharmacokinetic parameters and pharmacodynamic determinants (peak concentration [C(max)]/minimum inhibitory concentration [MIC], area under the plasma concentration-time curve during the 24-hour observational period [AUC(24)]/MIC, pharmacodynamic breakpoints [PDBPs]) were assessed. RESULTS: The mean estimated pharmacokinetic parameters (C(max) 4.40 mg/L at 1.4 hours, AUC(24) 42.67 mg . h/L, elimination half-life 12.55 hours, total body clearance 0.16 L/h/kg) were generally similar to those observed in both young and elderly historic controls (except for higher-dose normalised C(max) and lower volume of distribution of the central compartment). Median C(max)/MIC and AUC(24)/MIC ratios for moxifloxacin in the fully assessable cases were, respectively, 67.5 and 823.9 against Streptococcus pneumoniae, 25 and 310.2 against Moraxella catharralis and 416.5 and 3647.5 against Haemophilus influenzae. Mean estimates of PDBP for achieving C(max)/MIC values of 12.2 and AUC(24)/MIC values of 125 were 0.36 and 0.35 mg/L, respectively. CONCLUSION: In patients with AECB the pharmacokinetic behaviour of moxifloxacin is not significantly altered by aging processes. This is consistent with moxifloxacin being metabolised mainly by means of phase II hepatic reactions, the activity of which was shown not to decline with age. Both the pharmacokinetic and pharmacodynamic analyses suggest that moxifloxacin 400 mg/day may be a valid therapeutic approach in the treatment of AECB in the elderly. Of note, the unmodified pharmacokinetic behaviour with no need for age-related dosage adjustments combined with the once-daily administration favouring compliance and the low potential for drug-drug pharmacokinetic interactions in case of polytherapy, make moxifloxacin particularly attractive in the treatment of elderly subpopulations at a very high risk of AECB.     

Application of the MIC breakpoints based on pharmacokinetics and pharmacodynamics parameter in the clinical laboratory

The effectiveness of time-dependent antibiotics such as beta-lactams is related to the time above the MIC (TAM, %). We constructed a program to calculate the TAMs of beta-lactams using the pharmacokinetic parameters of the Japanese dosing regimen of a phase I study of the Japanese Society for Antimicrobial Chemotherapy (JSAC), and compared them with the MIC breakpoints published by the National Committee for Clinical Laboratory Standards (NCCLS) and JSAC. If the effective TAM was assumed to be more than 40% of the dosing interval, the pharmacokinetic/pharmacodynamic (PK/PD) breakpoints calculated by our program were in agreement with the JSAC breakpoints for pneumonia within 1 dilution MIC. When comparing with the NCCLS breakpoints for Enterobacteriaceae or Staphylococcus, the PK/PD breakpoints dosing three times per day of ampicillin (1 g, intravenous dose; i.v.), piperacillin (2 g, i.v.), cefotaxime (1 g, i.v.) and cefmetazole (1 g, i.v.) were calculated to be less than 2-fold dilution MIC, and those of amoxicillin (0.25 g, oral dose; p.o.) and cefaclor (0.5 g, p.o.) were calculated to be less than 3- to 4-fold dilution of MIC. Our program could calculate TAMs and PK/PD breakpoints by inputting the two factors of MIC and dosing interval. If this information is routinely reported to physicians from clinical laboratories, an appropriate dosing schedule could be proposed for various infectious cases.     

Population pharmacokinetics of ceftriaxone and pharmacodynamic considerations in haemodialysed patients

OBJECTIVES: To determine the pharmacokinetic parameters of ceftriaxone following an infusion in haemodialysed outpatients and to use these parameters for an optimisation of dosing based on pharmacodynamic indices. METHODS: Fifty haemodialysed patients were enrolled in a single-centre, prospective, open-label study. They received short intravenous infusions of ceftriaxone 1 or 2 g every 48 hours for bronchopneumonia immediately after the dialysis session. Total plasma concentrations of ceftriaxone were analysed with a population pharmacokinetic approach using nonlinear mixed-effects modelling. Free drug concentrations were derived from published binding parameters in order to estimate the time when they exceed the minimum inhibitory concentration (MIC). RESULTS: The pharmacokinetics were best described by a two-compartment model. None of the covariates tested (age, bodyweight, height, sex, body mass index, albumin) influenced the pharmacokinetic parameters. The estimated population pharmacokinetic parameters (interindividual variability [percentage of coefficient of variation]) were clearance 0.36 L/h (48%), volume of distribution of the central compartment 4.53 L (47%), intercompartmental clearance 10.8 L/h and volume of distribution of the peripheral compartment 9.54 L (63%). The terminal elimination half-life (t(1/2)beta) from plasma was 27.5 hours. The mean (range) times when the free drug concentration exceeded the MIC (T>MIC) following ceftriaxone 1 g infusion were 60.3 (53.0-67.7) hours and 2.5 (1.0-3.9) hours for the breakpoints 1 and 8 mg/L (based on free drug concentration), respectively. After administration of ceftriaxone 2 g, the T>MIC was 88.5 (78.8-98.3) hours and 17.7 (13.3-22.0) hours for the breakpoints 1 and 8 mg/L, respectively. The simulated free drug concentrations (median, first and third quartile) for 48 and 72 hours following the first dose of ceftriaxone 1g were 1.11, 0.63 and 1.89 mg/L, and 0.63, 0.28 and 1.18 mg/L, respectively. For ceftriaxone 2g infusion, the simulated free concentrations (median, first and third quartile) at 48 and 72 hours were 2.50, 1.40 and 4.52 mg/L, and 1.37, 0.60 and 2.70 mg/L, respectively. CONCLUSIONS: On the basis of decreased clearance in haemodialysed patients, it can be argued that the dose of ceftriaxone should be decreased or the delay between doses should be increased. However, taking into account pharmacodynamic considerations, this study showed that following intravenous administration of ceftriaxone 1 g after each dialysis session, some patients were at risk of achieving a concentration below the MIC (1 mg/L), particularly if the second administration occurred 72 hours after the first dosing. Thus, a dose of ceftriaxone 2 g intravenously is recommended immediately following dialysis, particularly in patients with severe infections or when the dosing interval will be higher than 48 hours.     

NCCLS perspectives in changing susceptibility breakpoints for antimicrobial drugs

The spread of resistance to many antimicrobial agents in various microbial species has been highlighted by the World Health Organisation and many government agencies around the world. The reasons for this increase and spread are complex and are discussed. A number of surveillance studies has monitored the increase in resistance among isolates of Streptococcus pneumoniae to various important classes of antimicrobials. These results are discussed with particular reference to penicillins, macrolides and fluoroquinolones. Although there is evidence that in vitro resistance to macrolides and more recently to fluoroquinolones may be associated with a reduced clinical efficacy, there is no such clear association with resistance to beta-lactams and lack of clinical efficacy in non-meningeal infections. Resistance or susceptibility to an antimicrobial agent is based on breakpoints and these are set in the US by the National Committee of Clinical and Laboratory Standards. In response to these recent clinical studies showing that non-meningeal pneumococcal infections with strains classified as resistant in vitro still responded well to treatment with various beta-lactams, new breakpoints have been set. Results are presented showing that using these breakpoints, the levels of resistance to the third generation cephalosporins, ceftriaxone and cefotaxime against a range of non-meningeal pneumococcal isolates were lower than those obtained using the previous breakpoints. The excellent pharmacokinetic and pharmacodynamic properties of these agents are believed to contribute to their good activity in the clinic.     

Pharmacokinetics and pharmacodynamics of ceftizoxime in patients with dosages adjusted for renal function

STUDY OBJECTIVE: Our institution developed dosing guidelines for patients with renal impairment based on pharmacokinetic data and class-specific pharmacodynamics. Ceftizoxime was chosen as a model agent to evaluate if the modified guidelines achieved similar minimal plasma concentration (Cp(min)) and time above the minimum inhibitory concentration of the infecting organism (T>MIC) in patients with renal impairment versus those with normal renal function. DESIGN: Prospective pharmacokinetic and pharmacodynamic evaluation of ceftizoxime dosages. SETTING: University-affiliated hospital. PATIENTS: Forty-three patients with suspected or documented infection were enrolled and classified into four groups based on creatinine clearance (Cl(cr); ml/min): group 1, above 100; group 2, 61-99; group 3, 31-60; and group 4, 15-30. INTERVENTIONS: Ceftizoxime serum concentrations were obtained at steady state. MEASUREMENTS AND MAIN RESULTS: Pharmacokinetic and pharmacodynamic parameters were calculated. As expected, clearance and elimination rate constant were reduced, and half-life tended to be greater in patients with renal impairment. The Cp(min) and area under the concentration-time curve over 24 hours were similar between groups (p=0.39, p=0.42). The T>MIC was 100% for all patient isolates, and 90% or more versus our clinical strain for all groups. Clinical outcomes were similar among all groups. CONCLUSION: Our dosing guidelines achieved similar Cp(min) among all groups of patients. Our results support that recommendations for dosing adjustments should be based on pharmacokinetic data and must also consider pharmacodynamic parameters.     

Pharmacodynamics of doxycycline for chemoprophylaxis of Lyme disease: preliminary findings and possible implications for other antimicrobials

The purpose of this study was to begin to characterise the pharmacodynamic parameters of single-dose doxycycline for the prevention of Lyme disease following a tick bite. Based on limited data from published human and murine studies, it was found that there is a direct correlation between efficacy rate and the area under the time-concentration of free antibiotic curve divided by the minimum inhibitory concentration (fAUC/MIC) (R(2)=0.74, using Pearson correlation), but not the maximum concentration of free drug in serum divided by the MIC (fC(max)/MIC) or the time that the free drug concentration remains above the MIC (fT>MIC). To determine the possible implications of these findings for other antimicrobials, it was assumed that the pharmacodynamic properties of doxycycline would be pertinent to azithromycin, an antibiotic whose activity is known to correlate with AUC/MIC. By making such an extrapolation and using pharmacokinetic modelling with conservative assumptions on MIC values against Borrelia burgdorferi, it is hypothesised that a single 500 mg dose of azithromycin in humans should have comparable efficacy to doxycycline for the prevention of Lyme disease. Additional experimental studies are needed to clarify more precisely the pharmacodynamic properties of doxycycline and to validate the accuracy of this hypothesis.     

The role of tazobactam-based combinations for the management of infections due to extended-spectrum β-lactamase-producing Enterobacterales: Insights from the Society of Infectious Diseases Pharmacists

Extended-spectrum β-lactamase (ESBL)-producing Enterobacterales are a global threat to public health due to their antimicrobial resistance profile and, consequently, their limited available treatment options. Tazobactam is a sulfone β-lactamase inhibitor with in vitro inhibitory activity against common ESBLs in Enterobacterales, including CTX-M. However, the role of tazobactam-based combinations in treating infections caused by ESBL-producing Enterobacterales remains unclear. In the United States, two tazobactam-based combinations are available, piperacillin-tazobactam and ceftolozane-tazobactam. We evaluated and compared the roles of tazobactam-based combinations against ESBL-producing organisms with emphasis on pharmacokinetic/pharmacodynamic exposures in relation to MIC distributions and established breakpoints, clinical outcomes data specific to infection site, and considerations for downstream effects with these agents regarding antimicrobial resistance development. While limited data with ceftolozane-tazobactam are encouraging for its potential role in infections due to ESBL-producing Enterobacterales, further evidence is needed to determine its place in therapy. Conversely, currently available microbiologic, pharmacokinetic, pharmacodynamic, and clinical data do not suggest a role for piperacillin-tazobactam, and we caution clinicians against its usage for these infections.     

Pharmacodynamic analysis of the microbiological efficacy of telithromycin in patients with community-acquired pneumonia

BACKGROUND AND OBJECTIVE: Telithromycin, a ketolide antibacterial, demonstrates concentration-dependent bactericidal activity against the major pathogens causing community-acquired respiratory tract infections. The objective of this study was to explore the relationships between pharmacokinetic/pharmacodynamic predictor variables, such as area under the plasma concentration-time curve (AUC) over minimum inhibitory concentration (MIC) [AUC/MIC], maximum plasma concentration (C(max)) over MIC (C(max)/MIC) and microbiological outcome from telithromycin therapy for community-acquired pneumonia (CAP). PATIENTS AND METHODS: Data were pooled from five phase III studies of oral telithromycin (800 mg once daily for 7-10 days) for the outpatient treatment of adults with CAP. Only subjects with a single pathogen isolated at baseline, a telithromycin MIC determination and at least one plasma pharmacokinetic sample were included. Bacteriologically modified intent-to-treat (bmITT) and bacteriologically evaluable per protocol (PPb) populations were analysed. Individual AUC and C(max) Bayesian estimates were obtained with a population pharmacokinetic model. Logistic regression, nonparametric smoothing, and classification analysis and regression tree (CART) were used to assess the relationship between AUC/MIC and C(max)/MIC and microbiological outcome by pathogen. RESULTS: The bmITT population included 224 patients (Streptococcus pneumoniae in 113, Haemophilus influenzae in 89 and Staphylococcus aureus in 22). Median telithromycin MIC was 0.015 microg/mL for S. pneumoniae, 2.0 microg/mL for H. influenzae and 0.12 microg/mL for S. aureus, with median AUC/MIC of 907.1, 6.9 and 98.4, and median C(max)/MIC of 172.0, 1.3 and 20.4 for the three pathogens, respectively. Both logistic regression and nonparametric smoothing showed the probability of microbiological cure to be consistently greater than 90% over the observed range of predictor variables. No reliable AUC/MIC or C(max)/MIC breakpoints were identified by CART. CONCLUSION: Telithromycin exhibits near-maximal efficacy against three major pathogens causing CAP at a dose of 800 mg once daily.     

Pharmacokinetics and pharmacodynamics of levofloxacin in intensive care patients

OBJECTIVE: A prospective pharmacokinetic study was performed in Caucasian patients from an intensive care unit with respiratory support to evaluate the influence of this circumstance on the pharmacokinetic behaviour of levofloxacin. PATIENTS AND METHODS: A standard dosage regimen of 500 mg/day was administered to nine Caucasian patients included in the study, irrespective of their demographic characteristics. The experimental data on plasma concentrations were analysed by independent-modelling techniques to estimate the following pharmacokinetic parameters: area under the plasma concentration-time curve (AUC), volume of distribution at steady state (V(ss)), plasma clearance (CL), maximum plasma concentration at steady state (C(max)(,)(ss)) and elimination half-life (t((1/2))(beta)). Multiple regression analysis was applied to establish the type of correlation between the pharmacokinetic parameters and patient characteristics; the Monte Carlo simulation technique was implemented for the pharmacokinetic/pharmacodynamic analysis based on the probability distribution of the values of AUC/minimum inhibitory concentration (MIC) and C(max)(,)(ss)/MIC observed in this group of patients. RESULTS AND CONCLUSION: The results show that for AUC the simplest linear model with creatinine clearance as the only independent variable fits the data at a 99% confidence level, explaining more than 85% of the observed variability in this parameter. The volume of distribution, however, showed a statistical correlation with the severity of the illness (Simplified Acute Physiology Score II), although total bodyweight also explains a high percentage of variability of these parameters. Since the group of patients included in the study was small and also included obese individuals, it is difficult to estimate with precision the contribution of each circumstance (overweight or illness severity) to the pharmacokinetic behaviour of levofloxacin.     

Pharmacokinetic/pharmacodynamic modelling of antibacterials in vitro and in vivo using bacterial growth and kill kinetics: the minimum inhibitory concentration versus stationary concentration

BACKGROUND: The minimum inhibitory concentration (MIC) is the in vitro reference value to describe the activity of an antibacterial against micro-organisms. It does not represent the dynamic effect of the antimicrobial at any point in time, but rather the total antimicrobial effect over the incubation period at a fixed concentration. OBJECTIVE: To explore the concentration-effect relationship of antimicrobial concentrations against micro-organisms in relation to the MIC. METHODS: Time-kill curves were generated for ceftazidime, meropenem and tobramycin against Pseudomonas aeruginosa. The Hill equation with variable slope was fit to the time-kill data, and mathematical models of growth and kill were explored with reference to the MIC. RESULTS: With declining concentrations, bacterial killing will decrease until a specific threshold concentration is reached. This concentration, at which bacteria are neither killed nor able to grow, is named the stationary concentration (SC) and is not equal to the MIC. Pharmacokinetic/pharmacodynamic simulations over a range of kill rates, growth rates and slope factors showed that for beta-lactam antibacterials, the SC is close to the MIC value, which may explain why concentrations in vivo need to be above the MIC, while regrowth of bacteria occurs when concentrations decline below the MIC. For concentration-dependent antibacterials, such as aminoglycosides and quinolones, the SC is shown to be markedly different from the MIC and, in general, is much lower. CONCLUSION: The MIC is not a good pharmacodynamic parameter to characterise the concentration effect relationship of a given antimicrobial. For 'concentration independent' antimicrobials the SC is likely to be close to the MIC, but may be much lower for 'concentration dependent' antimicrobials, and may explain sub-MIC effects.     

Class-dependent relevance of tissue distribution in the interpretation of anti-infective pharmacokinetic/pharmacodynamic indices

The pharmacokinetic/pharmacodynamic (PK/PD) indices useful for predicting antimicrobial clinical efficacy are well established. The most common indices include the time free drug concentration in plasma is above the minimum inhibitory concentration (MIC) (fT_>MIC) expressed as a percent of the dosing interval, the ratio of maximum concentration to MIC (C_max/MIC), and the ratio of the area under the 24-h concentration–time curve to MIC (AUC_0–24/MIC). A single PK/PD index may correlate well with an entire antimicrobial class. For example, the β-lactams correlate well with the fT_>MIC. However, other classes may be more complex and a single index cannot be generalised to the class, e.g. the macrolides. The rationale behind which PK/PD index best correlates with efficacy depends on several factors, including the mechanism of action, the microbial kill kinetics, the degree of protein binding and the degree of tissue distribution. Studies have traditionally emphasised the first two factors, whilst the significance of protein binding and tissue distribution is increasingly appreciated. In fact, the latter two factors may partially elucidate why the magnitude of reported target indices are not always as expected. For example, tigecycline and telithromycin are clinically efficacious with average serum concentrations below their MICs over a 24-h period. Therefore, to understand more fully the PK/PD relationship of antibiotics and to better predict the clinical efficacy of antibiotic dosing regimens, assessment of free drug concentrations at the site of action is warranted.     

Pharmacological considerations for the proper clinical use of aminoglycosides

Aminoglycosides constitute one of the oldest classes of antimicrobials. Despite their toxicity, mainly nephrotoxicity and ototoxicity, aminoglycosides are valuable in current clinical practice, since they retain good activity against multidrug-resistant Gram-negative pathogens, such as Pseudomonas aeruginosa and Acinetobacter spp. Time-kill studies have shown a concentration-dependent and partially concentration-dependent bacterial killing against Gram-negative and Gram-positive bacteria, respectively. Pharmacodynamic data gathered over recent decades show that the administration of aminoglycosides by an extended-interval dosing scheme takes advantage of the maximum potential of these agents, with the goal of achieving an area under the concentration-time curve (AUC) of 100?mg?·?h/L over 24 hours and a peak plasma drug concentration (C(max)) to minimum inhibitory concentration (MIC) ratio of 8-10. Several clinical conditions that are common in seriously ill patients result in expansion of the extracellular space and can lead to a lower than desirable C(max) with the usual loading dose. Extended-interval dosing schemes allow adequate time to decrease bacterial adaptive resistance, a phenomenon characterized by slow concentration-independent killing. Adaptive resistance is minimized by the complete clearance of the drug before the subsequent dose, thus favouring the extended-interval dosing schemes. The efficacy of these schemes is also safeguarded by the observed post-antibiotic sub-MIC effect and post-antibiotic leukocyte enhancement, which inhibit bacterial regrowth when the serum aminoglycoside levels fall below the MIC of the pathogen. In everyday clinical practice, aminoglycosides are usually used empirically to treat severe sepsis and septic shock while awaiting the results of antimicrobial susceptibility testing. The European Committee on Antimicrobial Susceptibility Testing acknowledges the regimen-dependent nature of clinical breakpoints for aminoglycosides, i.e. of MIC values that classify bacterial isolates into sensitive or resistant, and bases its recommendations on extended-interval dosing. To a large extent, the lack of correlation between in vitro antimicrobial susceptibility testing and clinical outcome is derived from the fact that the available clinical breakpoints for aminoglycosides are set based on mean pharmacokinetic parameters obtained in healthy volunteers and not sick patients. The nephrotoxicity associated with once- versus multiple-daily administration of aminoglycosides has been assessed in numerous prospective randomized trials and by several meta-analyses. The once-daily dosing schedule provides a longer time of administration until the threshold for nephrotoxicity is met. Regarding ototoxicity, no dosing regimen appears to be less ototoxic than another. Inactivation of aminoglycosides inside the bacterial pathogens occurs by diverse modifying enzymes and by operation of multidrug efflux systems, making both of these potential targets for inhibition. In summary, despite their use for several decades, the ideal method of administration and the preferred dosing schemes of aminoglycosides for most of their therapeutic indications need further refinement. Individualized pharmacodynamic monitoring has the potential of minimizing the toxicity and the clinical failures of these agents in critically ill patients.     

Impact of pharmacodynamic variability on drug delivery(1)

Modern pharmaceutical delivery systems are intended to produce plasma drug concentration versus time profiles that result in optimum therapeutic efficacy and a minimum of drug concentration-dependent adverse effects. To accomplish this requires that the drug delivery rate and temporal profile be based on the pharmacokinetic and pharmacodynamic characteristics of the specific medicinal agent. Pharmacokinetic and pharmacodynamic parameters are subject to considerable interindividual variability. Whereas the importance of pharmacokinetic variability is generally recognized, the significance of pharmacodynamic variability (i.e., variability in the relationship between effect intensity and drug concentration) is not as widely appreciated. Pharmacodynamic variability is typically quite large, reproducible, and often substantially exceeds the relative magnitude of pharmacokinetic variability. This article consists of a review of how to assess pharmacodynamic variability, clinical examples of pharmacodynamic variability of drugs with a wide range of indications, and an outline of mechanisms of pharmacodynamic variability.     

A retrospective analysis of pharmacokinetic-pharmacodynamic parameters as indicators of the clinical efficacy of ceftizoxime

OBJECTIVE: To analyse the relationship between a series of estimated pharmacokinetic-pharmacodynamic parameters and the reported efficacy of ceftizoxime. DESIGN: Retrospective literature search and analysis using different correlation models. METHODS: The following parameters were calculated for each group of patients included in the study from the simulated plasma concentration curves corresponding to the dosage regimen administered: (i) peak concentration at steady state divided by the minimum inhibitory concentration (CmaxSS/MIC); (ii) the time that the plasma drug concentration exceeded the MIC scaled to 24 hours at steady state [(tSS)24h > MIC]; (iii) the total area under the concentration-time curve over 24 hours at steady state divided by the MIC [(AUC(SS))24h/MIC]; and (iv) the AUC at steady state for the period of time that the concentration is above the MIC over a period of 24 hours divided by the MIC [(AUIC(SS))24h]. A univariate correlation analysis was performed considering efficacy [rate (%) of clinical cure or bacterial eradication] as the dependent variable and the pharmacokinetic-pharmacodynamic parameter as the independent variable, using linear and nonlinear models. RESULTS: (tSS)24h > MIC was the only parameter that was statistically correlated with efficacy, the linear model being the best choice among the 4 relationship approaches tested. A biased frequency distribution of reported efficacy data constricts the correlation analysis to a narrow range of efficacy and hinders interpretation of the results. CONCLUSIONS: The reporting of cases with low efficacy rates as well as those with high efficacy rates, including information on patient idiosyncrasies and the infecting organisms, would be of great help in performing retrospective analyses of the use of antimicrobial agents, leading to the optimisation of therapy with this type of drug in clinical practice.     

Gemifloxacin: effects of sub-inhibitory concentrations on various factors affecting bacterial virulence

This study investigated the ability of sub-MICs of gemifloxacin to interfere with the bacterial virulence parameters of adhesiveness, haemagglutination, hydrophobicity and motility, as well as their interactions with host neutrophilic defences such as phagocytosis, killing and respiratory bursts. The adhesiveness of both Escherichia coli and Staphylococcus aureus was significantly reduced to a subinhibitory concentration of 1/32 MIC. Indirect fimbriation parameters, such as hydrophobicity and haemagglutination were significantly reduced at a concentration of 1/8 MIC, as was migration (swarming). Phagocytosis and the respiratory burst measured by means of chemiluminescence were not affected, but killing was significantly increased from 1/2 to 1/8 MIC. The interpolation of these pharmacodynamic findings with pharmacokinetic curves indicates that sub-MIC concentrations of gemifloxacin can prolong antimicrobial effects on virulence determinants up to 27 h after the antimicrobial concentration has fallen below the MIC value.     

The epidemiology of antibiotic resistance in Streptococcus pneumoniae and the clinical relevance of resistance to cephalosporins, macrolides and quinolones

Invasive non-meningeal pneumococcal infections remain a major cause of morbidity and mortality worldwide. The factors affecting the epidemiology and mortality of pneumococcal infections are discussed. The increase and spread of resistance to antimicrobial agents among pneumococci is a cause of concern to the clinician. There are links between the usage of antibacterial agents and the development of resistance. Resistance to penicillin and other beta-lactams has become widespread but this does not appear to have decreased the efficacy of some of these agents against non-meningeal infections. There is evidence that the good pharmacokinetic and pharmacodynamic features of the third generation cephalosporins (cefotaxime and ceftriaxone) contribute to their efficacy in vivo. New breakpoints for cefotaxime and ceftriaxone against non-meningeal pneumococcal isolates were proposed by the National Committee for Clinical Laboratory Standard (NCCLS, US), based on the clinical evidence of the efficacy of these drugs. In contrast there is increasing evidence that resistance to macrolides can lead to a poor clinical response. Fluoroquinolones have been widely used to treat respiratory tract infections among others, and pneumococcal resistance to these agents in vitro, although currently low, is increasing. There are reports that resistance to fluoroquinolones can develop during treatment and may be reflected in a lack of clinical response. Several clinical and epidemiological variables (e.g. prior antibiotic use) can be useful to identify patients at risk from infections with antibiotic-resistant pneumococci. These patients would be those who would benefit the most from a pneumococcal vaccination programme.     

A tissue cage model in calves for studies on pharmacokinetic/pharmacodynamic interactions of antimicrobials

An in vivo model for studies of pharmacokinetic/pharmacodynamic (PK/PD) interactions of antimicrobials was developed. Tissue cages with a constant surface area but with different volumes were implanted in calves and infected with Mannheimia haemolytica. Penicillin was injected directly into the cages. With this procedure, different concentration-time profiles could be simulated so that the effect of a range of PK/PD indices on the infection could be monitored. The area under the curve to minimum inhibitory concentration (MIC) and time above MIC were equally predictive for effect, but Cmax to MIC was not. If drug dosages in relation to the MIC of strains used for infection are optimised, the model offers an interesting alternative to explore relevant factors for drug dosage optimisation.