Optimal Empiric Polymyxin B Treatment of Patients Infected with Gram-Negative Organisms Detected Using a Blood Antimicrobial Surveillance Network in China.

BACKGROUND: Few pharmacodynamics studies to date have evaluated the efficacy and safety of polymyxin B (PMB) in treating patients with bloodstream infections (BSIs) in China.
METHODS: Patients with BSIs were identified using an antimicrobial surveillance network, and their pathogens were isolated. Patients were treated with a loading dose of PMB followed by either a weight-based or weight-independent maintenance dose. Monte Carlo simulation was utilized to calculate the probability of target attainment (PTA) and cumulative fraction of response (CFR) against Gram-negative organisms in patients with normal or decreased renal function.
RESULTS: A total of 10,066 Gram-negative organisms, including 5500 Escherichia coli (Eco), 2519 Klebsiella pneumoniae (Kpn), 501 Acinetobacter baumannii (Aba), were isolated from patients with BSIs. Although these strains were highly resistant to carbapenem, they remained susceptible to PMB. Among patients with renal impairment (mean CrCL, 42 mL/min), a PMB 2.5 mg/kg loading dose followed by a maintenance dose of 60 mg q12h reached ≥90% PTA against isolates with an MIC of 2 mg/L, with a low risk of toxicity. Among patients with normal renal function (mean CrCL, 123 mL/min), all simulated regimens showed PTAs of 25-80%. A weight-based loading dose followed by either a weight-based or weight-independent maintenance dose showed a promising CFR, especially in patients with renal impairment, with CFRs ≥90% against carbapenem-resistant Eco, Kpn, and Aba. Simulated regimens showed a disappointing CFR (<80%) against carbapenem-resistant Pae in patients with normal renal function. Based on the optimal balance of efficacy and toxicity, a fixed maintenance dose of 60 mg q12h among patients with renal impairment yielded a CFR similar to regimens based on total body weight and was associated with a probability of toxicity (12.5%) significantly lower than that of simulations based on total body weight. Among patients with normal renal function, a weight-based maintenance dose of 1.25 mg/kg q12h achieved a higher CFR than a fixed maintenance dose, without significantly increasing toxicity.
CONCLUSION: A 2.5 mg/kg loading dose of PMB is optimal, regardless of renal function. A fixed maintenance dose of 60 mg q12h is recommended for empirical treatment of patients with renal impairment infected with Eco, Kpn, and Aba, whereas a weight-based maintenance dose of 1.25 mg/kg is recommended for patients with normal renal function.

Introduction

The widespread dissemination of bacterial strains resistant to antimicrobial treatment has posed a serious threat to public health.1 Disappointing clinical outcomes have been observed in patients with bloodstream infections (BSIs) with multidrug-resistant or carbapenem-resistant organisms.2,3 Data from the China Antimicrobial Surveillance Network (CHINET) have revealed significant increases in the rates of resistance of Klebsiella pneumoniae (Kpn) and Acinetobacter baumannii (Aba) strains to most classes of antimicrobial drugs, resulting in higher morbidity and mortality rates and higher medical costs in patients infected with such strains.4,5 Because of the limited effectiveness of antibiotics against life-threatening carbapenem-resistant isolates, the use of ceftazidime-avibactam, tigecycline, and polymyxins as last-resort options has increased. Ceftazidime-avibactam, which recently became clinical available in China, has exhibited excellent in vitro activity against carbapenem-resistant Enterobacteriaceae (mainly Kpn) isolated from CHINET 2018.6 However, ceftazidime-avibactam demonstrated limited activity (MIC50/90, 64/>64 mg/L) against Aba isolates, 79.2% of which were carbapenem-resistant. Polymyxins were approved for treatment in the 1950s, but they have a narrow therapeutic window and a potential to cause severe nephrotoxicity.7,8 Although polymyxins are regarded as alternative agents against carbapenem-resistant organisms in the “bad bugs, no drugs” era, their optimal dosing regimens remain poorly defined, especially that of polymyxin B (PMB). Because in vitro susceptibility is insufficient to select rational antibiotic dosing regimens, the integration of population pharmacokinetic (PPK) parameters and MIC data is needed to optimize PMB dosing regimens.

The pharmacokinetic/pharmacodynamic (PK/PD) relationships of the two clinically available polymyxins, colistimethate sodium (CMS) and PMB, are not fully understood.9,10 CMS is administrated parenterally as an inactive prodrug, with the in vivo conversion of CMS to colistin exhibiting a relatively large degree of interindividual variability. Thus, plasma concentrations of colistin increase slowly, leading to difficulties in optimal dose selection.11 Conversely, PMB appears to have remarkably low interpatient variability, making it easier to predict its PK.12 In addition, PMB has lower nephrotoxicity rates than CMS,13,14 suggesting that PMB has superior pharmacological characteristics in the treatment of infections. Because CMS is more widely available worldwide, clinical experience with PMB is lower than that with CMS.14,15

To date, no studies focusing on optimal PMB dosing regimens to treat patients in China with BSIs have been based on PK parameters and nationwide surveillance of MIC data. The present study was designed to (i) evaluate the distribution of PMB MCIs against Gram-negative organisms in patients with BSIs; (ii) re-evaluate the reasonable clinical breakpoints of PMB using Monte Carlo simulation (MCS) in Chinese populations; and (iii) determine the regimen involved in the prompt initiation of appropriate empirical antimicrobial therapy in patients with BSIs.

Materials and Methods

Bacterial Isolates

Gram-negative bacterial isolates, including Escherichia coli (Eco), Klebsiella pneumoniae (Kpn), Pseudomonas aeruginosa (Pae), Acinetobacter baumannii (Aba) and other strains, isolated from the Blood Bacterial Resistant Investigation Collaborative System (BRICS), were collected from patients in 60 tertiary and secondary hospitals in China between January 2018 and December 2019. Pathogens were isolated and identified by microbiological methods using matrix-assisted laser desorption ionization-time-of-flight (MALDI-TOF, Bruker) mass spectrometry (MS).16

Antimicrobial Susceptibility Testing

The MICs for imipenem and PMB were determined by the agar dilution and broth microdilution methods, respectively, as described by the Clinical and Laboratory Standards Institute (CLSI). For imipenem, MICs of ≤2 mg/L and ≥4 mg/L were defined as susceptible and resistant, respectively, whereas for PMB, MICs of ≤2 mg/L and ≥4 mg/L were defined as intermediate and resistant, respectively.17 E. coli strain 25,922 from the American Type Culture Collection (ATCC) was used for quality control.

Population PK Model and PK/PD Target

The PPK data for PMB were obtained from a recently published study on critically ill patients in China, with a two-compartment model used to describe the time-concentration relationship for PMB.18 In that study, patients were grouped into those with normal renal function (n=37) and renal insufficiency (n=33). The mean creatinine clearance (CrCL) in these two groups were 123.3 mL/min (range, 81.6–315.2 mL/min) and 42.0 mL/min (range, 15.6–77.6 mL/min), respectively. The detailed PPK parameters are listed in Table 1. Covariate modeling showed that PMB PK was not significantly associated with patient age, sex, CrCL or total body weight (WT). Patients receiving any form of renal replacement therapy were not enrolled in the PPK model.

Table 1

Pharmacokinetic Parameters Used in the Monte Carlo Simulation

	Normal Renal Function	Renal Impairment
Age (year)	47.3±17.7	54.2±17.5
Weight (kg)	68.6±11.6	66.9±11.1
CrCL (mL/min)	123(81.6–315.2)	42(15.6–77.6)
V1	6.87	1.12
V2	11.97	1.8
CL	2.19	1.58
Q	13.83	10.28
Omega2v1	0.78	0.38
Omega2v2	0.32	0.74
Omega2cl	0.22	0.26
Omega2q	0.68	NA

PMB displays concentration-dependent antibacterial effects against bacterial isolates. AUC/MIC is the optimal PK/PD index, closely associated with clinical efficacy. Based on data from a murine thigh infection model, the PD target had to be over 50 mg∙h/L for promising outcomes.19 In addition, consensus guidelines indicated that fAUC/MIC was the PK/PD target that best correlated with bacterial killing.20 Because the molecular characteristics and in vitro antibacterial activities of colistin and PMB against pathogens are similar, a fAUC/MIC of approximately 20 for colistin was responsible for 2-log killing of Pae and Aba.21 The unbound fraction of PMB was defined as 0.42 derived from Sandri study,12 making the PK/PD targets of AUC/MIC and fAUC/MIC approximately identical. AUC/MIC was defined as the PK/PD target for further analysis. In addition, PMB has a narrow therapeutic window, and its nephrotoxicity is a dose‐limiting adverse effect. Based on a pharmacometric meta-analysis of PMB nephrotoxicity, an AUCss,24h of 100 mg∙h/L was regarded as a predictor of nephrotoxicity,18,22 and a target AUCss,24h >100 mg∙h/L was defined as a threshold associated with an increased risk of nephrotoxicity. All the simulated dosing regimens were tested to calculate the possibility of clinical cure and toxic effects.

Monte Carlo Simulation

To date, widely used PMB dosing regimens have been based on total body weight. International consensus guidelines recommend that PMB dosage not be adjusted in patients with renal impairment, a recommendation inconsistent with the FDA approved package inserts.23,24 Furthermore, little PK information is available for patients at the extremes of body weight.12 Because PMB has a narrow therapeutic window, optimal dosages that balance efficacy and toxicity have not yet been determined. To optimize the balance between efficacy and toxicity in different populations, fixed and weight-based PMB maintenance dose were simulated. These included a loading dose of 2.5 mg/kg followed by a maintenance dose of 60, 80, or 100 mg q12h; a loading dose of 2.2 mg/kg followed by a maintenance dose of 1 or 1.25 mg/kg q12h; a loading dose of 2.5 mg/kg followed by a maintenance dose of 1.25 or 1.5 mg/kg q12h; and a loading dose of 3 mg/kg followed by a maintenance dose of 1.5 mg/kg q12h. A 5000 patient MCS was utilized to calculate the probability of target attainment (PTA) and the cumulative fraction of response (CFR) of each dosage regimen against a bacterial MIC population using Crystal Ball software (version 11.1.2.4; Oracle). During simulation, the PK parameters obeyed a log-normal distribution, whereas MIC obeyed a discrete distribution. Moreover, the steady state Cmin and Cmax were calculated. Dosing regimens were considered optimal if they provided ≥90% CFR and a low risk of drug-related nephrotoxicity. Dosing regimens with a CFR between 80% and 90% were regarded as providing moderate probabilities of treatment success.25

Results

Microbiological Data

A total of 10,066 Gram-negative bacterial isolates (5500 Eco, 2519 Kpn, 546 Pae, and 501 Aba) were collected from BRICS (Table 2). Of the total, Eco, Kpn, Pae, and Aba Gram-negative isolates collected from patients with BSIs, 1169 (11.6%), 82 (1.5%), 506 (20.1%), 210 (38.5%), and 315 (62.9%), respectively, were carbapenem-resistant. Compared with most antibiotics, which show poor antibacterial activity against carbapenem-resistant organisms, PMB exhibited favorable in vitro activity against all the tested organisms, including the carbapenem-resistant strains. PMB had MIC50 and MIC90 values of 0.5 and 1.0 mg/mL, respectively, against carbapenem-resistant organisms, with PMB having both MIC50 and MIC90 values of 2 mg/mL against Gram-negative organisms. PMB had mildly reduced antibacterial activity against Pae than against the other Gram-negative species.

Table 2

The in vitro Activities of PMB Against Gram-Negative Organisms Isolated from BRICS

Isolates	Number	Carbapenem-Resistance Rate	MIC50	MIC90	MIC Range
Eco	5500	-	0.5	2	0.03–32
Kpn	2519	-	0.5	2	0.03–32
Pae	546	-	2	2	0.03–32
Aba	501	-	1	2	0.125–32
G-	10,066	-	0.5	2	0.03–32
CR-Eco	82	1.5	0.5	2	0.25–4
CR-Kpn	506	20.1	0.5	2	0.25–32
CR-Pae	210	38.5	2	2	0.5–4
CR-Aba	315	62.9	1	2	0.25–32
CR-G-	1169	11.6	1	2	0.25–32

Abbreviations: Eco, Escherichia coli; Kpn, Klebsiella pneumoniae; Pae, Pseudomonas aeruginosa; Aba, Acinetobacter baumannii; G-, Gram-negative; CR, carbapenem-resistant; PMB, polymyxin B; BRICS, Blood Bacterial Resistant Investigation Collaborative System.

A 5000 subject MCS based on PPK data for each dosing regimen was performed to calculate PTA and CFR. The relationships between MIC and PTA for various dosing regimens and CrCL are presented in Figure 1. Based on the PK/PD target of AUC/MIC ≥50, all the simulated regimens reached ≥90% PTA against isolates with MICs of ≤1 mg/L in patients weighing 65 kg, regardless of renal function. However, none of the simulated regimens achieved >90% PTA at the current CLSI breakpoint of 2 mg/L in patients with normal renal function, whereas most simulated regimens achieved promising PTA in subjects with renal impairment.

Figure 1

Probability of target attainment (PTA) of 50 AUC/MIC for the simulated polymyxin B dosing regimens in patients with normal and decreased renal function.

The possibility of nephrotoxicity of each simulated PMB dosing regimen was also determined (Figure 2). MICs of 1 mg/L for subjects with normal renal function and 2 mg/L for subjects with reduced renal function were used to calculate the PTA of different PMB dosing regimens reaching ≥50 AUC/MIC. Based on the combined efficacy for reaching the PTA target and the probability of developing drug-related toxicity, patients with normal renal function weighing 50, 65, and 80 kg should receive PMB loading doses of 2.5, 2.5, and 2 mg/kg, respectively, followed by maintenance doses of 1.25, 1.25, and 1 mg/kg, respectively, to treat organisms with a MIC of 1 mg/L. Total body weight-based dosing strategies, however, may not be optimal in balancing efficacy and toxicity among patients with renal impairment. These patients should receive a weight-based loading dose followed by a fixed maintenance dose. Compared with weight-independent dosing strategies, weight-based dosing resulted in increased toxicity in higher-weight patients. For example, the probability of toxicity was >50% in patients weighing 65 kg who received a PMB loading dose of 2 mg/kg loading dose followed by a maintenance dose of 1.25 mg/kg q12h. A higher risk was observed in patients weighing 80 kg, even in those receiving a maintenance dose of 1 mg/kg q12h. By contrast, fixed maintenance dose strategies provided a better balance between efficacy and toxicity in patients of different body weight strata with reduced renal function.

Figure 2

Probability of target attainment (PTA) for a MIC of 1 mg/L in patients with normal renal function and for a MIC of 2 mg/L in patients with renal impairment when efficacy is defined as 50 AUC/MIC, and toxicity is defined as an AUC >100 mg∙h/L at steady state for polymyxin B doses administered to patients.

Calculations of simulated Cmin and Cmax showed that these values were highly heterogeneous in patients with reduced renal function (Table 3). Cmin and Cmax ranges were 0.94–3.01 mg/L and 4.55–14.56 mg/L, respectively, in patients with normal renal function, but were 0.07–0.23 mg/L and 12.94–41.41 mg/L, respectively, in patients with renal impairment.

Table 3

Simulated Cmin and Cmax of PMB Dosing Regimens at Steady State

Renal Function	WT (kg)	Maintenance Dose	Cmin		Cmax
			Median (mg/L)	Range (5–95%) (mg/L)	Median (mg/L)	Range (5–95%) (mg/L)
Normal renal function	50	PMB 1 mg/kg q12h	0.94	0.12–3.04	4.55	2.39–8.45
		PMB 1.25 mg/kg q12h	1.18	0.16–3.81	5.69	2.99–10.56
		PMB 1.5 mg/kg q12h	1.41	0.19–4.57	6.83	3.59–12.67
		PMB 2 mg/kg q12h	1.88	0.25–6.09	9.10	4.78–16.89
	65	PMB 1 mg/kg q12h	1.22	0.16–3.96	5.92	3.11–10.98
		PMB 1.25 mg/kg q12h	1.53	0.20–4.95	7.40	3.89–13.72
		PMB 1.5 mg/kg q12h	1.83	0.24–5.94	8.87	4.66–10.47
		PMB 2 mg/kg q12h	2.45	0.32–7.91	11.83	6.22–21.96
	80	PMB 1 mg/kg q12h	1.50	0.20–4.87	7.28	3.83–13.51
		PMB 1.25 mg/kg q12h	1.88	0.25–6.09	9.10	4.78–16.89
		PMB 1.5 mg/kg q12h	2.26	0.30–7.31	10.92	5.74–20.27
		PMB 2 mg/kg q12h	3.01	0.40–9.74	14.56	7.65–27.03
	–	PMB 60 mg q12h	1.13	0.15–3.65	5.46	2.87–10.14
	–	PMB 80 mg q12h	1.51	0.20–4.87	7.28	3.83–13.51
	–	PMB 100 mg q12h	1.88	0.25–6.09	9.10	4.78–16.89
Renal impairment	50	PMB 1 mg/kg q12h	0.07	0.00002–1.16	12.94	7.56–22.63
		PMB 1.25 mg/kg q12h	0.09	0.00003–1.45	16.18	9.45–28.29
		PMB 1.5 mg/kg q12h	0.11	0.00003–1.74	19.41	11.35–33.95
		PMB 2 mg/kg q12h	0.15	0.00004–2.33	25.88	15.13–45.27
	65	PMB 1 mg/kg q12h	0.10	0.00003–1.51	16.82	9.83–29.43
		PMB 1.25 mg/kg q12h	0.12	0.00004–1.89	21.03	12.29–36.78
		PMB 1.5 mg/kg q12h	0.14	0.00004–2.27	25.23	14.75–44.14
		PMB 2 mg/kg q12h	0.19	0.00006–3.02	33.64	19.67–58.85
	80	PMB 1 mg/kg q12h	0.12	0.00004–1.86	20.71	12.10–36.20
		PMB 1.25 mg/kg q12h	0.15	0.00004–2.33	25.88	15.13–45.27
		PMB 1.5 mg/kg q12h	0.18	0.00005–2.79	31.06	18.15–54.32
		PMB 2 mg/kg q12h	0.23	0.00007–3.72	41.41	24.20–72.43
	–	PMB 60 mg q12h	0.09	0.00002–1.40	15.53	9.08–27.16
	–	PMB 80 mg q12h	0.12	0.00003–1.86	20.71	12.10–36.21
	–	PMB 100 mg q12h	0.15	0.00004–2.33	25.88	15.13–45.27

Abbreviations: WT, total body weight; PMB, polymyxin B.

The simulated CFR results for weight-based and weight-independent maintenance doses are shown in Figures 3 and 4, respectively. Among patients with normal renal function weighing 65 kg, a PMB loading dose of 3 mg/kg followed by a maintenance dose of 1.5 mg/kg q12h displayed the highest CFR, whereas a loading dose of 2.5 mg/kg followed by a maintenance 1.25 mg/kg q12h achieved similar CFR, with >90% probabilities against carbapenem-resistant Eco (CR-Eco), followed by 88.8% against CR-Kpn, 83.0% against CR-Aba and 70.0% against CR-Pae. The relatively low risk of toxicity and low medical cost of the latter regimen were beneficial to patients when compared with a maintenance dose of 1.5 mg/kg q12h.

Figure 3

Cumulative fraction of response (CFR) to polymyxin B against the tested Eco and Kpn isolated from BRICS.

Figure 4

Cumulative fraction of response (CFR) to polymyxin B against the tested Pae, Aba and Gram-negative organisms isolated from BRICS.

Among patients with renal impairment, the CFR of a fixed maintenance dose was similar to that based on total body weight and was associated with a significantly lower probability of toxicity than that obtained in simulations based on total body weight. These findings indicate that a fixed maintenance dose was suitable for different body weight strata of patients with decreased renal function, especially at the extremes of body weight. Among underweight patients, a fixed maintenance dose of 60 mg q12h achieved higher CFRs than regimens based on total body weight. Meanwhile, the risk of toxicity remained relatively low (~12.5%). CFR could be further increased in overweight patients with renal impairment, as a weight-based loading dose was required, followed by a fixed maintenance dose. A fixed maintenance dose therefore resulted in a significantly lower risk of nephrotoxicity than a weight-based maintenance dose in patients with renal impairment.

Discussion

The development of antibiotic resistance in Gram-negative bacterial isolates has emerged as a global public health concern. Inappropriate antibiotic therapy for patients with BSIs has been associated with poor outcomes.26,27 Unfortunately, our results revealed a high prevalence of CR-Kpn, Pae, and Aba in patients with BSIs, similar to the CHINET and Chinese Meropenem Surveillance Study (CMSS) results, indicating that highly resistant pathogens were widespread throughout China.5,28 Although PMB has shown promising in vitro antibacterial activity against carbapenem-resistant Gram-negative strains, few studies to date have compared the efficacy and safety of PMB and CMS dosing regimens in the treatment of BSIs. Most areas in China may have access only to CMS, not to PMB. In addition, large scale surveillance data of the MICs of bacterial strains toward PMB are urgently needed. Because PMB has superior PK characteristics, optimizing its clinical use is crucial in managing difficult-to-treat patients with BSIs.

In the present study, MCS was performed using different PMB dosage regimens against Gram-negative organisms isolated from BRICS. The number of pathogens included in the present study was 10,066, significantly larger than the numbers included in previous studies.29 Unlike previous studies, the focus of the present study was on the treatment of BSIs. Furthermore, the PPK data were derived from the Chinese population. The integration of domestic PPK parameters and population MIC data was useful in optimizing PMB dosage regimens in China.30 To our knowledge, the BRICS is the largest blood antimicrobial surveillance in China.

Although the efficacy of PMB may be enhanced by administration of higher loading doses, higher loading doses may increase the risk of toxicity, as PMB has a narrow therapeutic window. Our simulation results demonstrated that a loading dose of 2.5 mg/kg followed by a maintenance dose of 1.25 mg/kg could provide sufficient antimicrobial exposure with low risks of drug-related toxicity in the treatment carbapenem-resistant organisms (except for CR-Pae) among patients with normal renal function. Higher doses increased the risk of nephrotoxicity risk, with a maintenance dose of 1.5 mg/kg q12h resulting in a >50% possibility of toxicity in patients weighing 80 kg. This situation was significantly amplified in patients with renal impairment. Thus a fixed maintenance dose may be optimal in overcoming toxicity in renally impaired patients. Our findings suggest that a loading dose of 2.5 mg/kg is optimal, regardless of renal function, followed by a fixed maintenance dose in patients with impaired renal function. Consistent with our findings, a weight-based loading dose followed by a fixed maintenance dose of PMB has been reported to maximize efficacy while balancing toxicity concerns, whereas weight-based loading and maintenance doses did not.22 Furthermore, a PMB PPK study found that CL and Q values differed significantly in patients with normal and reduced renal function, whereas the variance and median AUCss,24h changes remained within a 2-fold range in patients treated with a weight-based maintenance dose, a finding commonly accepted as the threshold justification for dosing adjustment.18,31 Although dosing adjustment may not be necessary in patients with renal impairment, this strategy has been associated with increased toxicity rates in patients with decreased renal function, with over 50% of simulated AUCss,24h being >100 mg∙h/L.18 Moreover, weight-based maintenance doses have been associated with increased toxicity in higher-weight patients.32,33 In the present study, a fixed maintenance dose of 60 mg q12h provided sufficient antimicrobial coverage against carbapenem-resistant Gram-negative organisms in patients with renal impairment, along with a relative low risk of toxicity. Thus, a strategy that includes a weight independent maintenance dose may be optimal in patients with renal insufficiency, providing the optimal balance between CFR and the risk of toxicity. TDM was recommended if applicable and patients should be clinically monitored for adverse reactions to PMB, such as nephrotoxicity and neurotoxicity. An adaptive feedback control algorithm has been reported to optimize the personalization of PMB dosing regimens.34 This algorithm significantly increased the attainment of AUC0–24 values within the target window (>95% vs 71%).

A relatively disappointing CFR was observed in patients infected with Pae, regardless of renal function. Suboptimal PMB monotherapy dosing regimens have yielded relatively low clinical cure rates (57–75%).35,36 Moreover, PMB monotherapy often resulted to the amplification of colistin-resistant subpopulations in heteroresistant strains, especially in Kpn.37 Acquisition of resistance has been reported after PMB therapy.38,39 Although PMB showed promising CFR against carbapenem-resistant Eco, Kpn, and Aba, studies have reported that PMB combination therapy may be required. PMB monotherapy showed excellent simulated results in treating carbapenem-resistant organisms, the combination of PMB with other agents could further prevent the emergence of pan-resistant organisms and improve patient outcomes. A previous meta-analysis indicated that mortality was significantly higher in patients treated with PMB monotherapy than in patients treated with combinations of PMB with tigecycline, Fosfomycin, and aminoglycosides, especially those infected with Kpn BSIs. These findings may be useful in empirically treating patients infected with carbapenem-resistant Gram-negative organisms.

This study had several limitations. First, the PPK model was developed from 462 plasma samples obtained from 37 normal patients and 33 with reduced renal function.18 The rich PK properties of PMB may be not fully evaluated, resulting in a bias in simulating PMB concentration. Second, the MIC of PMB against organisms from China may not be representative of the MIC distributions in other regions of the world. Third, combination regimens are often empirically prescribed for patients infected with carbapenem-resistant or pandrug-resistant organisms. Unfortunately, MCS was inapplicable in these situations.

Conclusions

To our knowledge, this is the largest study to date evaluate the efficacy and safety of PMB dosing regimens in Chinese patients infected with carbapenem-resistant microorganisms. Patients should be administered a loading dose of 2.5 mg/kg, regardless of renal function. This should be followed by a fixed maintenance dose of 60 mg q12h in the empirical treatment of CR-Eco, Kpn, and Aba infections in patients with impaired renal function. By contrast, patients with normal renal function should be administered a weight-based maintenance dose of 1.25 mg/kg PMB. Additional studies are needed to formulate the exact treatment strategies for patients with renal impairment.