Multidrug Resistant Gram-Negative Bacteria in Community-Acquired Pneumonia

Community-acquired pneumonia (CAP) is associated with high morbidity and mortality worldwide [1]. Although several different bacteria and respiratory viruses can be responsible for CAP, Streptococcus pneumoniae (pneumococcus) remains the most common causative pathogen. A small proportion of CAP cases are caused by Gram-negative bacteria, especially Pseudomonas aeruginosa, Klebsiella pneumoniae, Acinetobacter baumannii and Stenotrophomona maltophilia [2, 3]. The main problem concerning the treatment of Gram-negative bacterial infections is their related antibiotic resistance, reported as multidrug resistant (MDR = resistant to at least one agent in three or more groups of antibiotics), extensively drug resistant (XDR = resistant to at least one agent in all but two or fewer groups of antibiotics) and pan-drug resistant (PDR = resistant to all groups of antibiotics) [4]. This makes the clinical management of pneumonia caused by such pathogens a challenge for physicians. Taking into account the clinical severity that may be associated with CAP caused by Gram-negative bacteria (respiratory failure, bacteremia, shock, acute respiratory distress syndrome [ARDS]) the magnitude of the global health problem is tremendous.

We are currently living through an antibiotic resistance crisis, mainly because antibiotics tend to lose their efficacy over time due to the emergence and dissemination of resistance among bacterial pathogens, principally caused by the overuse and inappropriate use of antibiotics, as well as the extensive use of antibiotics in agriculture and the food industry. The Global Point Prevalence Survey (Global-PPS), an international network set up to measure antimicrobial prescription and resistance in the hospital setting, recently published its findings [5]. Pneumonia was the most common illness to receive antibiotic therapy worldwide, accounting for 19% of patients treated. The most frequently prescribed antibiotics for community-acquired infections were penicillins with a β-lactamase inhibitor (29%); amoxicillin with a β-lactamase inhibitor accounted for 16% and piperacillin with a β-lactamase inhibitor accounted for 8%. Third-generation cephalosporins were the second most commonly prescribed antibiotics for community-acquired infections (mainly ceftriaxone, 16%), followed by fluoroquinolones (14%).

Antibiotic resistance is a natural phenomenon in bacteria that cannot be stopped; however various measures can be taken in order to reduce the rate of its development and devise more effective strategies to control its spread [6].

Because CAP caused by MDR Gram-negative bacteria is an important clinical concern, we review the main findings concerning the epidemiology, diagnosis and clinical impact of CAP.

The reference microbiological diagnostic tools for bacteria causing respiratory tract infections remain the Gram stain and semi-quantitative conventional cultures from direct respiratory samples. Bacterial identification is currently based on matrix-assisted latex laser desorption/ionization time-of-flight mass spectrometry (MALDI-TOF MS) and susceptibility testing. As a consequence of the time needed for microbiological diagnosis, many patients initially receive inappropriate antibiotic treatment, which may increase morbidity and mortality.

Molecular techniques based on multiplex PCR have also been developed in recent years in order to simultaneously identify and quantify multiple respiratory pathogens from different types of samples in a single procedure [47]. However, the main challenge for the rapid diagnosis of respiratory infections is the early detection of the antibiotic resistance profile of the various bacteria. The biggest obstacle in the use of molecular techniques for detecting resistance is the discrepancy between genotype and phenotype, the continuous discovery of new resistance mechanisms and, as a result, the potential presence of unknown mechanisms, which may lead to false negative results using molecular techniques [47].

Recognizing patients at risk of colonization with MDR Gram-negative bacteria, such as patients with bronchiectasis or COPD (frequently colonized by P. aeruginosa), is essential, since several studies have reported the association between previous colonization and risk of pneumonia [48, 49].

Currently, there is no specific score to predict MDR Gram-negative pathogens in CAP. However, several scoring systems have been proposed to identify patients with risk factors for developing CAP caused by MDR pathogens. The Aliberti score [2] takes into account different variables and gives a specific score to each of them: chronic renal failure (5 points), prior hospitalization (4 points), nursing home residence (3 points) and other variables (0.5 points each). CAP patients with an Aliberti score ≥ 3 points have a reported prevalence of MDR of 38%, whereas CAP patients with an Aliberti score of ≤0.5 have a reported prevalence of MDR of 8%. The PES (P. aeruginosa, Enterobacteriaceae ESBL-positive, methicillin-resistant S. aureus [MRSA]) score includes 1 point each for age 40–65 years and male sex; 2 points each for age > 65 years, previous antibiotic use, chronic respiratory disorder, and impaired consciousness; 3 points for chronic renal failure; and minus 1 point if fever is present initially. The risk of MDR pathogens is higher with 5 points or more [50]. Unfortunately, studies validating the Aliberti and PES score do not include immunocompromised patients. The ability of these scores to identify risk factors for CAP by MDR pathogens in this population is still unclear.

An important study by Shindo et al. [51] investigated the main risk factors for MDR pathogens in 1413 patients with CAP. Six risk factors were identified: prior hospitalization, immunosuppression, previous antibiotic use, use of gastric acid-suppressive agents, tube feeding and non-ambulatory status. Unlike the Aliberti and PES studies, Shindo’s study included immunocompromised patients. Interestingly, the authors analyzed risk factors for Gram-positive (MRSA) and Gram-negative pathogens separately. The authors observed that the risk of MDR Gram-negative pathogens did not increase in the presence of ≥3 risk factors; conversely, for Gram-positive (MRSA) pathogens, the risk increased in the presence of ≥2 risk factors, especially if one of the risk factors was specific for MRSA, such as previous colonization or previous hospitalization.

Since antibiotic treatment for P. aeruginosa is completely different from standard therapy to cover the most common pathogens in CAP, current international guidelines for severe CAP stratify therapy recommendations on the basis of P. aeruginosa risk factors [1]. MDR P. aeruginosa should be covered only in cases that are strongly suspected because of concurrent risk factors. It is important to underline that prior antibiotic therapy has been reported as the only risk factor for MDR P. aeruginosa in CAP patients [11].

Because CAP caused by A. baumannii has a fulminant clinical presentation with a high mortality rate (approximately 50%), greater attention should be paid in elderly patients with multi-comorbidities, and patients with alcohol abuse, chronic lung disease and prior antibiotic therapy, especially in Asian countries where this pathogen is frequently reported. Early appropriate antimicrobial therapy is critical. Recommended empirical antibiotic therapy for A. baumannii CAP includes anti-pseudomonal penicillins, aminoglycoside, ciprofloxacin, and imipenem. Tigecycline, colistin, ceftazidime, doxycycline, minocycline, piperacillin/tazobactam, tobramycin, rifampin, fosfomycin and levofloxacin are active against variable percentages of strains. The treatment should include an association of two or more of these antibiotics according to the antibiogram of the isolated pathogen. Moreover some countries, notably Asia [52] and Australia [53], have implemented specific antibiotic recommendations in cases of severe CAP in order to cover pathogens such as A. baumannii.

In CAP caused by K. pneumoniae, depending on the clinical severity and the risk of infection by a strain with resistance mechanisms (production of ESBLs, cefaminases or carbapenemases), a 3rd generation cephalosporin (cefotaxime or ceftriaxone) or a fluoroquinolone (ciprofloxacin or levofloxacin) should be used. Another possibility, in case of infection by carbapenemase-producing or carbapenem-resistant strains (due to loss of porin and hyperproduction of Amp-C), is the use of associations of two or three of the following antibiotics: colistin, tigecycline, fosfomycin (if the strain is sensitive), an aminoglycoside (amikacin or gentamicin) and meropenem (if the minimum inhibitory concentration [MIC] = 16 mg/L), administered in high doses and by continuous perfusion. Hypervirulent strains (serotypes K1 and K2) are usually more sensitive to antibiotics, but production of K. pneumoniae-type carbapenemase has also been observed.

Figure 1 proposes an algorithm for the empiric antibiotic therapy of CAP in patients with risks factors for MDR pathogens.

Correct identification of CAP patients suspected of being infected with MDR Gram-negative pathogens is crucial. Specific risk factors, local ecology and resistance patterns should always be considered in order to determine the adequate empirical antibiotic therapy. Early hemodynamic and respiratory support is critical in these patients since the majority of cases of pneumonia may become fulminant systemic disease with both respiratory failure and multiple organ dysfunction.

The collaboration of a multidisciplinary team (critical care specialists, pneumologist, infectious disease specialists, microbiologists) improves management of the most severe cases. The role of the microbiology laboratory, in particular, is of pivotal importance to determine the antimicrobial susceptibility pattern of the pathogen causing CAP, so that appropriate antibiotic therapy can be initiated as soon as possible, avoiding excessive use of broad spectrum antimicrobials, which increase the selection of resistant pathogens.