Treatment of extended-spectrum β-lactamase-producing Enterobacteriaceae (ESBLs) infections: what have we learned until now?

Clinical question 1: Carbapenems or β-lactam/β-lactamase inhibitor combinations in ESBL-PE infections?

Carbapenems possess the broadest spectrum of β-lactam antibiotics with greatest potency against Gram-negative bacteria and are characterized by stability to hydrolysis by the majority of β-lactamases⁷. Several studies have shown that carbapenem treatment is associated with improved outcomes in patients with severe ESBL-PE infections and remains the “gold standard” treatment for serious and invasive ESBL-PE infections^8,9. Specific considerations among carbapenems are the induction of carbapenem resistance and their side effects, especially as far as their epileptogenic effect is concerned¹⁰. Most studies have evaluated either meropenem or imipenem for the treatment of ESBL-PE, although a recently published multinational retrospective study compared the clinical efficacy of ertapenem with that of other carbapenems in ESBL-PE BSIs¹¹. Cure rates were similar (90.6% with ertapenem and 75.5% with other carbapenems in empiric and 89.8% and 82.6% in targeted treatment), and no differences have been observed for mortality among the two groups, but for patients with severe sepsis a non-significant trend favoring other carbapenems was observed¹¹.

Among β-lactam/β-lactamase inhibitor (BLBLI) combinations, the combination of piperacillin–tazobactam (PTZ) has been extensively studied as an alternative carbapenem-sparing option against ESBL-PE infections¹². In 2012, a meta-analysis compared the mortality rates among carbapenems and alternative regimens, including BLBLIs, for the treatment of ESBL-PE BSIs¹³. According to their results, differences were noticed in mortality rates when administered as either definitive or empirical therapy, although they mentioned one study’s significant heterogeneity¹³. Since the question about the role of BLBLIs remained, six subsequent studies from 2012 to 2017 tried to elucidate the role of BLBLIs against ESBL-PE with rather conflicting results^14–18. These controversies were interpreted by substantial differences among the studies’ design. In particular, the Spanish groups included mainly E. coli as the attributed ESBL-PE, and their studies had lower inoculum infections, ICU admissions, and median PTZ minimum inhibitory concentration (MIC) and higher PTZ treatment dosages compared with the study by Tamma et al.^9,15,18. A further analysis of cases of the Spanish group, conducted by Retamar et al., revealed that all patients who presented with ESBL-PE BSIs from a urinary source had a favorable outcome, irrespectively of the PTZ MIC¹⁹. Furthermore, among patients with an ESBL-PE BSI with a source other than a urinary one, the outcome was dismal when the MIC of the isolate for PTZ was more than 2 mg/L¹⁹. A recently published randomized controlled trial was conducted comparing PTZ, cefepime, and ertapenem for the treatment of ESBL-PE UTIs caused by E. coli²⁰. Based on the results, the clinical and microbiological response to PTZ treatment was estimated to be 94% and was similar to the response to ertapenem treatment. An ongoing retrospective observational study (BICAR) is trying to evaluate the efficacy of BLBLI combinations for the treatment of ESBL-PE BSIs in hematological patients with neutropenia²¹. In addition, a recently published propensity score-weighted multicenter cohort study in Korea showed that, among 232 patients with ESBL-PE BSIs, non-carbapenem regimens were not inferior to carbapenems (30-day mortality rates for non-carbapenems 6.3% versus carbapenems 11.4%)²².

Authors’ recommendations. For invasive, high-inoculum ESBL-PE infections with a source of infection other than E. coli and in critically ill patients, carbapenems remain the “gold standard” of targeted treatment. Especially for ICU patients, according to a recent systematic review, the empirical use of PTZ when high risk of ESBL-PE is suspected should be avoided²³. Definitive therapy with BLBLIs should be selected under specific criteria such as stable condition, after microbial documentation with susceptibility results, in combination with dose and infusion modalities to the MIC in order to reach pharmacological targets²³.

Definite answers concerning the role of BLBLIs (and specifically PTZ) against ESBL-PE BSIs will be given by an ongoing multicenter clinical trial (MERINO trial) comparing PTZ versus carbapenems for the definitive treatment of BSIs caused by ceftriaxone-resistant E. coli and Klebsiella spp.²⁴. Based on the preliminary MERINO results presented at European Congress of Clinical Microbiology & Infectious Diseases 2018, the most common ESBL-PE bacteremia source was the urinary tract (60.9%) with clear predominance of E. coli (86.5%). Although no difference between the two groups regarding subsequent infections of drug-resistant bacteria or C. difficile was reported, the 30-day mortality rate differed (12.3% for PTZ versus 3.7% for meropenem)²⁵. In addition, it is of utmost importance to clearly define in future studies the specific subset of patients with ESBL-PE infections who could benefit from carbapenem-sparing treatments, especially regarding hematological patients with neutropenia²⁶.

Clinical question 2: What is the role of cefepime in treating ESBL-PE infections?

The results from published studies and reviews evaluating the efficacy of cefepime versus carbapenems for the treatment of ESBL-PE infections remain controversial. Few studies have shown comparable efficacy, whereas others reported significant inferiority of cefepime^27–31. Among these studies, Lee et al.³¹ and Wang et al.²⁷ showed significantly lower mortality rates at 30 and 14 days, respectively (17% versus 59% and 41% versus 20%, respectively). In particular, in the study by Lee et al., a significant association was observed between the mortality rates of the patients receiving cefepime and the MIC of the drug. In particular, for cefepime MIC of not more than 1 μg/mL, the mortality rate was 16.7%; for MIC of 2–8 μg/mL, the rates reached 45.5%; while for MIC of at least 16 μg/mL, the rates were 100% (p = 0.035)³¹. Even after propensity score adjustment, cefepime remained inferior compared with carbapenem (adjusted odds ratio 6.8, 95% confidence interval (CI) 1.5–31.2, p = 0.01). A subsequent randomized controlled trial was conducted comparing PTZ, cefepime, and ertapenem for the treatment of ESBL-PE UTIs caused by E. coli showing inferiority of cefepime compared with the other treatment options. The efficacy of cefepime was 33.3% compared with 94% efficacy of PTZ treatment²⁰.

Authors’ recommendations. For serious invasive ESBL-PE infections with high inoculum and lack of source control, cefepime seems to be inferior compared with carbapenems because of two significant issues: increased MICs of the drug because of high inoculum effect and failure to achieve its pharmacodynamic targets in severe ESBL-PE infections. Cefepime could be administered only in non-severe ESBL-PE UTIs, where high drug concentrations could be achieved and when simultaneously low MIC of the drug is reported (MICs ≤2 μg/mL).

Clinical question 3: What is the role for fosfomycin, aminoglycosides, or temocillin in ESBL-PE infections?

Fosfomycin is an old bactericidal antibiotic agent (phosphonic compound) with a unique mode of action of inhibiting bacterial cell wall biosynthesis^32,33. A recently published literature review concerning the susceptibility of contemporary Gram-negative bacteria revealed that, for ESBL-producing E. coli, susceptibilities ranged from 81% to 100% and, for ESBL-producing K. pneumoniae, from 15% to 100%³⁴. Owing to its low molecular weight, its hydrophilicity, and its negligible serum protein binding, the drug achieves good tissue penetration and high concentrations in the serum, soft tissue, lungs, bone, cerebrospinal fluid, and heart valves^35,36. Especially for the urinary tract, the drug achieves high concentrations for a prolonged period of time. Finally, in critically ill patients, a significant increase of fosfomycin volume of distribution is observed; therefore, the current paucity of data on fosfomycin in critically ill patients prevents accurate dosing guidance³⁶. Clinical data concerning the efficacy of intravenous fosfomycin against ESBL-PE invasive infections are very limited and focus mainly on UTI treatment^32,37–42. A randomized clinical trial (“FOREST”) comparing the safety and efficacy of fosfomycin versus meropenem in bacteremic UTIs caused by ESBL-producing E. coli is ongoing³⁸. Fosfomycin as monotherapy for the treatment of multidrug-resistant organism (MDRO)-associated invasive infections is limited by the emergence of drug resistance to fosfomycin during treatment³⁹. A more recently published meta-analysis conducted by Grabein et al. tried to summarize the current clinical evidence of intravenous fosfomycin in 128 studies⁴³. According to their results, the drug showed comparable clinical or microbiological efficacy compared with other antibiotics when used for sepsis/bacteremia, urinary tract, respiratory tract, bone and joint, and central nervous system infections⁴³. The pooled estimate for resistance development during fosfomycin monotherapy was 3.4% (95% CI 1.8%–5.1%).

Up-to-date data concerning the role of aminoglycosides in combating MDRO infections showed that for ESBL infections they can be used as part of a combination regimen, especially for UTIs and intra-abdominal infections (IAIs), as a carbapenem-sparing option⁸. An in vitro synergistic effect has been confirmed for the concomitant administration of aminoglycosides plus β-lactams, while the monotherapy is not generally recommended for ESBL-PE infections, except for ESBL-PE non-bacteremic UTIs, mainly owing to the high risk of resistance development^44–47. Among newer aminoglycosides, plazomicin (formerly ACHN-490), a next-generation aminoglycoside synthetically derived from sisomicin, is recently gaining more attention against MDRO infections^47,48. The unique characteristic of plazomicin is its resistance to inactivation by aminoglycoside-modifying enzymes compared with other agents of the same group^47,48. However, plazomicin is not active against bacterial isolates expressing ribosomal methyltransferases^47,48. In two studies, plazomicin has been shown to be more potent than other aminoglycosides in treating Enterobacteriaceae^49,50.

Temocillin is a β-lactamase-resistant carboxypenicillin active against both ESBL-PE and AmpC-producing Enterobacteriaceae and with limited activity against Pseudomonas, Acinetobacter spp., and anaerobic bacteria. Although this carbapenem-sparing drug option is licensed in only a few European countries (UK and Belgium), data from a multicenter study in the UK among 92 infection episodes (42 BSIs) treated with temocillin showed promising results⁵¹. In particular, both clinical and microbiological cure rates were reported to be 86% and 84%⁵¹. In addition, a prospective randomized controlled trial conducted in Belgium in 2014 showed that for critically ill patients the optimal dose regimen for temocillin in order to achieve its pharmacological targets with longer free-serum concentrations is 2 g three times a day administered by continuous infusion⁵².

Authors’ recommendations. Fosfomycin is strongly suggested for ESBL-PE UTIs and as a step-down therapy in source-controlled ESBL-PE infections. A randomized clinical trial (“FOREST”) comparing the safety and efficacy of fosfomycin versus meropenem in bacteremic UTIs caused by ESBL-producing E. coli is ongoing⁴¹. Other options of source-controlled ESBL-PE UTIs are aminoglycosides, especially for cystitis infections. In addition, they can be used as part of a combination regimen, especially for UTIs and IAIs, as a carbapenem-sparing option⁸. For temocillin, larger clinical studies among different patient groups are needed in order to establish their role as a valuable carbapenem-sparing option against ESBL-PE BSIs.

Clinical question 4: What is the role of the newly approved drugs against ESBL-PE infections?

In Table 2, some of the new drugs active against multidrug-resistant bacteria, including ESBL-producing ones, are reported. Among newer BLBLIs developed, two of them—ceftazidime–avibactam and ceftolozane–tazobactam—have already received US Food and Drug Administration (FDA) approval and therefore will be discussed further.

Ceftazidime–avibactam is a combination of cephalosporin with a new non-BLBLI that is generally active against Enterobacteriaceae and P. aeruginosa producing class A β-lactamases (ESBLs and KPCs) and class C β-lactamases (AmpCs) and some Enterobacteriaceae producing class D β-lactamases (OXAs) but lacks activity against class B carbapenemases and is less active against anaerobes compared with other BLBLIs. A phase 3 trial (RECLAIM 1 and RECLAIM 2) conducted by Mazuski et al. evaluated the efficacy of ceftazidime–avibactam in treating complicated IAI (cIAI), revealing non-inferiority of the tested combination drug and similar clinical cure rates of 81.6% versus 85.1%, respectively⁵³. A subsequent phase 3 (REPRISE) study by Carmeli et al. recently published the results of the efficacy of ceftazidime–avibactam—2 to 0.5 g intravenously every 8 hours (q8h)—versus the best available therapy both for complicated UTI or cIAI due to ceftazidime-resistant Enterobacteriaceae or P. aeruginosa with similar clinical cure rates⁵⁴. Finally, in 2015, the drug was approved by the FDA for complicated UTIs and cIAI with a recommended dosage of 2 g/0.5 g) 8 hourly for 7 days for UTIs and 4 to 14 days for IAIs with dose adjustment in renal insufficiency. An ongoing clinical trial is evaluating the safety and efficacy profile of the drug for nosocomial pneumonia⁵⁵.

Ceftolozane–tazobactam is a co-formulation of a novel cephalosporin with an old β-lactamase inhibitor. Ceftolozane is a new cephalosporin based on the scaffold of ceftazidime—with only one modification of the side chain at the 3-position of the cephem nucleus—with improved activity against multidrug-resistant Pseudomonas spp. Ceftolozane, like other oxyimino-cephalosporins such as ceftazidime and ceftriaxone, is not stable against class A, B, or D β-lactamases (mainly ESBLs or carbapenemases). The combination with tazobactam significantly broadens its spectrum against ESBL-PE and against few anaerobes^56,57. In 2014, the FDA approved the administration of the combination drug for the treatment of complicated UTIs and cIAIs based on previously published clinical trials (ASPECT trials)^58–60. In particular, the drug was evaluated in phase 3 non-inferiority clinical trials versus levofloxacin 750 mg daily in complicated UTI or meropenem 1 g q8h in cIAI. The UTI trial compared ceftolozane 1,000 mg q8h versus ceftazidime 1,000 mg q8h, including pyelonephritis, and demonstrated similar microbiologic and clinical outcomes, as well as a similar incidence of adverse effects after 7 to 10 days of treatment, respectively. The second cIAI trial has been conducted comparing ceftolozane–tazobactam 1,000/500 mg and metronidazole 500 mg q8h versus meropenem 1,000 mg q8h in the treatment of cIAI. The recommended FDA dosage is 1 g/0.5 g 8 hourly for 7 days in complicated UTIs and 4 to 14 days in cIAIs, respectively⁶¹.