In Vivo Pharmacodynamics of ß-Lactams/Nacubactam against Carbapenem-Resistant and/or Carbapenemase-Producing Enterobacter cloacae and Klebsiella pneumoniae in Murine Pneumonia Model.

Carbapenem-resistant Enterobacterales (CRE) and carbapenemase-producing Enterobacterales (CPE) have become global threats. CRE- and CPE- derived infections have been associated with high mortality due to limited treatment options. Nacubactam is a ß-lactamase inhibitor and belongs to the new class of diazabicyclooctane. The agent has an in vitro antimicrobial activity against several classes of ß-lactamase-producing Enterobacterales. This study evaluated antimicrobial activity of combination therapies including ß-lactams (aztreonam, cefepime, and meropenem) and nacubactam against four Enterobacter cloacae and six Klebsiella pneumoniae isolates with murine pneumonia model. Based on changes in bacterial quantity, antimicrobial activities of some regimens were assessed. Combination therapies including ß-lactams (aztreonam, cefepime, and meropenem) with nacubactam showed enhanced antimicrobial activity against CRE E. cloacae (-3.70 to -2.08 Δlog10 CFU/lungs) and K. pneumoniae (-4.24 to 1.47 Δlog10 CFU/lungs) with IMP-1, IMP-6, or KPC genes, compared with aztreonam, cefepime, meropenem, and nacubactam monotherapies. Most combination therapies showed bacteriostatic (-3.0 to 0 Δlog10 CFU/lungs) to bactericidal (<-3.0 Δlog10 CFU/lungs) activities against CRE isolates. This study revealed that combination regimens with ß-lactams (aztreonam, cefepime, and meropenem) and nacubactam are preferable candidates to treat pneumonia due to CRE and CPE.

Pharmacodynamic evaluation of meropenem, cefepime, or aztreonam combined with a novel ß-lactamase inhibitor, nacubactam, against carbapenem-resistant and/or carbapenemase-producing Klebsiella pneumoniae and Escherichia coli using a murine thigh-infection model.

BACKGROUND: Carbapenem-resistant Enterobacterales (CRE) and carbapenemase-producing Enterobacterales (CPE) are difficult to treat and are a serious public health threat. Nacubactam (NAC) is a novel non-ß-lactam diazabicyclooctane ß-lactamase inhibitor with in vitro activity against some Enterobacterales expressing classes of ß-lactamases. METHODS: The antimicrobial efficacy of meropenem (MEM), cefepime (FEP), and aztreonam (ATM), each in combination with NAC, were assessed in vitro and in vivo against Klebsiella pneumoniae and Escherichia coli. Ten isolates, including CRE and/or CPE with ß-lactamase genes, were used in this study. The relationship between phenotype and in vivo efficacy was assessed in a murine neutropenic thigh-infection model. Efficacy was determined by the change in bacterial quantity. RESULTS: The results of the in vitro study showed the minimum inhibitory concentrations of the combination of NAC with either MEM, FEP, or ATM in a 1:1 ratio were 2 to >128-fold lower than those of MEM, FEP, or ATM alone against CRE+ isolates. In addition, combinations of ß-lactams and NAC administered in the murine thigh-infection model showed greater efficacy against CRE+/CPE+, CRE+/CPE-, and CRE-/CPE+ isolates harboring various ß-lactamase genes (IMP-1, IMP-6, KPC, DHA-1, or OXA-48) compared with MEM, FEP, ATM, and NAC alone. CONCLUSION: MEM, FEP, or ATM in combination with NAC showed potent in vivo antimicrobial activity in a murine thigh-infection model caused by K. pneumoniae and E. coli, including CRE and/or CPE isolates. These findings indicate that these combinations of ß-lactams and NAC are potential candidates for the treatment of CRE and/or CPE infections.

Investigations on yearly changes in tebipenem susceptibility of bacterial isolates from pediatric patients -A post-marketing surveillance of tebipenem pivoxil granules for pediatric.

We conducted the post-marketing surveillance of tebipenem pivoxil (Orapeneme fine granules 10% for pediatric), an oral carbapenem antibacterial agent, to investigate changes in bacterial susceptibility against tebipenem (TBPM). Bacterial strains used in this surveillance were methicillin-susceptible Staphylococcus aureus (MSSA: 303 strains), Streptococcus pneumoniae (554 strains), other Streptococcus spp. (242 strains: including Streptococcus pyogenes 133 strains), Moraxella catarrhalis (306 strains) and Haemophilus influenzae (506 strains) isolated from pediatric patients in 15 medical facilities in Japan between April 2010 and March 2015. Investigation was conducted three times (April 2010-March 2011, April 2012-March 2013 and April 2014-March 2015), and in any of these investigation periods, there were a large number of isolates from infants in terms of the frequency of isolates by age. The MIC90s of TBPM against MSSA, S. pneumoniae, other Streptococcus spp., M. catarrhalis and H. influenzae in these investigations were 0.015-0.03, 0.06, 0.008-0.015 (0.002 for S. pyogenes), 0.03 and 0.5-1 µg/mL, respectively, which were less than 2-fold, and a remarkable increase in MIC90 was not shown. On the other hand, the MIC50s of carbapenems including TBPM and penicillins against S. pneumoniae decreased to 1/4-1/8 during the investigation periods, and decreased gPRSP*¹ (48.7% - 26.1%) and increased gPISP (2x)*² (24.1% -+ 46.8%) were suggested to be involved in these changes in susceptibility. In S. pneumoniae, a decrease of macrolides-resistant strains due to mefA*³ (38.5% - 18.8%) and an increase of macrolides-resistant strains due to ermB*4 (41.7% - 62.4%) were noted. In H. influenzae, the frequencies of gBLNAR*5 and ß-lactamase-producing strains were about 60-70% and 7-9%, respectively, and a remarkable change in susceptibility was not shown. As a result of investigations in the susceptibility of clinical isolates collected from pediatric patients as post-marketing surveillance, there was no decrease in TBPM susceptibility noted.

Prediction of clinical bacteriological efficacy of oral antibiotics using a mechanism-based pharmacokinetic-pharmacodynamics modeling.

The objective of this study was to predict the clinical bacteriological efficacy of antibiotics and to examine the pharmacodynamics (PD) characteristics of antibiotics against bacterial strains using a mechanism-based pharmacokinetic-pharmacodynamics (PK-PD) modeling developed on the basis of interaction between drug concentrations and antibacterial activities. Dynamic PD parameters (epsilon, gamma, EC50) and growth rate of organisms (lambda) were obtained from in vitro time-kill profile data of oral antibiotics, tebipenem pivoxil (TBPM-PI) and cefditoren pivoxil (CDTR-PI) against Streptococcus pneumoniae or Haemophilus influenzae. PD characteristics of both drugs against S. pneumoniae or H. influenzae were examined, which indicated TBPM was concentration-dependent as well as time-dependent, and CDTR was mainly time-dependent to exhibit their bactericidal activities. Next, we simulated TBPM and CDTR concentrations in plasma after oral administration according to the dosage regimen of each drug specified in package insert, using population pharmacokinetic parameters of both drugs in pediatric patients with infections. In addition, changes in viable in vivo bacterial counts in humans were simulated using dynamic PD parameters and mean plasma concentrations of each drug. As a result, simulated profile of viable counts of S. pneumoniae and H. influenzae were well corresponding to the bacteriological efficacy results in clinical double-blinded comparative study of TBPM-PI and CDTR-PI in oral administration to pediatric patients with acute otitis media. As mentioned in the above, it was considered to be possible to clarify the PD characteristics of TBPM and CDTR against each bacterial strain using the mechanism-based PK-PD model developed on the basis of interaction between drug concentrations and antibacterial activities, and to estimate the clinical bacteriological efficacy of those drugs.

New concept and a theoretical consideration of the mechanism-based pharmacokinetics/ pharmacodynamics (PK/PD) modeling for antimicrobial agents.

Pharmacodynamic (PD) characterization (concentration-dependent, time-dependent, etc.) of antibiotics is determined by aspects of the pharmacodynamic interaction between antibiotics and microorganisms. There are three major aspects of the pharmacodynamic interaction between antibiotics and microorganisms; 1) the minimum drug concentration required for the exhibition of antibacterial activity (MIC: minimum inhibitory concentration, MBC: minimum bactericidal concentration, etc.), 2) the relationship between drug concentration and bactericidal activity and 3) the magnitude of any persistent antibiotic activity (sub-MIC effect, post antibiotic effect, etc.). In the PK/PD approach based on the MIC (static MIC approach), information concerning aspect 1) alone is treated as the quantitative PD parameter (MIC), while information concerning aspects 2) and 3) are not represented as quantified PD parameters in spite of their importance in in vivo pharmacodynamic situation. On the other hand, in the PK/PD approach based on the time-kill profile (dynamic PK/PD approach), information concerning aspects 1) - 3) can all be represented as quantitative dynamic PD parameters (epsilon; the maximum kill rate constant, gamma; the Hill coefficient and EC50; the antibiotic concentration at which 50% of the maximum effect is obtained) together with the growth rates of the organisms (lambda). We thought that the PD characterization of antibiotics should be determined by integrating the dynamic PD parameters and the growth rates, so we developed a new concept integrating these parameters so that a good approximation of the time course of in vivo antibacterial activity exhibited by a antibiotic might be predicted from these parameters and the pharmacokinetics of the drug. To achieve this, we analyzed the time-kill profiles of a wide range of antibiotics against various microorganisms and obtained the dynamic PD parameters and the growth rates for the various combinations of antibiotics and microorganisms. Then we analyzed the causal relationship between the PD characteristics of the antibiotics and the dynamic PD parameters and the growth rates. As a result, we derived the following criteria for predicting the PD characteristics of antibiotics. (i) if the epsilon/lambda is greater than about 10 and gamma is less than one, the pharmacodynamics should be concentration-dependent (ii) if the epsilon/lambda is within the range 1-2 and gamma is about 5 or more, the pharmacodynamics should be time-dependent (iii) if the epsilon/lambda is within the range 1-4 and gamma is in the range 1-12, the pharmacodynamics should be time-dependent or both time- and concentration-dependent. The PD characterization of antibiotics against various strains of different microorganisms can be predicted relatively easily and quickly by utilizing these criteria. These findings make it possible to determine the kinds of causative pathogens to which the antibiotics should be applicable in the clinical sites. Furthermore, it is expected that effective strategies for development and establishing the optimum dosage regimen of novel antibiotics could be worked out more scientifically and efficiently than ever on the basis of the PK/PD parameters corresponding to the predicted PD characters.

Therapeutic effect of ME1036 on endocarditis experimentally induced by methicillin-resistant Staphylococcus aureus.

The efficacy of ME1036, a novel parenteral carbapenem, was compared with that of vancomycin by using a rabbit model of methicillin-resistant Staphylococcus aureus (MRSA) endocarditis. Compared with vancomycin, ME1036 reduced the bacterial counts in the vegetations at a lower dosage or over a shorter period of administration when it was used for the treatment of MRSA endocarditis.