Mark W. Garrison

Assessment of effects of protein binding on daptomycin and vancomycin killing of Staphylococcus aureus by using an in vitro pharmacodynamic model.

Initial clinical trials with daptomycin (2 mg/kg per day) were prematurely suspended because of unexplained treatment failures in patients with bacteremia who were treated with daptomycin, despite in vitro data indicating that the gram-positive cocci causing the infection were susceptible to daptomycin. One explanation for these clinical failures may relate to the relatively high degree of daptomycin protein binding (94%). To evaluate the impact of protein on daptomycin activity, a two-chamber in vitro pharmacodynamic model was used to study and compare the interaction between Staphylococcus aureus (clinical isolate) and either daptomycin or vancomycin, each in the presence and absence of physiologic human albumin concentrations. Low-dose (2 mg/kg) daptomycin, high-dose (6 mg/kg) daptomycin, and 10 mg of vancomycin per kg beta-phase elimination serum-concentration-versus-time curves were simulated by using this in vitro pharmacodynamic model. The bacterial kill rates by all three regimens were decreased in the presence of albumin (P less than 0.0002). The average times required for a 99% kill of the initial S. aureus inocula (approximately 5 x 10(7) CFU/ml) without albumin were 0.81 (low-dose daptomycin), 0.33 (high-dose daptomycin), and 6.18 (vancomycin) h. The average times required for a 99% kill of S. aureus with albumin were 7.66 (low-dose daptomycin), 0.95 (high-dose daptomycin), and 10.52 (vancomycin) h. These data demonstrate that, depending on the concentration of daptomycin, the presence of albumin can profoundly diminish the bactericidal activity of daptomycin.

Levofloxacin: A Therapeutic Review

This therapeutic review discusses the pharmacology, pharmacokinetics, in vitro activity, drug interactions, and adverse effects of levofloxacin, a fluoroquinolone antibiotic. Particular emphasis is placed on the clinical efficacy of levofloxacin and its place in therapy. Compared with ciprofloxacin and the earlier quinolone agents, levofloxacin has an improved pharmacokinetic profile that allows convenient once-daily dosing in either an oral or parenteral formulation. Levofloxacin has enhanced activity against gram-positive aerobic organisms, including penicillin-resistant pneumococci. In published comparative trials involving commonly used treatment regimens, levofloxacin had equivalent if not greater activity in the treatment of community-acquired pneumonia, acute bacterial exacerbations of chronic bronchitis, acute bacterial sinusitis, acute pyelonephritis, and complicated urinary tract infection. Levofloxacin is well tolerated and induces minimal adverse drug reactions. Based on the above attributes, it may be reasonable to include levofloxacin on the hospital formulary in place of older quinolones. More recently released quinolones such as trovafloxacin exhibit similar advantages; however, until direct comparative trials between levofloxacin and these newer agents are conducted, it is difficult to advocate one agent over another. Regardless of which quinolone is the primary agent on the formulary, it is imperative that this class of antimicrobial drugs be used with discretion to minimize the development of resistance.

Individualizing vancomycin dosage regimens: One- versus two-compartment Bayesian models

The absolute and relative predictive performances of one- and two-compartment Bayesian forecasting models were evaluated and compared. Initial population parameters were derived from 25 adult patients with stable renal function and who were being treated for presumed or documented gram-positive infections. The performance of each model was compared using these population parameters with and without steady-state or non-steady-state feedback concentrations to predict future peak and trough concentrations in an additional 20 patients. Both models tended to underpredict vancomycin peak and trough concentrations obtained at steady state. The use of a two-compartment model resulted in statistically less bias and more precise predictions of vancomycin peak concentrations when either population parameters or non-steady-state concentrations were used for future predictions. No difference in model performance was observed when steady-state concentrations were used to predict future steady-state concentrations. The results of this evaluation demonstrate that the two-compartment Bayesian model is less biased and more precise in determining future vancomycin serum concentrations given only population parameters or non-steady-state feedback information. No difference in model performance could be discerned when steady-state concentrations were used as feedback information.

Evaluation of a two-compartment bayesian forecasting program for predicting vancomycin concentrations

Summary: The application of a two-compartment Bayesian forecasting program for vancomycin was tested retrospectively in 45 adult patients with stable renal function. Serial blood samples from 25 of these patients were used to determine population-based parameter estimates. The predictive performance of the Bayesian program was assessed by using both non-steady-state and steady-state vancomycin concentrations as feedback information. Overall, the program tended to underpredict peak and trough steady-state vancomycin serum concentrations. A larger mean prediction error (ME) was seen when non-steady-state feedback serum concentrations were used compared with using population-based parameter estimates (no feedback). In contrast, a marked improvement in ME (peaks: −1.03 versus −2.61; troughs: −1.60 versus −2.07) was seen when steady-state feedback serum concentrations were used compared with no feedback data. Precision improved when either feedback serum concentrations were used to predict steady-state peak and trough vancomycin concentrations. The results from this clinical evaluation demonstrate that the initial pharmacokinetic parameter estimates for a two-compartment Bayesian model provided accurate prediction of steady-state vancomycin concentrations. Prediction bias and precision were improved when steady-state vancomycin concentrations were used to determine individualized pharmacokinetic parameters.

Comparison of various in vitro susceptibility methods for testing Stenotrophomonas maltophilia

A total of 57 clinical isolates were screened by disk diffusion for a related pharmacodynamic study. Testing was performed using National Committee for Clinical Laboratory Standards guidelines, except that results were interpreted at 16 to 18 h and 48 h. Of the 57 isolates, 19 were randomly chosen for additional comparative susceptibility testing of five methods (disk diffusion, Etest, Alamar colorimetric broth microdilution, Vitek, and MicroScan) and an in-house broth microdilution method. The two diffusion methods (disk and Etest) had the closest correlation. The commercial broth microdilution methods and the in-house microdilution method generated inconsistent results for all agents except trimethoprim-sulfamethoxazole. Vitek compared poorly with both diffusion and microbroth dilution methods. The most significant discrepancies were evident with all methods when the incubation period was extended to 48 h. When results were interpreted at 48 h, the incidence of resistance for all bactericidal agents was approximately double the resistance observed at 16 to 18 h. The bacteriostatic agents, trimethoprim-sulfamethoxazole and doxycycline, demonstrated the greatest in vitro activity and were least influenced by extended incubation with diffusion methods. Because correlative in vivo and in vitro studies have not revealed an effective therapeutic regimen for serious S. maltophilia infections, susceptibility results with all testing methods should be interpreted with caution when choosing therapy for patients with life-threatening infections. Susceptibility testing for this heterogeneous group remains controversial and routine testing, with the possible exception of doxycycline (or minocycline) and trimethoprim-sulfamethoxazole, should be avoided. Our data support that if testing is done with bactericidal agents, consideration should be given to interpretation after 48-h incubation.

Aminoglycosides: Another Perspective

Despite the introduction of several new classes of antimicrobial agents, aminoglycosides are still recognized as first-line therapeutic agents in the management of severe gram-negative sepsis. The major obstacle limiting the use of aminoglycoside antibiotics has been, and continues to be, the possibility of drug-induced ototoxicity and nephrotoxicity. This review critically examines the definitions used to establish the diagnosis of aminoglycoside-induced nephrotoxicity and ototoxicity and the clinical significance of these adverse reactions. The review also focuses on the practical and economic issues surrounding therapeutic drug monitoring practices. We conclude that aminoglycoside antibiotics remain an effective and economical form of therapy for severe infections and that if careful criteria are used in the selection of these agents, the benefits of therapy outweigh the risk of toxicity.

Suboptimal effect of daptomycin in the treatment of bacteremias

We have reported two cases involving bacteremic patients who failed to respond adequately to the investigational agent daptomycin. Despite apparent sensitivity of the organisms, therapy was unsuccessful in both patients using the recommended dosage. The sponsor of daptomycin is currently reevaluating the recommendation and may be revising their dosage guidelines in the future.

Clinical assessment of a published model to predict aminoglycoside-induced nephrotoxicity

During the past decade, several patient risk factors have been identified as contributing to the development of aminoglycoside nephrotoxicity. Sawyers et al. recently published a method for estimating the probability of aminoglycoside nephrotoxicity on an individual patient basis. The present work represents a refinement of previous publications and has not been tested with the common variations used in aminoglycoside dosing. The purpose of this study was to determine both the qualitative and quantitative value of this method in predicting aminoglycoside induced nephrotoxicity. Eighty-three patients (47 male, 36 female) meeting the inclusion criteria of Sawyers et al. were entered into the study. Patient risk factors (age, sex, initial 1-h postinfusion aminoglycoside serum level, initial calculated creatinine clearance, duration of therapy, and presence of liver disease) were entered into a logistic regression analysis to determine the individual patients risk of developing nephrotoxicity. These calculated probability scores were then compared with the observed nephrotoxicity in specific groups within our patient sample to see how effectively the model quantitatively performed. Twelve patients (14.5%) developed nephrotoxicity. The model predicted only 5 of the 12 patients developing nephrotoxicity (sensitivity or true positive = 42%). In the nonnephrotoxic group, the model accurately predicted only 38 of 71 patients (specificity or true negative = 54%). These data suggest that the model may accurately quantitate the number of patients likely to develop nephrotoxicity from a specific group but is unable to discriminate specific patients at risk of developing aminoglycoside-induced nephrotoxicity.

Influence of pH on the antimicrobial activity of clarithromycin and 14-hydroxyclarithromycin against Haemophilus influenzae using an in vitro pharmacodynamic model

Clarithromycin activity can be influenced by the pH of the surrounding environment. Evidence supports a reduced pH of middle ear fluid (MEF) and lung tissues in patients with otitis media and pneumonia, respectively. To evaluate the influence of pH on clarithromycin activity, an in vitro pharmacodynamic chamber model (PDCM) was used to generate bacterial time-kill curves for clarithromycin and a 2:1 ratio of clarithromycin and 14-hydroxyclarithromycin (HC) against Haemophilus influenzae at three different pH values: 7.2, 6.8, 6.4. Concentrations observed in MEF and lung tissues were simulated for clarithromycin alone and clarithromycin plus HC. Differences in activity at each pH were identified by comparing initial kill curve slopes and total log reduction. Experiments with amoxicillin-clavulanate were conducted as a reference. In simulated MEF regimens at pH 7.2, activity of clarithromycin alone improved by adding HC (additional 2 log10 reduction at 8 h); however, at pH values of 6.8 and 6.4, kill curves resembled growth controls. In simulated lung regimens, differences between clarithromycin alone and clarithromycin plus HC were insignificant; both produced a 2 log10 reduction at pH 7.2, and activity dramatically dropped to < 0.4 log10 as pH declined. In contrast, amoxicillin-clavulanate consistently produced a 3 log10 reduction over each pH value with more rapid initial kill relative to all clarithromycin regimens. These findings suggest the activity of clarithromycin against H. influenzae may be significantly compromised in respiratory tract infections involving a reduced pH. Trials with emphasis on clinical outcomes analysis will assist further in determining the significance of these experimental findings.

Therapeutic Update on Glycopeptide and Lipopeptide Antibiotics

Glycopeptide antibiotics in the form of vancomycin have been available for almost 30 years. In the past, vancomycin usually was reserved as an alternative agent to treat staphylococcal and streptococcal infection in patients with a penicillin allergy or hemodialysis shunt infection. With the increasing frequency of both methicillin‐resistant Staphylococcus aureus and Staphylococcus epidermidis, now it is often used as a first‐line agent. Over a 10‐year period, vancomycin sales have increased by almost