Application of Population Pharmacokinetic Modeling, Exposure-Response Analysis, and Classification and Regression Tree Analysis to Support Dosage Regimen and Therapeutic Drug Monitoring of Plazomicin in Complicated Urinary Tract Infection Patients with Renal Impairment.

In 2018, the FDA approved plazomicin for the treatment of complicated urinary tract infections (cUTI) including pyelonephritis in adult patients with limited or no alternative treatment options. The objective of this article is to provide the scientific rationales behind the recommended dosage regimen and therapeutic drug monitoring (TDM) of plazomicin in cUTI patients with renal impairment. A previous population pharmacokinetic (PK) model was used to evaluate the dosage regimen in cUTI patients with different degrees of renal impairment. The exposure-response analysis was conducted to identify the relationship between plazomicin exposure and nephrotoxicity incidence in cUTI patients with renal impairment. Classification and regression tree (CART) analysis was utilized to assess the TDM strategy. The receiver operating characteristics curve was plotted to compare two TDM thresholds in cUTI patients with renal impairment. The analyses suggested that dose reduction is necessary for cUTI patients with moderate or severe renal impairment. TDM should be implemented for cUTI patients with mild, moderate, or severe renal impairment to reduce the risk of nephrotoxicity. The trough concentration of 3 µg/mL is a reasonable TDM threshold to reduce the nephrotoxicity incidence while maintaining efficacy in cUTI patients with renal impairment. The application of population PK modeling, exposure-response analysis, and CART analysis allowed for the evaluation of a dosage regimen and TDM strategy for plazomicin in cUTI patients with renal impairment. Our study demonstrates the utility of pharmacometrics and statistical approaches to inform a dosage regimen and TDM strategy for drugs with narrow therapeutic windows.

Population Pharmacokinetic Analyses for Plazomicin Using Pooled Data from Phase 1, 2, and 3 Clinical Studies.

Plazomicin is an aminoglycoside with activity against multidrug-resistant Enterobacteriaceae Plazomicin is dosed on a milligram-per-kilogram-of-body-weight basis and administered by a 30-min intravenous infusion every 24 h, with dose adjustments being made for renal impairment and a body weight (BW) of ≥125% of ideal BW. A population pharmacokinetic analysis was performed to identify patient factors that account for variability in pharmacokinetics and to determine if dose adjustments are warranted based on covariates. The analysis included 143 healthy adults and 421 adults with complicated urinary tract infection (cUTI), acute pyelonephritis, bloodstream infection, or hospital-acquired bacterial pneumonia/ventilator-associated bacterial pneumonia (HABP/VABP) from seven studies (phases 1 to 3). A three-compartment structural pharmacokinetic model with a zero-order rate constant for the intravenous infusion and linear first-order elimination kinetics best described the plasma concentration-time profiles. The base structural model included creatinine clearance (CLCR) as a time-varying covariate for clearance. The covariates included age, BW, height, body surface area, body mass index, sex, race, and disease-related factors. The ranges of the α-, ß-, and γ-phase half-lives for the analysis population were 0.328 to 1.58, 2.77 to 5.38, and 25.8 to 36.5 h, respectively. Total and renal clearances in a typical cUTI or HABP/VABP patient were 4.57 and 4.08 liters/h, respectively. Starting dose adjustments for CLCR are sufficient for minimizing the variation in plasma exposure across patient populations; adjustments based on other covariates are not warranted. The results support initial dosing on a milligram-per-kilogram basis with adjustments for CLCR and BW. Subsequent adjustments based on therapeutic drug management are recommended in certain subsets of patients, including the critically ill and renally impaired.

Application of the Hartford Hospital Nomogram for Plazomicin Dosing Interval Selection in Patients with Complicated Urinary Tract Infection.

Plazomicin is a new FDA-approved aminoglycoside antibiotic for complicated urinary tract infections (cUTI). In the product labeling, trough-based therapeutic drug management (TDM) is recommended for cUTI patients with renal impairment to prevent elevated trough concentrations associated with serum creatinine increases of ≥0.5 mg/dl above baseline. Herein, the utility of the Hartford nomogram to prevent plazomicin trough concentrations exceeding the TDM trough of 3 µg/ml and optimize the area under the curve (AUC) was assessed. The AUC reference range was defined as the 5th to 95th percentile AUC observed in the phase 3 cUTI trial (EPIC) (121 to 368 µg · h/ml). Observed 10-h plazomicin concentrations from patients in EPIC (n = 281) were plotted on the nomogram to determine an eligible dosing interval (every 24 h [q24h], q36h, q48h). Based on creatinine clearance (CLcr), a 15- or 10-mg/kg of body weight dose was simulated with the nomogram-derived interval. The nomogram recommended an extended interval (q36h and q48h) in 31% of patients. Compared with the 15 mg/kg q24h regimen received by patients with CLcr of ≥60 ml/min in EPIC, the nomogram-derived interval reduced the proportion of patients with troughs of ≥3 µg/ml (q36h, 27% versus 0%, P = 0.021; q48h, 57% versus 0%, P = 0.002) while significantly increasing the number of patients within the AUC range. Compared with the 8 to 12 mg/kg q24h regimen (received by patients with CLcr of >30 to 59 ml/min in EPIC), the nomogram-derived interval significantly reduced the proportion of troughs of ≥3µg/ml in the q48h cohort (72% versus 0%, P < 0.001) while maintaining a similar proportion of patients in the AUC range. Simulated application of the Hartford nomogram optimized plazomicin exposures in patients with cUTI while reducing troughs to <3 µg/ml.

A Phase 1 Study To Assess the Pharmacokinetics of Intravenous Plazomicin in Adult Subjects with Varying Degrees of Renal Function.

Plazomicin is an FDA-approved aminoglycoside for the treatment of complicated urinary tract infections. In this open-label study, 24 adults with normal renal function or mild, moderate, or severe renal impairment (n = 6 per group) received a single 7.5-mg/kg of body weight dose of plazomicin as a 30-min intravenous infusion. Total clearance declined with renal impairment, resulting in 1.98-fold and 4.42-fold higher plazomicin exposures, as measured by the area under the concentration-time curve from 0 h to infinity, in subjects with moderate and severe impairment, respectively, than in subjects with normal renal function. (This study has been registered at ClinicalTrials.gov under identifier NCT01462136.).

Interaction of drug- and granulocyte-mediated killing of Pseudomonas aeruginosa in a murine pneumonia model.

BACKGROUND: Killing of bacterial pathogens by granulocytes is a saturable process, as previously demonstrated. There is virtually no quantitative information about how granulocytes interact with antimicrobial chemotherapy to kill bacterial cells. METHODS: We performed a dose-ranging study with the aminoglycoside plazomicin against Pseudomonas aeruginosa ATCC27853 in a granulocyte-replete murine pneumonia model. Plazomicin was administered in a humanized fashion (ie, administration of decrementing doses 5 times over 24 hours, mimicking a human daily administration profile). Pharmacokinetic profiling was performed in plasma and epithelial lining fluid. All samples were simultaneously analyzed with a population model. Mouse cohorts were treated for 24 hours; other cohorts treated with the same therapy were observed for another 24 hours after therapy cessation, allowing delineation of the therapeutic effect necessary to reduce the bacterial burden to a level below the half-saturation point. RESULTS: The mean bacterial burden (±SD) at which granulocyte-mediated kill was half saturable was 2.45 × 10(6) ± 6.84 × 10(5) colony-forming units of bacteria per gram of tissue (CFU/g). Higher levels of plazomicin exposure reduced the bacterial burden to <5 log10 CFU/g, allowing granulocytes to kill an additional 1.0-1.5 log CFU/g over the subsequent 24 hours. CONCLUSIONS: For patients with large bacterial burdens (eg, individuals with ventilator-requiring hospital-acquired pneumonia), it is imperative to kill ≥2 log10 CFU/g early after treatment initiation, to allow the granulocytes to contribute optimally to bacterial clearance.

Pharmacokinetics and safety of single and multiple doses of ACHN-490 injection administered intravenously in healthy subjects.

ACHN-490 is an aminoglycoside with activity against multidrug-resistant pathogens, including those resistant to currently used aminoglycosides. Two randomized, double-blind, placebo-controlled clinical studies investigated the pharmacokinetics (PK), safety, and tolerability of ACHN-490 injection in healthy subjects. Study 1 used a parallel-group design with escalating single (SD) and multiple doses (MD). Study 2 explored a longer duration of the highest dose tolerated in the first study. Subjects were randomly assigned to receive either ACHN-490 injection or a placebo administered by a 10-min intravenous infusion. Study 1 enrolled 39 subjects (30 active and 9 placebo) and consisted of a single dose of 1 mg/kg body weight followed by ascending SD and MD cohorts of 4, 7, 11, and 15 mg/kg for 10, 10, 5, and 3 days, respectively. Study 2 enrolled 8 subjects (6 active and 2 placebo) who received 15 mg/kg for 5 days. Safety was assessed from adverse event (AE) reporting, standard clinical laboratory procedures, and testing for renal, cochlear, and vestibular function. ACHN-490 exhibited linear and dose-proportional PK, with agreement between the studies for PK parameters assessed. The 15-mg/kg dose did not accumulate with repeated dosing over 5 days. Mean steady-state (±standard deviation) area under the concentration-time curve from 0 to 24 h (AUC(0-24)), maximum concentration of drug in serum (C(max)), half-life (t(1/2)), clearance, and volume of distribution at steady state (V(ss)) for the 15-mg/kg, day 5 dose were 239 ± 45 h·mg/liter, 113 ± 17 mg/liter, 3 ± 0.3 h, 1.1 ± 0.1 ml/min/kg, and 0.24 ± 0.04 liters/kg, respectively. AEs were mild to moderate and rapidly resolved. No evidence of nephrotoxicity or ototoxicity was observed.

Manufacture of pH- and HAase-responsive hydrogels with on-demand and continuous antibacterial activity for full-thickness wound healing.

A kind of "intelligent" antibacterial dressing-A-HA/HA-ADH/SS hydrogel was in situ formed quickly via dynamic covalent bonds cross-linking between aldehyde hyaluronic acid (A-HA), adipic acid dihydrazide graft hyaluronic acid (HA-ADH) and sisomicin sulfate (SS). FT-IR, SEM and rheological results displayed that the hydrogels were successfully prepared. The hydrogels had good optical transmittance, injectability, self-healing ability, cytocompatibility, antioxidant activity and hemostatic performance which were beneficial to observe the wound healing condition and provide a good healing environment for wounds. In addition, the hydrogels showed a pH- and HAase- dependent degradability, which allowed them to release more SS at infected wound and then exert on-demand and sustained antibacterial effect against S. aureus and E. coli. The results of wound healing and histological examination revealed that these hydrogels have a good therapeutic effect in the full-thickness mouse skin defect wound. Thus, the hydrogels are expected to be used as potential wound dressings to improve wound healing.

A Simulated Application of the Hartford Hospital Aminoglycoside Dosing Nomogram for Plazomicin Dosing Interval Selection in Patients With Serious Infections Caused by Carbapenem-Resistant Enterobacterales.

PURPOSE: In the Phase III Study of Plazomicin Compared With Colistin in Patients With Infection Due to Carbapenem-Resistant Enterobacteriaceae (CARE), plazomicin was studied for the treatment of critically ill patients with infections caused by carbapenem-resistant Enterobacterales. Initial plazomicin dosing was guided by creatinine clearance (CrCl) and subsequent doses adjusted by therapeutic drug monitoring to achieve AUC0-24 exposures within a target range (210-315 mg∙h/L). We applied the Hartford nomogram to evaluate whether this clinical tool could reduce plazomicin troughs levels and increase the proportion of patients within the target AUC range. METHODS: Thirty-seven patients enrolled in cohorts 1 or 2 of CARE were eligible for analyses. Observed 10-hour concentrations after the initial dose were plotted on the Hartford nomogram to determine an eligible dosing interval group (q24h, q36h or q48h). On the basis of baseline CrCl, a 15- or 10-mg/kg dose was simulated with the nomogram-recommended dosing interval. The proportion of patients in each dosing interval group with a trough ≥3 mg/L (trough threshold associated with serum creatinine increases ≥0.5 mg/dL in product label) was quantified. Simulated interval-normalized AUC0-24 was compared with the target AUC range. FINDINGS: Among the 28 patients with a CrCl ≥60 mL/min, the nomogram recommended every-24-hour dosing in 61% and an extended-interval (q36h or q48h) in 39% of patients. For patients with a CrCl ≥30-59 mL/min (n = 9), the nomogram recommended every-24-hour dosing and an extended-interval in 22% and 78% of patients, respectively. Among both renal function cohorts, exposure simulation with the nomogram significantly reduced the proportion of patients with trough concentrations ≥3 mg/L (CrCl ≥60 mL/min cohort: 91% vs 9%, P < 0.001; CrCl ≥30-59 mL/min cohort, 100% vs 0%, P < 0.001). Relative to the observed mean (SD) AUC0-24 of 309 mg∙h/mL (96 mg∙h/mL), simulation of extended intervals resulted in a mean interval-normalized AUC0-24 of 210 mg∙h/mL (40 mg∙h/mL) in all patients eligible for an extended interval, resulting in a similar proportion (49% vs 54%) of patients within the target AUC0-24 range after the first dose. IMPLICATIONS: Application of the Hartford nomogram successfully reduced the likelihood of elevated plazomicin trough concentrations while improving AUC exposures in these patients with carbapenem-resistant Enterobacterales infections.

Pharmacodynamics of plazomicin and a comparator aminoglycoside, amikacin, studied in an in vitro pharmacokinetic model of infection.

The new aminoglycoside plazomicin shows in vitro potency against multidrug-resistant Enterobacteriales. The exposure-response relationship of plazomicin and the comparator aminoglycoside amikacin was determined for Escherichia coli, while for Klebsiella pneumoniae only plazomicin was tested. An in vitro pharmacokinetic model was used. Five E. coli strains (two meropenem-resistant) and five K. pneumoniae strains (two meropenem-resistant) with plazomicin MICs of 0.5-4 mg/L were used. Antibacterial effect was assessed by changes in bacterial load and bacterial population profile. The correlation between change in initial inoculum after 24 h of drug exposure and the AUC/MIC ratio was good (plazomicin R2 ≥ 0.8302; amikacin R2 ≥ 0.9520). Escherichia coli plazomicin AUC/MIC ratios for 24-h static, -1, -2 and -3 log drop were 36.1 ± 18.4, 39.3 ± 20.9, 41.2 ± 21.9 and 44.8 ± 24.3, respectively, and for amikacin were 49.5 ± 12.7, 55.7 ± 14.8, 64.1 ± 19.2 and 73.3 ± 25.3. Klebsiella pneumoniae plazomicin AUC/MIC ratios for 24-h static, -1, -2 and -3 log drop were 34.0 ± 15.2, 46.8 ± 27.8, 67.4 ± 46.5 and 144.3 ±129.8. Plazomicin AUC/MIC ratios >66 and amikacin AUC/MIC ratios >57.7 were associated with suppression of E. coli growth on 4 × or 8 × MIC recovery plates. The equivalent plazomicin AUC/MIC to suppress resistance emergence with K. pneumoniae was >132. The plazomicin AUC/MIC for 24-h static effect and -1 log reduction in E. coli and K. pneumoniae bacterial load was in the range 30-60. Plazomicin AUC/MIC targets aligned with those of amikacin for E. coli.

Plazomicin for the treatment of patients with complicated urinary tract infection.

In June 2018, the United States Food and Drug Administration (FDA) approved plazomicin, a novel neoglycoside, for the treatment of adults with complicated urinary tract infections who have limited or no alternative treatment options. This approval was based on substantial preclinical and clinical work, and marks an important advance in the treatment of multidrug-resistant bacterial pathogens. This manuscript reviews the in vivo and in vitro work that led to the approval of plazomicin and examines how the drug may be used in the years ahead to treat patients with aggressive and life-threatening infections.

Ocular penetration of subconjunctivally injected gentamicin, sisomicin and cephaloridine.

The intraocular penetration of three current bactericidal broad-spectrum antibiotics, namely, gentamicin sulphate, sisomicin sulphate (Ensamycin) and cephaloridine, following subconjunctival injection was studied in 95 patients undergoing elective cataract surgery. Rapid and high penetration of all three drugs was evidenced by the fact that the first samples assayed by modified disc diffusion technique 15 minutes after injection showed drug levels effective against all susceptible pathogens. Peak levels of gentamicin, sisomicin and cephaloridine attained one hour after injection were 14.913 +/- 0.310, 19.000 +/- 0.408 and 30.830 +/- 1.195 micrograms/ml, respectively. Such high drug titres would provide drug concentrations 6 to 8 times the minimum inhibitory concentration necessary against susceptible organisms. The duration of the effective bioavailability of the drugs studied varied from 12 to 18 hours. We believe our study is the first to document the excellent penetration of sisomicin and the little-studied drug cephaloridine, and hope our results will open an avenue for in vivo studies to evaluate their clinical use.

In vitro simulated pharmacokinetics profiles: forecasting antibiotic optimal dosage.

Sisomicin (SMN) and cefotaxime (CTX) antimicrobial effect (AME) kinetics were studied under in vitro stimulation the drug monoexponential pharmacokinetic profiles mimicking normal and impaired elimination of SMN or CTX administered in various doses to humans. Similar general shape of the AME intensity or duration vs the SMN and CTX AUC curves, i.e. the appearance of the "bacteriostatic" and "bactericidal" phases, was established irrespective of the antibiotic elimination rate. At the same time the AME vs AUC curves simulated normal and delayed drug elimination did not match. Thus, AME is defined not only the AUC value but also the peculiarities of the pharmacokinetic profile and, subsequently, the term of "antibiotic efficient concentration" is unseparable of the pharmacokinetic profile.

[Pharmacokinetic monitoring of aminoglycoside therapy: an optimal method of administration of individualized doses of gentamicin and sisomicin]. / Farmakokineticheskii monitoring pri lechenii aminoglikozidami: optimal'nyi sposob individualizatsii dozirovaniia gentamitsina i sizomitsina.

One of the most promising approaches to design the optimal schedule for TDM provides a single determination of a drug content in the blood specimen being collected at the "ideal" sampling time equaled to the inverse value of the elimination rate constant. Three versions of the one-point method when the specimen was collected at the "ideal" time point (3 h after a single i.m. drug administration), as well as at the times of "maximum" (1 h after injection) and "minimum" (6 h after injection) concentrations were compared by the retrospective analysis of the routine TDM data obtained with HPLC-techniques in 47 patients treated with gentamicin or sisomicin. As optimal individualized doses were considered ones calculated on the base of three subsequent determinations of the aminoglycoside concentrations, i.e. 1, 3 and 6 h after injection, and the estimation of individual clearance values (Cli). The optimal doses (DCl) were calculated according to equation DCl = Dp.Cli/Clp, where Dp and Clp are population values of the dose (1 mg/kg) and Cl 72.4 ml/(h.kg), respectively. The approximate values of the individual doses (D) were calculated according to equation D = Dp.Cp/Ci, where Ci is the individual drug serum concentration 1, 3 or 6 h after administration and Cp is the corresponded population value (4.8, 1.9 and 0.8 mg/l, respectively).(ABSTRACT TRUNCATED AT 250 WORDS)

[Pharmacokinetic monitoring of antibiotic therapy]. / Farmakokineticheskii monitoring v antibiotikoterapii.

The general strategy in optimization of antibiotic dosage regimens included development of population or common regimens for an "average" patient (the 1st approximation), subpopulation regimens for patients of certain categories on the basis of interactions between the pharmacokinetic parameters and "patient factors" (the 2nd approximation) and individual regimens on the basis of the data of the pharmacokinetic monitoring (the 3rd approximation). Characteristics of every of the approximations in antibiotic therapy of adults and children were analyzed. Out of the peculiarities of the strategy use in pediatrics+ and micropediatrics+ the following should be indicated: (1) pharmacokinetic heterogeneity of the population requiring grouping of the patients and consequently development of subpopulation dosage regimens omitting stage I, (2) possible development of dosage regimens on the basis of the ration between the pharmacokinetic parameters or immediate drug concentration values and the "patient factors" not only in chronic but also in transitory impairment of some functions and (3) the necessity of considering systematic changes in "pharmacokinetic status" of every child during individualization of the dosage regimens by the data of the pharmacokinetic monitoring.

[Ways of increasing the effectiveness of antibacterial therapy in newborns]. / Puti povysheniia éffektivnosti antibakterial'noi terapii novorozhdennykh.

Ways for increasing antibiotic therapy efficacy in newborns are discussed. They are the following: consideration of the structure of the antibiotic use, improvement of infection diagnosis, the use of computers in epidemiological supervision of antibiotic resistance, the use of "old" antibiotics in new dosage forms, pharmacokinetic monitoring. The data on the frequency of the antibiotic use in newborns in maternity hospitals, at home and in neonatal departments as well as on diagnosis and treatment of chlamydiosis in newborns are presented. Requirements to the computer programs on control of antibiotic resistance are described. With the account of the requirements an original epidemiological program for personal computers was developed. The results of the pharmacokinetic monitoring of the use of sisomicin and amikacin are presented as well.

[Individual schedule of administration of aminoglycosides with reference to anatomo-physiological and pathological factors]. / Individualizatsiia skhem vvedenia aminoglikozidov s uchetom anatomo-fiziologicheskikh i patologicheskikh faktorov.

Potentiality of designing individual dosage of sisomicin and gentamicin in regard to "patient factors" was estimated. 62 adult patients with various pulmonary diseases at the background of volemic disorders of diverse degrees were treated with the aminoglycosides under monitoring of their blood levels. Concentrations of sisomicin and gentamicin in serum 1, 3 and 6 hours after their single administration in a dose of 1 mg/kg were determined by HELC. The antibiotic pharmacokinetics was characterized by pronounced individual variability. The ratio of the difference between the upper and lower confidence limits to the average values of the steady-state volume of distribution, the total clearance and the mean residence time amounted to 70, 60 and 57 per cent respectively. To elucidate the cause of the variability multiple correlation analysis of the pharmacokinetic parameters by the "patient factors" was performed. The highest coefficient of the multiple correlation (r = 0.690) defined relation between the aminoglycoside concentration 1 hour after the injection and the hematocrit, globular volume and phase of the volemic disorders which was expressed in coded variables. The coefficient of the multiple correlation between the total clearance and the body surface area, concentrations of creatinine and urea in serum, hematocrit, circulating blood volume and the phase of the volemic disorders was equal to 0.439. Therefore, the consideration of the above factors allowed to explain only 20 per cent of the observed individual variability of the pharmacokinetic parameters. In this connection mediated prediction of total clearance and subsequently individual dosage of the aminoglycosides by the "patient factors" was expedient only until the primary data on the pharmacokinetic monitoring were obtained.

[Correlation of dose-antimicrobial effect in modeling in vitro pharmacokinetic profiles of normal and impaired elimination of antibiotics]. / Sootnosheniia kontsentratsii/antimikrobnyi éffekt pri modelirovanii in vitro farmakokineticheskikh profilei normal'noi i narushennoi éliminatsii antibiotikov.

Relationships between concentration and antimicrobial effect (AME) of sisomicin (SMN) and cefotaxime (CTX) were established by simulating their pharmacokinetic profiles in an in vitro dynamic model. The AME duration (TE, time shift between the curves of bacteria heat output in the presence and absence of the antibiotics) or intensity (IE, area between the above curves) for both the antibiotics depended in the same way on the area under the concentration/time curve (AUC, mimicing of intravenous administration of the antibiotics in various doses). At low and moderate values of the AUC the dependences of IE or TE vs the AUC (the bacteriostatic phase of the AME development) were of the sigmoid shape while at high values of the AUC there was a marked increase in IE or TE (the bactericidal phase). The patterns of the IE or TE vs AUC curves in impaired antibiotic elimination were analogous. At the same time the IE or TE vs AUC curves for both the antibiotics under simulation of normal elimination (T 1/2, SMN-2.1 h, T 1/2, CTX-1.2 h) and impaired one (T 1/2, SMN-8.3 h, T 1/2, CTX-4.6 h) did not match. In the first case the AMESMN was on the whole higher and the AMECTX was lower than in the second case. Therefore, in patients with renal failure the efficient concentration of the aminoglycoside in blood can be higher and that of the cephalosporin on the contrary can be lower than the normal.

Comparison of the next-generation aminoglycoside plazomicin to gentamicin, tobramycin and amikacin.

Plazomicin (formerly ACHN-490) is a next-generation aminoglycoside that was synthetically derived from sisomicin by appending a hydroxy-aminobutyric acid substituent at position 1 and a hydroxyethyl substituent at position 6'. Plazomicin inhibits bacterial protein synthesis and exhibits dose-dependent bactericidal activity. Plazomicin demonstrates activity against both Gram-negative and Gram-positive bacterial pathogens, including isolates harboring any of the clinically relevant aminoglycoside-modifying enzymes. However, like older parenteral aminoglycosides, plazomicin is not active against bacterial isolates expressing ribosomal methyltransferases conferring aminoglycoside resistance. Plazomicin has been reported to demonstrate in vitro synergistic activity when combined with daptomycin or ceftobiprole versus methicillin-resistant Staphylococcus aureus, heteroresistant vancomycin-intermediate S. aureus, vancomycin-intermediate S. aureus, and vancomycin-resistant S. aureus and against Pseudomonas aeruginosa when combined with cefepime, doripenem, imipenem or piperacillin-tazobactam. After intravenous administration of plazomicin to humans at a dose of 15 mg/ kg, the maximum concentraration was 113 µg/ml, the area under the curve(0-24) was 239 h·µg/ml, the half-life was 4.0 h and the steady-state volume of distribution was 0.24 L/kg. Results from a Phase II randomized, double-blind study in patients with complicated urinary tract infection and acute pyelonephritis including cases with concurrent bacteremia comparing plazomicin 15 mg/kg intravenously once daily for 5 days with levofloxacin 750 mg intravenously. for 5 days are anticipated in 2012. Human studies to date have not reported nephrotoxicity or ototoxicity, and lack of ototoxicity has been reported in the guinea pig model. Given reported increases in bacterial resistance to current antimicrobial agents and the lack of availability of new agents with novel mechanisms, plazomicin may become a welcomed addition to the antibacterial armamentarium pending positive results from large-scale clinical trials and other required clinical studies.