Research ArticleOriginal Article
Open Access

Comparison of bacteremic pneumonia caused by Escherichia coli and Klebsiella pneumoniae

A retrospective study

Fuxing Li, Junqi Zhu, Yunwei Zheng, Youling Fang, Longhua Hu and Jianqiu Xiong
Saudi Medical Journal March 2024, 45 (3) 241-251; DOI: https://doi.org/10.15537/smj.2024.45.3.20230428

Abstract

Objectives: To compare the prognosis of bacteremic pneumonia caused by Klebsiella pneumoniae (K. pneumoniae) and Escherichia coli (E. coli) pathogens.

Methods: A retrospective analysis was carried out on the clinical data of 162 patients who were diagnosed with bacterial pneumonia caused by either K. pneumoniae or E. coli between 2016-2019. The primary outcome of the analysis was the patients’ 30-day mortality rate.

Results: There were 82 patients in the E. coli bacteremic pneumonia (E. coli-BP) group and 80 patients in the K. pneumoniae bacteremic pneumonia (KP-BP) group. The 30-day mortality rate was 43.75% (n=35/80) in the KP-BP group and 21.95% (n=18/82) in the E. coli-BP group (p<0.001). Following the adjustment for confounding variables in 4 distinct models, the hazard ratios for the primary outcome in KP-BP were determined to be 0.70 (95% confidence interval [CI]: [0.44-1.02]) in Model 1, 0.72 (95% CI: [0.46-1.14]) in Model 2, 0.99 (95% CI: [0.57-1.73]) in Model 3, and 1.22 (95% CI: [0.69-2.18]) in Model 4.

Conclusion: Patients diagnosed with KP-BP exhibited a similar prognosis as those diagnosed with E. coli-BP. For patients with KP-BP, the risk of mortality was significantly higher for those who were in the intensive care unit, were infected with carbapenem-resistant strains, or had a high sequential organ failure assessment score. In patients with E. coli-BP, the Pitt bacteremia score was strongly associated with the 30-day mortality rate.

Keywords:

The global morbidity and mortality of community-acquired pneumonia (CAP) significantly affect the public health systems worldwide.1 Nosocomial pneumonia, inclusive of hospital-acquired pneumonia (HAP) and ventilator-associated pneumonia (VAP), is the predominant form of iatrogenic infection.2 While pneumonia is primarily caused by Gram-positive bacteria, the incidence of Gram-negative bacteria-induced pneumonia is steadily increasing.3,4

Klebsiella pneumoniae (K. pneumoniae) is the main cause of CAP, HAP, and VAP, such that K. pneumoniae has led to a relatively large number of cases (15.4%) of CAP in Asia.5-7 In recent years, there has been an increasing incidence of carbapenem-resistant K. pneumoniae (CRKP), thereby posing a substantial concern in public health.8 Escherichia coli (E. coli) is derived from the Enterobacteriaceae family and is the second most prevalent bacterial cause of bacteremic pneumonia in the United States.9 A comprehensive study revealed that E. coli constituted approximately 8% of culture-positive bacterial CAP cases.10

Recently, the emergence of multidrug-resistant Gram-negative bacteria has emerged as a significant concern, particularly among individuals receiving hospital care. Consequently, an increasing body of research has been dedicated to examining the epidemiology, risk factors, and clinical outcomes associated with pneumonia caused by Gram-negative bacteria. Although some studies have characterized pneumonia caused by these 2 pathogens individually, it was observed that hospital-acquired bacteremic pneumonia (HABP) attributed to K. pneumoniae exhibited a markedly elevated mortality rate in comparison to E. coli.7,10-12 However, comprehensive comparative studies are still lacking. Hence, a study was carried out to analyze the characteristics of patients with K. pneumoniae bacteremic pneumonia (KP-BP) and those with E. coli bacteremic pneumonia (E. coli-BP) to compare the outcomes and to identify the predictors of the 30-day mortality rate in the 2 groups, which complemented a previous small cohort study.12

Methods

A comprehensive retrospective cohort study was carried out at the Affiliated Hospital of Nanchang University, Jiangxi, China, a tertiary healthcare facility with a bed capacity of 2400. The study focused on various factors and outcomes related to bacteremic pneumonia caused by K. pneumoniae and E. coli. Enrollment was limited to patients admitted to the hospital between January 2016 and December 2019, and these patients had to be diagnosed with a specific type of pneumonia. Based on the consensus criteria, patients exhibiting typical signs and symptoms of pneumonia along with a demonstrable infiltrate were diagnosed with pneumonia.13,14 Blood samples were obtained from adult patients aged 18 years old or older within 24 hours of being diagnosed with pneumonia. The inclusion criteria for the study required patients to have at least one positive blood culture for K. pneumoniae or E. coli. Exclusion from the study included deaths occurring within 48 hours of admission, polymicrobial infections, pregnant women, patients with incomplete data, and infections other than pneumonia (Figure 1). In patients with multiple episodes of KP-BP or E. coli-BP during hospitalization, only the first episode was considered. The present study was approved by the research ethics committee of the Second Affiliated Hospital of Nanchang University, Jiangxi, China. Given the retrospective nature of the study, the requirement for informed consent was waived.

Figure 1
Figure 1

- Flow chart of patients selected. K. pneumoniae: Klebsiella pneumoniae, E. coli: Escherichia coli.

Community-acquired pneumonia was defined as the contraction of community-onset pneumonia within 48 hours of hospitalization. The diagnostic criteria for CAP included the presence of the following symptoms: i) the manifestation of a recently acquired cough, production of sputum, or deterioration of pre-existing respiratory symptoms, accompanied by or without the presence of purulent sputum, chest discomfort, difficulty in breathing, and coughing up blood; ii) fever; iii) evidence of pulmonary solid lesions or audible wet rhonchi; iv) peripheral blood leukocyte counts exceeding 10 x 109/L or falling below 4 x 109/L, with or without the presence of immature white blood cells; v) chest imaging demonstrates the identification of emerging patchy infiltrative shadows, lobar or segmental solid shadows, ground glass shadows, or interstitial changes, with or without the presence of pleural effusion.13 In contrast, HAP was diagnosed if it occurred after 48 hours of hospitalization (including VAP).14 The determination of sepsis was established according to the diagnostic criteria outlined in Sepsis-3, a publication by the American Society of Critical Care Medicine (SCCM)/European Society of Critical Care Medicine (ESICM) from 2016.15 These criteria encompassed 2 key components: i) the detection or existence of an infection and ii) a sequential organ failure assessment (SOFA) score equal to or exceeding 2. Polymicrobial infection was defined as 2 or more bacterial species in respiratory or blood cultures collected within 48 hours of admission. Immunosuppression was defined to include various forms, such as the administration of oral steroids or other immune system-suppressing medications, organ transplantation, the presence of HIV infection, and chemotherapy for cancer.16 If the chosen antibiotic displayed no efficacy against the isolated strain in the laboratory test, antibiotic treatment was deemed ineffective. Empirical therapy was defined as antimicrobial treatment administered before drug susceptibility testing. Appropriate empirical therapy referred to an active agent that was started within 24 hours of pneumonia diagnosis, while inappropriate therapy was defined as antibiotic treatment without any active agent. Failure of antimicrobial therapy was characterized by the persistence or progression of signs and symptoms of infection. The primary outcome chosen for this study was the mortality rate within 30 days.

The hospital information system (HIS) and laboratory information system (LIS) were used to collect clinical data and laboratory results. The collected data included the following: i) demographics, such as age and gender; ii) type of pneumonia (community-acquired or nosocomial); iii) department of hospitalization (namely, Internal Medicine Department); iv) invasive procedures (surgery, tracheotomy, and trachea cannula); v) bacterial type (extended-spectrum β-lactamases [ESBL]-producing strains, carbapenemase-resistant strains, and others); vi) underlying disease (immunocompromisation, cerebral vascular disease, hypertension, and others); vii) laboratory values, including C-reaction protein (CRP; BC-5390, Shenzhen, China) and procalcitonin (PCT; Burgess Hill, Roche Diagnostic, UK); viii) illness severity; ix) the strategy for antibiotic use and clinical outcomes; and x) the test outcomes for drug sensitivity. The comorbidity was assessed using the age-adjusted Charlson comorbidity index (aCCI) on the day of admission, while disease severity upon admission was evaluated through the SOFA and Pitt bacteremia scores.

Bacterial identification was carried out using the VITEK® 2 system (Bio-Merieux, Inc., France) or the matrix-assisted laser desorption/ionization time-of-flight mass spectrometry (MALDI-TOF/MS) system (bioMérieux, Germany). Antibiotic susceptibility testing of the isolates was carried out using a Kirby-Bauer test (HD-L100, Xiamen, China) and the Vitek 2 compact system. Additionally, minimal inhibitory concentrations (MICs) were determined through microdilution testing following the criteria established by the Clinical and Laboratory Standards Institute (CLSI), and ESBL production was detected using the combined disc method (ceftriaxone alone and ceftriaxone-clavulan).17

Statistical analysis

Data that followed a normal distribution were reported as mean ± standard deviation (SD). Data that deviated from a normal distribution were reported as the median and interquartile range (IQR). One-way analysis of variance was carried out to compare normally distributed data. Alternative statistical methods were employed if the data did not conform to a normal distribution, such as the Mann-Whitney-U test. Count data were presented as numbers and precentages (%), while group comparisons were analyzed using either the Chi-square test or Fisher’s exact test. Furthermore, the study carried out by KP-BP utilized the Cox proportional hazards model to assess the 30-day mortality rate. The analysis involved calculating hazard ratios (HR) and 95% confidence intervals (CI). These estimated HR and CI were employed to evaluate the influence of different factors on the 30-day mortality rate. To mitigate the impact of confounding factors, this study established 4 distinct modules. Model 1 was adjusted for demographic factors such as age and gender, as well as variables related to the inpatient department and invasive procedures. Model 2 included additional adjustments for bacterial type, while Model 3 further accounted for underlying diseases and severity scores. In contrast, Model 4 incorporated adjustments for specific empiric therapies and treatment outcomes. Lastly, the risk factors for the 30-day mortality rate in patients with KP-BP and E. coli-BP were assessed using univariate and multivariate Cox regression analyses. Variables with a p-value of <0.10 in univariate analysis were included in the multivariate analysis.

The Statistical Package for the Social Sciences, version 25.0 (IBM Corp., Armonk, NY, USA) was used for statistical analysis. A p-value of <0.05 was considered significant.

Results

A comprehensive study carried out over 48 months included a total of 162 patients diagnosed with bacteremic pneumonia. Among these patients, 80 (49.4%) were identified as KP-BP patients, while the remaining 82 (50.6%) were classified as E. coli-BP patients (Figure 1). In this study, sputum cultures were not established. The collected patient information included their demographic and clinical features (Table 1). The 162 patients included 95 (58.6%) men and 67 (41.4%) women with a mean age of 60.97±16.15 years, and hospital-acquired pneumonia was found in 72.22% of patients. A total of 53 (32.7%) isolates produced ESBLs, and 30 (18.5%) were resistant to carbapenem antibiotics. The median aCCI score was 4 (IQR: 2-5). Most of the patients included in this study were severe cases with a median SOFA score of 5 (IQR: 3-8), and 122 (75.31%) patients had sepsis during hospitalization. Empiric carbapenem therapy was initiated in 64 (39.5%) patients. A total of 49 (30.3%) patients received at least 3 antibiotics during their hospitalization, and 32.72% of patients received inappropriate empirical treatment. The 30-day mortality rate was 32.7% for all patients. Most patients with E. coli-BP were primarily admitted to the surgical department, had ESBL-producing strains, and received empiric third-generation cephalosporin therapy. Furthermore, a lower proportion of E. coli-BP patients were male, admitted to the ICU, received an indwelling urinary catheter, tracheotomy, trachea cannula, had carbapenemase-resistant strains, diabetes mellitus, sepsis, and received empiric carbapenem therapy. The Pitt and SOFA scores were significantly higher in KP-BP patients than in E. coli-BP patients (p<0.05). Compared with the E. coli-BP group, higher 14-day treatment failure and 30-day mortality rates were observed in the KP-BP group (p<0.05).

View this table:
Table 1

- Clinical characteristics of patients with Klebsiella pneumoniae and Escherichia coli bacteremic pneumonia.

Drug susceptibility was tested for 80 isolates of K. pneumoniae and 82 isolates of E. coli (Table 2). Escherichia coli-BP isolates exhibited higher susceptibility rates for amikacin, aztreonam, cefoxitin, cefixime, imipenem, and piperacillin than KP-BP isolates, but the susceptibility rate for levofloxacin was lower (p<0.05).

View this table:
Table 2

- Antimicrobial resistance of Klebsiella pneumoniae and Escherichia coli isolated from 2 groups.

The study observed a 30-day mortality rate of 43.75% (n=35/80) in the KP-BP group, which was significantly higher compared to the 21.95% (n=18/82) mortality rate in the E. coli-BP group (p=0.003). To evaluate potential predictors of 30-day mortality in both groups, 4 multivariate Cox regression models were developed (Table 3). After adjustments for demographic factors (namely, age and gender) and other variables (namely, inpatient department and invasive procedures), the HR for the 30-day mortality rate of KP-BP to E. coli-BP was reported to be 0.70 (95% CI: [0.44-1.02], p=0.059; Model i). Additional analyses were carried out to account for the type of bacteria involved, and the HR remained statistically insignificant (HR=0.72, 95% CI: [0.46-1.14], p=0.163; Model ii). Furthermore, similar findings were observed after adjustments for underlying diseases (such as cerebral vascular disease and diabetes mellitus) and scores related to severity of illness (Pitt score and SOFA score) (HR=0.99, 95% CI: [0.57-1.73], p=0.975; Model iii), as well as after further adjustments for empiric therapy (namely, third-generation cephalosporins and carbapenems) and 14-day treatment failure (HR=1.22, 95% CI: [0.69-2.18], p=0.493; Model 4).

View this table:
Table 3

- Hazard ratio for 30-day mortality according to Klebsiella pneumoniae bacteremic pneumonia and Escherichia coli bacteremic pneumonia.

The baseline clinical characteristics of the survival and non-survival groups are displayed in Table 4. Additionally, univariable and multivariable Cox regression analyses were carried out to ascertain the risk factors for 30-day mortality (Table 5). In the KP-BP group, univariate analysis revealed that factors such as ICU stay, venous catheterization, tracheotomy, trachea cannula, carbapenem-resistant strains, Pitt score, SOFA score, and inappropriate empirical therapy were significantly associated with an increased 30-day mortality rate. The multivariate Cox regression analysis revealed that ICU stay (adjusted HR=2.88, 95% CI: [1.42-5.82], p=0.003), carbapenem-resistant strains (adjusted HR=2.61, 95% CI: [1.28-5.32], p=0.008), and SOFA score (adjusted HR=1.16, 95% CI: [1.09-1.25], p<0.001) were identified as independent predictors of the 30-day mortality rate in patients with KP-BP (Table 5).

View this table:
Table 4

- Characteristics of 30-day survivors and non-survivors.

View this table:
Table 5

- Risk factors for 30-day mortality in patients with Klebsiella pneumoniae and Escherichia coli bacteremic pneumonia.

In the E. coli-BP group, univariate analysis revealed a significant association between tracheotomy, trachea cannula, sepsis, Pitt score, and SOFA score with an increased 30-day mortality rate. However, multivariate analysis revealed that only the Pitt score remained a significant risk factor for the 30-day mortality rate (adjusted HR=1.99, 95% CI: [1.49-2.65], p<0.001; Table 5).

Discussion

This study analyzed the clinical characteristics and antimicrobial susceptibility of KP-BP and E. coli-BP between January 2016 and December 2019. The 2 groups demonstrated several differences, revealing that men were more at risk of K. pneumoniae pneumonia than women. Epidemiological studies indicate that KP pneumonia is more common in middle-aged and old men. Similar results were obtained by Chen et al.7 However, the gender discrepancy might be explained by the relatively small number of cases. Compared with E. coli-BP, patients with KP-BP had a more severe primary condition, higher rates of ICU admission, invasive procedures, and carbapenem resistance. Overall, patients with KP-BP had a higher 30-day mortality rate (43.75% vs. 21.95%, p=0.003) than E. coli-BP patients.

Escherichia coli and K. pneumoniae are prevalent Enterobacteriaceae causing pneumonia in hospital and community settings. Their high morbidity and mortality rates have gained the attention of clinicians worldwide.17-19 In 2 studies of liver abscesses caused by K. pneumoniae and E. coli, investigators reported significantly higher Pitt bacteremia scores and disease severity in K. pneumoniae infection than in the E. coli group, supporting the results of our study.20,21 Another study revealed that ESBL-producing K. pneumoniae was associated with a significantly higher 30-day mortality rate than ESBL-producing E. coli (33.7% vs. 17.4%). The results of the present study further supported the conclusion.22

Patients with E. coli-BP were used as a reference to identify the risk factors for the 30-day mortality rate in KP-BP. After adjustments for various confounding factors such as age and gender, ward admission, and invasive procedures, there was no significant disparity observed in the risk of mortality within 30 days between the 2 cohorts (Model 1; HR=0.70, p=0.059). Equivalent results were obtained after adjustments for additional confounders (Models 2, 3, and 4). This finding was consistent with a previous study, which also reported no significant difference in mortality between E. coli and K. pneumoniae pneumonia.10 Although statistically nonsignificant, the 30-day mortality risk was consistently higher in KP-BP patients (Model 4; HR=1.22, p=0.493). Another study reported that the type of bacteria is one of the most important determinants of the risk of death from bloodstream infection.22 The host and disease severity can significantly affect the outcome of patients with bacteremic pneumonia. Baseline data indicated that patients with KP-BP had a more severe underlying condition. The high rate of carbapenem resistance increased the 30-day mortality risk, which provided a reasonable explanation for this trend. Nevertheless, due to the small sample size of our study, PSM analysis was not carried out, and only crude mortality rates were analyzed in the 2 groups. Therefore, further analysis is required to validate our findings.

The 30-day mortality rate of the KP-BP group in this study was 43.75%, which was lower than previously reported in another study (55.1%) but higher than another study (36.5%).7,23 The high mortality rate suggests that KP-BP is a serious threat to human health and should be prioritized clinically. With the widespread use of antibiotics, carbapenem-resistant Enterobacteriaceae (CRE) is increasingly prevalent. Its multi-drug resistance, rapid spread of resistance, high morbidity and mortality rates, and the limited clinical availability of antimicrobial drugs pose a serious challenge to clinical management. Klebsiella pneumoniae is the main causative agent of CRE bloodstream infections (85.6%, n=178/208).24 Moreover, the present study unveiled a significantly elevated prevalence of carbapenem resistance, amounting to 36.25% of patients. These results were consistent with a prior inquiry in Taiwan, which documented an even more pronounced rate of carbapenem resistance (58.2%).7 Current evidence suggests that tigecycline is effective in treating CRE, but it is limited by its low blood drug concentration.25 Polymyxin is another effective treatment for CRE but is limited by heterogeneous drug resistance, complex dose calculations, and nephrotoxicity.26,27 Ceftazidime/avibactam (CAZ/AVI) is a combination of a third-generation cephalosporin and the novel non-β-lactam β-lactamase inhibitor, avibactam. The combination reported excellent antibacterial activity against multi-drug resistant bacteria and has become an option for the treatment of CRE infections in recent years, which has led to an increasing rate of drug resistance.28,29 Consequently, CRE treatment should account for the patient’s medication history, underlying disease, drug resistance, organ function, and other conditions. Sensitive drugs should be selected to deliver accurate and targeted treatment. More importantly, existing antibacterial drugs should be used rationally to minimize the emergence of drug-resistant bacteria. In line with other research, the current study found that inappropriate empirical treatment increased the risk of death (HR=2.35, p=0.014).30 Hence, appropriate antibiotics should be administered in conjunction with the patient’s drug-sensitivity results to minimize the risk of death. However, the statistical analysis did not reveal a significant difference in the time interval between the administration of inappropriate empirical antibiotics and appropriate definitive antibiotics among K. pneumoniae and E. coli groups (p>0.05). This lack of significance might be attributed to the limited sample size of the present study, necessitating further validation through larger datasets and multicenter studies. In addition, ICU admission and higher SOFA scores are predictors of increased 30-day mortality risk, which were confirmed by numerous studies.31,32 Although carbapenem-resistant strains were highly correlated with the 30-day mortality rate, the genotypes and phenotypes of resistant strains were not determined in this study, thereby requiring further research.

In another study, patients with E. coli-BP exhibited a 30-day mortality rate of 21.95%.10 In the present study, more than 30% of the E. coli samples were resistant to quinolones, and many previous studies have reported increasing resistance to quinolone antibiotics.33 Nevertheless, our study displayed that E. coli isolates were highly susceptible to amikacin and piperacillin, which could be used as first-line empirical therapy. Notably, a high proportion of ESBL-producing E. coli was observed in nosocomial infections (50.88%). This could be attributed to the patients having more severe conditions, comorbid cardiovascular and cerebrovascular diseases, ICU admission, or undergoing invasive operations. These are risk factors for multidrug-resistant Enterobacteriaceae bacterial infection.6,34 Moreover, effective medications are challenged by the notable prevalence of ESBL-producing E. coli. Although the proportion of E. coli exhibiting resistance to carbapenem antibiotics was found to be low in this investigation, it should be noted that 28.5% of patients were administered carbapenem antibiotics before obtaining drug sensitivity results, thereby facilitating the development of carbapenem-resistant strains. Consequently, using such antibiotics should be approached cautiously following the recommended indications for carbapenem antibiotics. The Pitt bacteremia scores serve as a biomarker for evaluating the gravity of illness and the likelihood of mortality in individuals afflicted with bloodstream infections caused by both Gram-negative and Gram-positive bacteria. Typically, elevated scores indicate a critical state and an unfavorable prognosis for the patient.35,36 In this study, higher Pitt bacteremia scores were significantly associated with an increased risk of 30-day mortality in cases of E. coli-BP, thereby establishing Pitt bacteremia scores as an independent risk factor. Although Pitt bacteremia and SOFA scores were relatively similar, the present study found no difference in SOFA scores in E. coli-BP, which could be related to the single-center, small sample size of the present study. Therefore, further validation is required in a large-scale prospective clinical trial.

Study limitations

Despite the prospective findings in this study, there were several inherent limitations. First, this research was carried out at a single center with a small number of cases, thereby limiting its reliability and validity to the study hospital, albeit still offering some degree of reference value. Second, the retrospective nature of this analysis rendered it susceptible to selection bias. Furthermore, it is imperative to note that patients who tested negative from blood cultures were not included within the scope of this research. Next, it is imperative to note that the aforementioned strains primarily originated from HAP cases, thereby necessitating further exploration in subsequent research endeavors. Additionally, a comprehensive assessment of sample size was not carried out. Finally, the study did not analyze the prevalence of drug-resistant strains within the hospital and evaluate the genotypes associated with these strains. These limitations should be addressed in subsequent investigations.

In conclusion, KP-BP and E. coli-BP groups exhibited notable differences, but the prognosis (30-day mortality) of patients with KP-BP was similar to that of patients with E. coli-BP. The prevalence of drug-resistant strains posed a significant challenge in this study, thereby highlighting the importance of prioritizing appropriate antibiotic therapy.

Acknowledgment

The authors gratefully acknowledge Home for Researchers (www.home-for-researchers.com) for English language editing.

Footnotes

  • Disclosure. Authors have no conflict of interests, and the work was not supported or funded by any drug company.

  • Received December 12, 2023.
  • Accepted January 15, 2024.

This is an Open Access journal and articles published are distributed under the terms of the Creative Commons Attribution-NonCommercial License (CC BY-NC). Readers may copy, distribute, and display the work for non-commercial purposes with the proper citation of the original work.

References

  1. 1.
    1. Forstner C,
    2. Patchev V,
    3. Rohde G,
    4. Rupp J,
    5. Witzenrath M,
    6. Welte T, et al.
    Rate and predictors of bacteremia in Afebrile community-acquired pneumonia. Chest 2020; 157: 529-539.
    OpenUrl
  2. 2.
    1. Yin Y,
    2. Zhao C,
    3. Li H,
    4. Jin L,
    5. Wang Q,
    6. Wang R, et al.
    Clinical and microbiological characteristics of adults with hospital-acquired pneumonia: a 10-year prospective observational study in China. Eur J Clin Microbiol Infect Dis 2021; 40: 683-690.
    OpenUrl
  3. 3.
    1. Cillóniz C,
    2. Dominedò C,
    3. Torres A.
    Multidrug resistant gram-negative bacteria in community-acquired pneumonia. Crit Care 2019; 23: 79.
    OpenUrl
  4. 4.
    1. Amati F,
    2. Restrepo MI.
    Emerging resistance of gram negative pathogens in community-acquired pneumonia. Semin Respir Crit Care Med 2020; 41: 480-495.
    OpenUrl
  5. 5.
    1. Metlay JP,
    2. Waterer GW,
    3. Long AC,
    4. Anzueto A,
    5. Brozek J,
    6. Crothers K, et al.
    Diagnosis and treatment of adults with community-acquired pneumonia. An official clinical practice guideline of the American Thoracic Society and Infectious Diseases Society of America. Am J Respir Crit Care Med 2019; 200: e45-e67.
    OpenUrlCrossRefPubMed
  6. 6.
    1. Tamma PD,
    2. Aitken SL,
    3. Bonomo RA,
    4. Mathers AJ,
    5. van Duin D,
    6. Clancy CJ.
    Infectious diseases society of America 2022 guidance on the treatment of extended-spectrum β-lactamase producing enterobacterales (ESBL-E), carbapenem-resistant enterobacterales (CRE), and Pseudomonas aeruginosa with difficult-to-treat resistance (DTR-P. aeruginosa). Clin Infect Dis 2022; 75: 187-212.
    OpenUrl
  7. 7.
    1. Chen IR,
    2. Lin SN,
    3. Wu XN,
    4. Chou SH,
    5. Wang FD,
    6. Lin YT.
    Clinical and microbiological characteristics of bacteremic pneumonia caused by Klebsiella pneumoniae. Front Cell Infect Microbiol 2022; 12: 903682.
    OpenUrl
  8. 8.
    1. Jean SS,
    2. Chang YC,
    3. Lin WC,
    4. Lee WS,
    5. Hsueh PR,
    6. Hsu CW. Epidemiology
    , treatment, and prevention of nosocomial bacterial pneumonia. J Clin Med 2020; 9: 275.
    OpenUrl
  9. 9.
    1. Weiss G.
    Nutrition and infection. Clin Microbiol Infect 2018; 24: 8-9.
    OpenUrlPubMed
  10. 10.
    1. John TM,
    2. Deshpande A,
    3. Brizendine K,
    4. Yu PC,
    5. Rothberg MB.
    Epidemiology and outcomes of community-acquired Escherichia coli pneumonia. Open Forum Infect Dis 2021; 9: ofab597.
    OpenUrl
  11. 11.
    1. Chen D,
    2. Zhang Y,
    3. Wu J,
    4. Li J,
    5. Chen H,
    6. Zhang X, et al.
    Analysis of hypervirulent Klebsiella pneumoniae and classic Klebsiella pneumoniae infections in a Chinese hospital. J Appl Microbiol 2022; 132: 3883-3890.
    OpenUrl
  12. 12.
    1. Li F,
    2. Zhu J,
    3. Hang Y,
    4. Chen Y,
    5. Gu S,
    6. Peng S, et al.
    Clinical characteristics and prognosis of hospital-acquired Klebsiella pneumoniae bacteremic pneumonia versus Escherichia coli bacteremic pneumonia: a retrospective comparative study. Infect Drug Resist 2023; 16: 4977-4994.
    OpenUrl
  13. 13.
    1. Olson G,
    2. Davis AM.
    Diagnosis and treatment of adults with community-acquired pneumonia. JAMA 2020; 323: 885-886.
    OpenUrl
  14. 14.
    1. Fernando SM,
    2. Tran A,
    3. Cheng W,
    4. Klompas M,
    5. Kyeremanteng K,
    6. Mehta S, et al.
    Diagnosis of ventilator-associated pneumonia in critically ill adult patients-a systematic review and meta-analysis. Intensive Care Med 2020; 46: 1170-1179.
    OpenUrlCrossRefPubMed
  15. 15.
    1. Singer M,
    2. Deutschman CS,
    3. Seymour CW,
    4. Shankar-Hari M,
    5. Annane D,
    6. Bauer M, et al.
    The third international consensus definitions for sepsis and septic shock (sepsis-3). JAMA 2016; 315: 801-810.
    OpenUrlCrossRefPubMed
  16. 16.
    1. Hachiya A,
    2. Karasawa M,
    3. Imaizumi T,
    4. Kato N,
    5. Katsuno T,
    6. Ishimoto T, et al.
    The ISN/RPS 2016 classification predicts renal prognosis in patients with first-onset class III/IV lupus nephritis. Sci Rep 2021; 11: 1525.
    OpenUrl
  17. 17.
    1. Humphries R,
    2. Bobenchik AM,
    3. Hindler JA,
    4. Schuetz AN.
    Overview of changes to the clinical and laboratory standards institute performance standards for antimicrobial susceptibility testing, M100, 31st edition. J Clin Microbiol 2021; 59: e0021321.
    OpenUrlCrossRef
  18. 18.
    1. Jain S,
    2. Self WH,
    3. Wunderink RG,
    4. Fakhran S,
    5. Balk R,
    6. Bramley AM, et al.
    Community-acquired pneumonia requiring hospitalization among U.S. adults. N Engl J Med 2015; 373: 415-427.
    OpenUrlCrossRefPubMed
  19. 19.
    1. Jain S,
    2. Pavia AT.
    Editorial commentary: the modern quest for the “Holy Grail” of pneumonia etiology. Clin Infect Dis 2016; 62: 826-828.
    OpenUrlCrossRefPubMed
  20. 20.
    1. Chen SC,
    2. Wu WY,
    3. Yeh CH,
    4. Lai KC,
    5. Cheng KS,
    6. Jeng LB, et al.
    Comparison of Escherichia coli and Klebsiella pneumoniae liver abscesses. Am J Med Sci 2007; 334: 97-105.
    OpenUrlCrossRefPubMed
  21. 21.
    1. Shelat VG,
    2. Chia CL,
    3. Yeo CS,
    4. Qiao W,
    5. Woon W,
    6. Junnarkar SP.
    Pyogenic liver abscess: does Escherichia coli cause more adverse outcomes than Klebsiella pneumoniae? World J Surg 2015; 39: 2535-2542.
    OpenUrl
  22. 22.
    1. Scheuerman O,
    2. Schechner V,
    3. Carmeli Y,
    4. Gutiérrez-Gutiérrez B,
    5. Calbo E,
    6. Almirante B, et al.
    Comparison of predictors and mortality between bloodstream infections caused by ESBL-producing Escherichia coli and ESBL-producing Klebsiella pneumoniae. Infect Control Hosp Epidemiol 2018; 39: 660-667.
    OpenUrlPubMed
  23. 23.
    1. Lin YT,
    2. Jeng YY,
    3. Chen TL,
    4. Fung CP.
    Bacteremic community-acquired pneumonia due to Klebsiella pneumoniae: clinical and microbiological characteristics in Taiwan, 2001-2008. BMC Infect Dis 2010; 10: 307.
    OpenUrlCrossRefPubMed
  24. 24.
    1. Zhou C,
    2. Jin L,
    3. Wang Q,
    4. Wang X,
    5. Chen F,
    6. Gao Y, et al.
    Bloodstream infections caused by carbapenem-resistant enterobacterales: risk factors for mortality, antimicrobial therapy and treatment outcomes from a prospective multicenter study. Infect Drug Resist 2021; 14: 731-742.
    OpenUrl
  25. 25.
    1. Çopur Çiçek A,
    2. Ertürk A,
    3. Ejder N,
    4. Rakici E,
    5. Kostakoğlu U,
    6. Esen Yıldız İ, et al.
    Screening of antimicrobial resistance genes and epidemiological features in hospital and community-associated carbapenem-resistant Pseudomonas aeruginosa infections. Infect Drug Resist 2021; 14: 1517-1526.
    OpenUrl
  26. 26.
    1. Zhang X,
    2. Qu F,
    3. Jia W,
    4. Huang B,
    5. Shan B,
    6. Yu H, et al.
    Polymyxin resistance in carbapenem-resistant Enterobacteriaceae isolates from patients without polymyxin exposure: a multicentre study in China. Int J Antimicrob Agents 2021; 57: 106262.
    OpenUrl
  27. 27.
    1. Raro OHF,
    2. Collar GS,
    3. da Silva RMC,
    4. Vezzaro P,
    5. Mott MP,
    6. da Cunha GR, et al.
    Performance of polymyxin B agar-based tests among carbapenem-resistant Enterobacterales. Lett Appl Microbiol 2021; 72: 767-773.
    OpenUrl
  28. 28.
    1. Castanheira M,
    2. Doyle TB,
    3. Deshpande LM,
    4. Mendes RE,
    5. Sader HS.
    Activity of ceftazidime/avibactam, meropenem/vaborbactam and imipenem/relebactam against carbapenemase-negative carbapenem-resistant Enterobacterales isolates from US hospitals. Int J Antimicrob Agents 2021; 58: 106439.
    OpenUrl
  29. 29.
    1. Suda KJ,
    2. Traversa A,
    3. Patel U,
    4. Poggensee L,
    5. Fitzpatrick MA,
    6. Wilson GM, et al.
    Uptake in newly approved antibiotics prescribed to patients with carbapenem-resistant Enterobacterales (CRE). Infect Control Hosp Epidemiol 2023; 44: 674-677.
    OpenUrl
  30. 30.
    1. Gutiérrez-Gutiérrez B,
    2. Salamanca E,
    3. de Cueto M,
    4. Hsueh PR,
    5. Viale P,
    6. Paño-Pardo JR, et al.
    Effect of appropriate combination therapy on mortality of patients with bloodstream infections due to carbapenemase-producing Enterobacteriaceae (INCREMENT): a retrospective cohort study. Lancet Infect Dis 2017; 17: 726-734.
    OpenUrlPubMed
  31. 31.
    1. Meng H,
    2. Han L,
    3. Niu M,
    4. Xu L,
    5. Xu M,
    6. An Q, et al.
    Risk factors for mortality and outcomes in hematological malignancy patients with carbapenem-resistant Klebsiella pneumoniae bloodstream infections. Infect Drug Resist 2022; 15: 4241-4251.
    OpenUrl
  32. 32.
    1. Montrucchio G,
    2. Costamagna A,
    3. Pierani T,
    4. Petitti A,
    5. Sales G,
    6. Pivetta E, et al.
    Bloodstream infections caused by carbapenem-resistant pathogens in intensive care units: risk factors analysis and proposal of a prognostic score. Pathogens 2022; 11: 718.
    OpenUrl
  33. 33.
    1. Kotov SV,
    2. Pulbere SA,
    3. Alesina NV,
    4. Boyarkin VS,
    5. Guspanov RI,
    6. Belomytsev SV, et al.
    [The problem of antibiotic resistance in patients with urinary tract infection]. Urologiia 2021: 5-12. [In Russian]
  34. 34.
    1. Paul M,
    2. Carrara E,
    3. Retamar P,
    4. Tängdén T,
    5. Bitterman R,
    6. Bonomo RA, et al.
    European society of clinical microbiology and infectious diseases (ESCMID) guidelines for the treatment of infections caused by multidrug-resistant Gram-negative bacilli (endorsed by European society of intensive care medicine). Clin Microbiol Infect 2022; 28: 521-547.
    OpenUrl
  35. 35.
    1. Al-Hasan MN,
    2. Baddour LM.
    Resilience of the Pitt bacteremia score: 3 decades and counting. Clin Infect Dis 2020; 70: 1834-1836.
    OpenUrl
  36. 36.
    1. Henderson H,
    2. Luterbach CL,
    3. Cober E,
    4. Richter SS,
    5. Salata RA,
    6. Kalayjian RC, et al.
    The Pitt bacteremia score predicts mortality in nonbacteremic infections. Clin Infect Dis 2020; 70: 1826-1833.
    OpenUrl
Back to top

In this issue

Print
Download PDF
Email Article
Citation Tools
Bookmark this article

Jump to section

Keywords