In vitro pharmacodynamic evaluation of ceftolozane/tazobactam against ß-lactamase-producing Escherichia coli in a hollow-fibre infection model.

The proliferation of multidrug-resistant Gram-negative pathogens has been exacerbated by a lack of novel agents in current development by pharmaceutical companies. Ceftolozane/tazobactam was recently approved by the FDA for the treatment of complicated intra-abdominal infections and complicated urinary tract infections. In the present study, the activity of ceftolozane/tazobactam against four isogenic Escherichia coli strains was investigated in a hollow-fibre infection model simulating various clinical dosing regimens. The four investigational E. coli strains included #2805 (no ß-lactamase), #2890 (AmpC ß-lactamase), #2842 (CMY-10 ß-lactamase) and #2807 (CTX-M-15 ß-lactamase). Each strain was exposed to regimens simulating 1 g ceftolozane, 2 g ceftolozane, 1 g ceftolozane/0.5 g tazobactam, and 2 g ceftolozane/1 g tazobactam utilising a starting inoculum of ca. 106 CFU/mL. Whereas 1 g of ceftolozane eradicated strains #2805 and #2842 without subsequent regrowth, 1 g ceftolozane/0.5 g tazobactam was required to eradicate strain #2890. For strain #2890, ceftolozane monotherapy led to bacterial growth on plates impregnated with 20 mg/L ceftolozane by 24 h, whilst combination treatment with tazobactam completely suppressed the development of ceftolozane resistance. In contrast, none of the regimens, including 2 g ceftolozane/1 g tazobactam, were able to entirely suppress bacterial growth in strain #2807, with bacterial counts exceeding 108 CFU/mL by 48 h and ceftolozane-resistant populations being amplified after 24 h. Thus, the combination of ceftolozane and tazobactam achieved bactericidal activity followed by sustained killing over 10 days for three of four isogenic E. coli strains. Ceftolozane/tazobactam is a promising new agent to counter multidrug-resistant Gram-negative bacteria.

Combinatorial Pharmacodynamics of Ceftolozane-Tazobactam against Genotypically Defined ß-Lactamase-Producing Escherichia coli: Insights into the Pharmacokinetics/Pharmacodynamics of ß-Lactam-ß-Lactamase Inhibitor Combinations.

Despite a dearth of new agents currently being developed to combat multidrug-resistant Gram-negative pathogens, the combination of ceftolozane and tazobactam was recently approved by the Food and Drug Administration to treat complicated intra-abdominal and urinary tract infections. To characterize the activity of the combination product, time-kill studies were conducted against 4 strains ofEscherichia colithat differed in the type of ß-lactamase they expressed. The four investigational strains included 2805 (no ß-lactamase), 2890 (AmpC ß-lactamase), 2842 (CMY-10 ß-lactamase), and 2807 (CTX-M-15 ß-lactamase), with MICs to ceftolozane of 0.25, 4, 8, and >128 mg/liter with no tazobactam, and MICs of 0.25, 1, 4, and 8 mg/liter with 4 mg/liter tazobactam, respectively. All four strains were exposed to a 6 by 5 array of ceftolozane (0, 1, 4, 16, 64, and 256 mg/liter) and tazobactam (0, 1, 4, 16, and 64 mg/liter) over 48 h using starting inocula of 10(6)and 10(8)CFU/ml. While ceftolozane-tazobactam achieved bactericidal activity against all 4 strains, the concentrations of ceftolozane and tazobactam required for a ≥3-log reduction varied between the two starting inocula and the 4 strains. At both inocula, the Hill plots (R(2)> 0.882) of ceftolozane revealed significantly higher 50% effective concentrations (EC50s) at tazobactam concentrations of ≤4 mg/liter than those at concentrations of ≥16 mg/liter (P< 0.01). Moreover, the EC50s at 10(8)CFU/ml were 2.81 to 66.5 times greater than the EC50s at 10(6)CFU/ml (median, 10.7-fold increase;P= 0.002). These promising results indicate that ceftolozane-tazobactam achieves bactericidal activity against a wide range of ß-lactamase-producingE. colistrains.

New dosing strategies for an old antibiotic: pharmacodynamics of front-loaded regimens of colistin at simulated pharmacokinetics in patients with kidney or liver disease.

Increasing evidence suggests that colistin monotherapy is suboptimal at currently recommended doses. We hypothesized that front-loading provides an improved dosing strategy for polymyxin antibiotics to maximize killing and minimize total exposure. Here, we utilized an in vitro pharmacodynamic model to examine the impact of front-loaded colistin regimens against a high bacterial density (10(8) CFU/ml) of Pseudomonas aeruginosa. The pharmacokinetics were simulated for patients with hepatic (half-life [t1/2] of 3.2 h) or renal (t1/2 of 14.8 h) disease. Front-loaded regimens (n=5) demonstrated improvement in bacterial killing, with reduced overall free drug areas under the concentration-time curve (fAUC) compared to those with traditional dosing regimens (n=14) with various dosing frequencies (every 12 h [q12h] and q24h). In the renal failure simulations, front-loaded regimens at lower exposures (fAUC of 143 mg · h/liter) obtained killing activity similar to that of traditional regimens (fAUC of 268 mg · h/liter), with an ∼97% reduction in the area under the viable count curve over 48 h. In hepatic failure simulations, front-loaded regimens yielded rapid initial killing by up to 7 log10 within 2 h, but considerable regrowth occurred for both front-loaded and traditional regimens. No regimen eradicated the high bacterial inoculum of P. aeruginosa. The current study, which utilizes an in vitro pharmacodynamic infection model, demonstrates the potential benefits of front-loading strategies for polymyxins simulating differential pharmacokinetics in patients with hepatic and renal failure at a range of doses. Our findings may have important clinical implications, as front-loading polymyxins as a part of a combination regimen may be a viable strategy for aggressive treatment of high-bacterial-burden infections.

Pharmacodynamics of early, high-dose linezolid against vancomycin-resistant enterococci with elevated MICs and pre-existing genetic mutations.

OBJECTIVES: Vancomycin-resistant enterococci (VRE) have emerged as an important nosocomial pathogen in medical centres worldwide. This study evaluated the impact of front-loading of linezolid on bacterial killing and suppression of resistance against VRE strains with defined genetic mutations. METHODS: Time-killing experiments over 48 h assessed the concentration effect relationship of linezolid against eight strains of vancomycin-resistant Enterococcus faecalis. A hollow fibre infection model (HFIM) simulated traditional and front-loaded human therapeutic linezolid regimens against VRE strains at 10(6) cfu/mL over 240 h. Translational modelling was performed using S-ADAPT and NONMEM. RESULTS: Over 48 h in time-kill experiments, linezolid displayed bacteriostatic activity with >2 log(10) cfu/mL killing for all strains with an MIC of 4 and minimal activity against VRE with MICs of 16 and 64 mg/L. Against one strain with no resistant alleles (MIC 4 mg/L), 600 mg of linezolid every 12 h achieved maximal reductions of 0.96 log(10) cfu/mL over 240 h in the HFIM, whereas front-loaded 1200 mg of linezolid every 12 h ×10 doses or 2400 mg of linezolid every 12 h ×10 doses followed by 600 mg of linezolid every 12 h provided significantly improved killing with maximal reductions of 3.02 and 3.46 log(10) cfu/mL. Front-loaded regimens suppressed amplification of resistant subpopulations against VRE strains with no resistant alleles (MIC 4 mg/L) and postponed regrowth of resistant subpopulations against a VRE with 3.2 resistant alleles (MIC 4 mg/L). Modelling yielded excellent population fits (r = 0.934) and identified the number of sensitive alleles as a critical covariate. CONCLUSIONS: Early, high-dose regimens of linezolid provided promising killing against selected susceptible strains and may be clinically beneficial if early bactericidal activity is necessary.

Front-loaded linezolid regimens result in increased killing and suppression of the accessory gene regulator system of Staphylococcus aureus.

Front loading is a strategy used to optimize the pharmacodynamic profile of an antibiotic through the administration of high doses early in therapy for a short duration. Our aims were to evaluate the impact of front loading of linezolid regimens on bacterial killing and suppression of resistance and on RNAIII, the effector molecule of the accessory gene regulator system (encoded by agr) in methicillin-resistant Staphylococcus aureus (MRSA). Time-killing experiments over 48 h were utilized for linezolid against four strains of MRSA: USA100, USA300, USA400, and ATCC 29213. A hollow-fiber infection model simulated traditional and front-loaded human therapeutic regimens of linezolid versus USA300 at 10(6) CFU/ml over 240 h. Over 48 h in time-kill experiments, linezolid displayed bacteriostatic activity, with reductions of >1 log(10) CFU/ml for all strains. Front-loaded regimens that were administered over 5 days, 1,200 mg every 12 h (q12h) (total, 10 doses) and 2,400 mg q12h (total, 10 doses) followed by 300 mg q12h thereafter, resulted in sustained bactericidal activity, with reductions of the area under the CFU curve of -6.15 and -6.03, respectively, reaching undetectable limits at the 10-day study endpoint. All regimens displayed a reduction in RNAIII relative expression at 24 h and 240 h compared with that of the growth control. Monte Carlo simulations predicted a <1.27× increase in the fractional decreases in platelets for all front-loaded regimens versus the 600 mg q12h regimen, except for the highest-dose front-loaded regimen. Front-loading strategies for linezolid are promising and may be of utility in severe MRSA infections, where early aggressive therapy is necessary.

In vitro pharmacodynamics of novel rifamycin ABI-0043 against Staphylococcus aureus.

OBJECTIVES: ABI-0043 is a novel benzoxazinorifamycin derivative, which derives its potent bactericidal activity by the specific inhibition of bacterial RNA polymerase. We evaluated the in vitro pharmacodynamics and bactericidal activity of ABI-0043 against clinical isolates of methicillin-resistant Staphylococcus aureus (MRSA) and methicillin-susceptible S. aureus (MSSA). METHODS: Using time-kill studies at a wide range of concentrations of ABI-0043, we evaluated the killing activity against four clinical isolates of S. aureus over 24 h. An integrated pharmacokinetic/pharmacodynamic area measure was applied to all cfu data and was fitted to a Hill-type mathematical model to evaluate pharmacodynamics. RESULTS: Bacterial killing for ABI-0043 occurred rapidly and in a concentration-dependent manner. Bactericidal activity was achieved within 4 h at > or =16 x MIC against all isolates. Bacterial reductions were greatest at > or =64 x MIC against MRSA and MSSA isolates, as a >4 log(10) cfu/mL reduction was observed as early as 2 h, and sustained throughout 24 h. The pharmacodynamics of ABI-0043 was well described by a Hill-type model, with a steep sigmoidicity constant and a low EC(50) against all isolates. CONCLUSIONS: ABI-0043 displayed rapid and sustained bactericidal activity against S. aureus clinical isolates. ABI-0043 represents a promising antistaphylococcal agent to combat serious S. aureus infections. Further, pharmacokinetic, pharmacodynamic and in vivo studies are warranted to determine its ultimate place in antibacterial therapy.

Attenuated vancomycin bactericidal activity against Staphylococcus aureus hemB mutants expressing the small-colony-variant phenotype.

The in vitro bactericidal activities of vancomycin against Staphylococcus aureus hemB mutants displaying the small-colony-variant phenotype and their parental strains were evaluated. Vancomycin killing activities against hemB mutants were markedly attenuated, demonstrating approximately 50% less effect, a result which was well described by a Hill-type pharmacodynamic model.

Pharmacodynamics of cefprozil against Haemophilus influenzae in an in vitro pharmacodynamic model.

An in vitro pharmacodynamic model was used to determine the pharmacokinetic-pharmacodynamic (PK-PD) measure and magnitude most strongly related to cefprozil activity against Haemophilus influenzae. Using 3 clinical isolates of H. influenzae, a series of dose-fractionation studies were conducted, simulating cefprozil pediatric pharmacokinetics. The studies were designed to deliver a range of free cefprozil AUC(24) given once daily, twice daily, and by continuous infusion (CI). Drug effect, characterized by computing the log(10) ratio of the area under the 24-h bacterial colony-forming unit (CFU) (AUC(CFU)) curve to drug-free control, was fit to a Hill-type model for 3 PK-PD measures of activity: AUC(24)/MIC, C(max)/MIC, and %T > MIC. Once daily regimens provided much less activity than twice daily or CI regimens. AUC(24)/MIC and %T > MIC characterized the data well, whereas C(max)/MIC did not. Based on the PK-PD model results, for cefprozil twice daily, 50% and 80% of maximum drug effect (E(max)) was achieved at a %T > MIC of approximately 52% and 75%, respectively. A 2-log(10) reduction in log(10) ratio would require free drug %T > MIC of 58% or AUC(24)/MIC of 86. Bacteriostasis was achieved at a %T > MIC and an AUC(24)/MIC of approximately 25% and 30%, respectively. An in vitro pharmacodynamic model was able to characterize the PK-PD of cefprozil against H. influenzae. Consistent with limited clinical data, a minimum %T > MIC of 40% to 50% would be suggested to achieve in vivo activity in otitis media, with maximal activity at approximately 70%T > MIC.

Application of an in vitro infection model and simulation for reevaluation of fluoroquinolone breakpoints for Salmonella enterica serotype typhi.

Salmonella enterica serotype Typhi and nontyphoidal Salmonella remain major causes of morbidity and mortality worldwide. Ampicillin, trimethoprim-sulfamethoxazole, and chloramphenicol no longer provide reliable coverage of Salmonella, and fluoroquinoloes have emerged as first-line treatment options. Due to mounting evidence of decreased in vitro susceptibility and diminished clinical response to fluoroquinolone therapy, it has been suggested that the NCCLS breakpoints for the salmonellae be reevaluated. We utilized an in vitro infection model to determine which pharmacokinetic-pharmacodynamic (PK-PD) measure was most closely linked to fluoroquinolone activity against salmonellae and the magnitude that was predictive of efficacy. Monte Carlo simulation was utilized to determine the probability of attaining potential susceptibility breakpoints for three fluoroquinolones. The free-drug area under the concentration-time curve from 0 to 24 h/MIC ratio was the PK-PD measure most predictive of efficacy, and a ratio of 105 corresponded to 90% of maximal activity. Simulation results suggested susceptible breakpoints of 0.12 microg/ml for ciprofloxacin and gatifloxacin and 0.25 microg/ml for levofloxacin. These proposed breakpoints correspond to the MIC separating the wild-type susceptible organism population from those strains possessing single-step mutations in the quinolone resistance-determining region. These results that integrate PK-PD measures and fluoroquinolone MIC distributions in the genetic context of examined Salmonella isolates clearly demonstrate that the prudent use of a lower susceptibility breakpoint minimizes the probability of clinical failure or delayed response in fluoroquinolone-treated patients.