Practice guidelines for therapeutic monitoring of vancomycin treatment for Staphylococcus aureus infection in adult patients were reviewed by an expert panel of the Infectious Diseases Society of America, the American Society of Health-System Pharmacists, and the Society of Infectious Diseases Pharmacists. A literature review of existing evidence regarding vancomycin dosing and monitoring of serum concentrations, in addition to patient outcomes combined with expert opinion regarding the drug's pharmacokinetic, pharmacodynamic, and safety record, resulted in new recommendations for targeting and adjustment of vancomycin therapy.
Recent clinical data on vancomycin pharmacokinetics and pharmacodynamics suggest a reevaluation of current dosing and monitoring recommendations. The previous 2009 vancomycin consensus guidelines recommend trough monitoring as a surrogate marker for the target area under the curve over 24 hours to minimum inhibitory concentration (AUC/MIC). However, recent data suggest that trough monitoring is associated with higher nephrotoxicity. This document is an executive summary of the new vancomycin consensus guidelines for vancomycin dosing and monitoring. It was developed by the American Society of Health-System Pharmacists, the Infectious Diseases Society of America, the Pediatric Infectious Diseases Society, and the Society of Infectious Diseases Pharmacists vancomycin consensus guidelines committee. These consensus guidelines recommend an AUC/MIC ratio of 400–600 mg*hour/L (assuming a broth microdilution MIC of 1 mg/L) to achieve clinical efficacy and ensure safety for patients being treated for serious methicillin-resistant Staphylococcus aureus infections.
Pharmacodynamics provides a rational basis for optimizing dosing regimens by describing the relationship between drug, host and antimicrobial effect. The successful identification of meaningful pharmacodynamic outcome parameters can, therefore, greatly assist clinicians in making objective prescribing decisions rather than relying on static in vitro MIC data. While pharmacodynamic outcome parameters have been proposed for select antimicrobial agents, their clinical application remains to be defined fully. Quinolone antibiotics are generally considered to have concentration-dependent bactericidal activity and peak/MIC and AUC/MIC ratios have been identified as possible pharmacodynamic predictors of clinical and microbiological outcome as well as the development of bacterial resistance. Investigators have suggested that AUC/MIC ratios of 100-125 or peak/MIC ratios of >10 are required to predict clinical and microbiological success and to limit the development of bacterial resistance. These conclusions are derived primarily from studies of Gram-negative bacteria, and recent data suggest that these ratios may not be applicable for Streptococcus pneumoniae, where an AUC/MIC ratio of <40 appears to be a more accurate predictor. There is considerable variation in pharmacodynamic calculations and outcome parameters appear to be quinolone- and pathogen-specific. Additional prospective clinical research is needed to characterize quinolone pharmacodynamic parameters and answer unresolved questions regarding optimal pharmacodynamic outcome predictors for Gram-positive bacteria, anaerobes and atypical respiratory pathogens.
The bulk of the evidence supports the concept that, in treating endocarditis and meningitis, it is important to use antibacterial agents with in vitro bactericidal activity. This conclusion is based on both human and animal data. The data to support bactericidal drugs' superiority to bacteriostatic drugs do not exist for most other clinical situations, and animal models do not support this concept in some situations. Clinicians should be aware that drugs that are bacteriostatic for one organism may in fact be bactericidal for another organism or another strain of the same organism.
Compared with nalidixic acid, ciprofloxacin is representative of a newer, more potent class of quinolones, termed the fluoroquinolones. It is available in both oral and parenteral dosage forms. The primary target of quinolone activity appears to be the bacterial DNA gyrase enzyme, which is a member of the class of type II topoisomerases. Bacterial do not acquire resistance to fluoroquinolones through mechanisms that are plasmid or R-factor mediated and, additionally, the quinolones do not appear to be vulnerable to degradation by bacterial inactivating mechanisms. Rather, bacterial resistance to ciprofloxacin occurs either through chromosomal mutation in the target enzyme DNA gyrase or through mutations that alter drug permeability into the bacterial cell. Ciprofloxacin and the fluoroquinolones in general are no more likely to select resistant mutant than are aminoglycosides or beta-lactam antibiotics. Ciprofloxacin displays in vitro activity against most Gram-negative and many Gram-positive pathogenic bacteria, many of which are resistant to a wide range of antibiotics. This finding is of considerable potential clinical significance. High pressure liquid chromatography (HPLC) and microbiological agar diffusion assays have been routinely used to quantify ciprofloxacin concentrations in biological fluids. Both methods are reproducible and accurate for serum but HPLC is recommended for other specimens because of the presence of microbiologically active metabolites. Absorption after oral administration is rapid and can be satisfactorily described as a zero-order process; peak serum ciprofloxacin concentrations (Cmax) are reached in approximately 1 to 2 hours. Concomitant administration of food does not cause clinically significant impairment of absorption and may be helpful in minimising gastric distress caused by the drug. A linear relationship between serum ciprofloxacin concentrations and the dose administered either orally or intravenously has been reported. The absolute bioavailability of ciprofloxacin is approximately 70%. The volume of distribution is large with a steady-state range after oral or intravenous dosing of 1.74 to 5.0 L/kg reflecting penetration of the drug into most tissues. Nonrenal clearance accounts for approximately 33% of the elimination of ciprofloxacin; to date, 4 metabolites have been identified. A first-pass effect has been reported but is thought to be clinically unimportant. Faecal recovery of ciprofloxacin accounts for approximately 15% of an intravenous dose. Nonrenal elimination includes metabolic degradation, biliary excretion and transluminal secretion across the enteric mucosa. Glomerular filtration and tubular secretion account for approximately 66% of the total serum clearance. The terminal disposition half-life (t1/2) is about 3 to 4 hours.(ABSTRACT TRUNCATED AT 400 WORDS)
Vancomycin is a commonly used antibiotic due to its effectiveness in treating serious gram-positive infections caused by methicillin-resistant Staphylococcus aureus. As commercial drug assays and a multitude of pharmacokinetic data from a variety of patient populations are widely available, therapeutic monitoring of serum vancomycin concentrations is frequently performed by clinicians, with the expectation that targeting the concentrations within a relatively narrow range can minimize toxicity yet still achieve therapeutic success. Much debate exists, however, over the value of routine therapeutic monitoring of vancomycin levels because of conflicting evidence regarding the ability of serum concentrations to predict effectiveness or prevent toxicity. In addition, studies have suggested that the potential for nephrotoxicity or ototoxicity with vancomycin monotherapy is minimal at conventional dosages of 1 g (15 mg/kg) every 12 hours. However, increased rates of nephrotoxicity have recently been reported with doses of 4 g/day or higher. The American Society of Health-System Pharmacists, the Infectious Diseases Society of America, and the Society of Infectious Diseases Pharmacists published a consensus statement on therapeutic monitoring of serum vancomycin levels in adults. These organizations established an expert panel to review the scientific data and controversies associated with vancomycin monitoring and to make recommendations based on the available evidence. As the members of this panel, we summarize the conclusions and highlight the recommendations from the consensus statement. We determined that the area under the concentration-time curve (AUC): minimum inhibitory concentration (MIC) ratio is the most useful pharmacodynamic parameter to predict vancomycin effectiveness and suggested a target ratio of 400 or greater to eradicate S. aureus. In addition, trough serum concentration monitoring is the most accurate and practical method to monitor vancomycin serum levels. Increasing trough concentrations to 15-20 mg/L to attain the target AUC:MIC ratio may be desirable but is currently not supported by clinical trials. Alternative therapies should be considered in patients with S. aureus infections that demonstrate a vancomycin MIC of 2 mg/L or greater because the target AUC:MIC ratio ( 400) is unlikely to be achieved in this setting. Increasing the dosage to result in higher trough concentrations may increase the potential for toxicity; however additional clinical experience is required to determine the extent.
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