The limited treatment options available for carbapenemase-producing Klebsiella pneumoniae (KPC) have made it a formidable pathogen. Previously we have shown the enhanced activity of pharmacodynamically optimized doripenem against KPC. Capitalizing on KPC's increased affinity for ertapenem, we evaluated the efficacy of a combination of ertapenem and doripenem in both an in vitro chemostat and an in vivo murine thigh infection model. Overall, the combination of doripenem plus ertapenem demonstrated enhanced efficacy over either agent alone.
dWe recently investigated the pharmacokinetics-pharmacodynamics (PK-PD) of tazobactam in combination with ceftolozane against an isogenic CTX-M-15-producing Escherichia coli triplet set, genetically engineered to transcribe different levels of bla CTX-M-15 . The percentage of the dosing interval that tazobactam concentrations remained above a threshold (%Time>threshold) was identified as the PK-PD exposure measure that was most closely associated with efficacy. Moreover, the tazobactam concentration was dependent upon the enzyme transcription level. Given that the aforementioned strains were genetically engineered to transcribe a single -lactamase enzyme and that clinical isolates typically produce multiple -lactamase enzymes with various transcription levels, it is likely that the tazobactam threshold concentration is isolate/enzyme dependent. Our first objective was to characterize the relationship between the tazobactam %Time>threshold in combination with ceftolozane and efficacy using clinical isolates in an in vitro PK-PD infection model. Our second objective was to identify a translational relationship that would allow for the comodeling across clinical isolates. The initial challenge panel included four well-characterized -lactamase-producing E. coli strains with variable enzyme expression and other resistance determinants. As evidenced by r 2 values of ranging from 0.90 to 0.99 for each clinical isolate, the observed data were well described by fitted functions describing the relationship between the tazobactam %Time>threshold and change in log 10 CFU from baseline; however, the data from the four isolates did not comodel well. The threshold concentration identified for each isolate ranged from 0.5 to 4 mg/liter. We identified an enabling translational relationship for the tazobactam threshold that allowed comodeling of all four clinical isolates, which was the product of the individual isolate's ceftolozane-tazobactam MIC value and 0.5. As evidenced by an r 2 value of 0.90, the transformed data were well described by a fitted function describing the relationship between tazobactam %Time>threshold and change in log 10 CFU from baseline. Due to these findings, the challenge panel was expanded to include three well-characterized -lactamase-producing Klebsiella pneumoniae strains with variable enzyme expression and other resistance determinants. The translational relationship for the tazobactam threshold that allowed for the comodeling of the four E. coli isolates performed well for the expanded data set (seven isolates in total; four E. coli and three K. pneumoniae), as evidenced by an r 2 value of 0.84. This simple translational relationship is especially useful as it is directly linked to in vitro susceptibility test results, which are used to guide the clinician's choice of drug and dosing regimen.
We have previously demonstrated that a high-dose, prolonged-infusion meropenem regimen (2 g every 8 h [q8h]; 3-hour infusion) can achieve 40% free drug concentration above the MIC against Pseudomonas aeruginosa with MICs of <16 g/ml. The objective of this experiment was to compare the efficacy of this high-dose, prolonged-infusion regimen against carbapenemase-producing Klebsiella pneumoniae isolates with the efficacy against P. aeruginosa isolates having similar meropenem MICs. An in vitro pharmacodynamic model was used to simulate human serum concentrations. Eleven genotypically confirmed K. pneumoniae carbapenemase (KPC)-producing isolates and six clinical P. aeruginosa isolates were tested for 24 h, and time-kill curves were constructed. High-performance liquid chromatography (HPLC) was used to verify meropenem concentrations in each experiment. Meropenem achieved a rapid >3 log CFU reduction against all KPC isolates within 6 h, followed by regrowth in all but two isolates. The targeted %fT>MIC (percent time that free drug concentrations remain above the MIC) exposure was achieved against both of these KPC isolates (100% fT>MIC versus MIC ؍ 2 g/ml, 75% fT>MIC versus MIC ؍ 8 g/ml). Against KPC isolates with MICs of 8 and 16 g/ml that did regrow, actual meropenem exposures were significantly lower than targeted due to rapid in vitro hydrolysis, whereby targeted %fT>MIC was reduced with each subsequent dosing. In contrast, a >3 log CFU reduction was maintained over 24 h for all Pseudomonas isolates with meropenem MICs of 8 and 16 g/ml. Although KPC and P. aeruginosa isolates may share similar meropenem MICs, the differing resistance mechanisms produce discordant responses to a high-dose, prolonged infusion of meropenem. Thus, predicting the efficacy of an antimicrobial regimen based on MIC may not be a valid assumption for KPC-producing organisms.
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