Abstract
Introduction
The impact of immunosuppression on prognosis of carbapenem-resistant organism (CRO) bloodstream infection (BSI) remains unclear. The aim of this study was to clarify the relationship between immunosuppression and mortality of CRO-BSI and to identify the risk factors associated with mortality in immunosuppressed patients.
Methods
This retrospective study included 279 patients with CRO-BSI from January 2018 to March 2023. Clinical characteristics and outcomes were compared between the immunosuppressed and immunocompetent patients. The relationship between immunosuppression and 30-day mortality after BSI onset was assessed through logistic-regression analysis, propensity score matching (PSM) and inverse probability of treatment weighting (IPTW). Factors associated with mortality in immunosuppressed patients were analyzed using multivariable logistic regression analysis.
Results
A total of 88 immunocompetent and 191 immunosuppressed patients were included, with 30-day all-cause mortality of 58.8%. Although the 30-day mortality in immunosuppressed patients was significantly higher than in immunocompetent patients (46.6% vs. 64.4%, P = 0.007), immunosuppression was not an independent risk factor for mortality in multivariate logistic regression analysis (odds ratio [OR] 3.53, 95% confidence interval [CI] 0.74–18.89; P = 0.123), PSM (OR 1.38, 95% CI 0.60–3.18; P = 0.449,) or IPTW (OR 1.40, 95% CI 0.58–3.36; P = 0.447). For patients with CRO-BSI, regardless of immune status, appropriate antibiotic therapy was associated with decreased 30-day mortality, while Charlson comorbidity index (CCI), intensive care unit (ICU)-acquired infection and thrombocytopenia at CRO-BSI onset were associated with increased mortality.
Conclusion
Despite the high mortality rate of CRO-BSI, immunosuppression did not affect the mortality. Appropriate antibiotic therapy is crucial for improving the prognosis of CRO-BSI, regardless of the immune status.
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Avoid common mistakes on your manuscript.
Why carry out this study? |
Carbapenem-resistant organism (CRO) infections are associated with high mortality and substantial costs, and immunosuppressed patients are special populations deserving particular attention because of their vulnerability. |
This study compared the characteristics of immunosuppressed patients with the immunocompetent and aimed to determine whether immunosuppression was an independent risk factor for mortality in CRO bloodstream infection (BSI). |
What was learned from the study? |
Although the 30-day mortality in immunosuppressed patients was significantly higher compared with immunocompetent patients, immunosuppression was not an independent risk factor in CRO bloodstream infections. |
Appropriate antibiotic therapy was crucial for improving the prognosis of CRO-BSI, in both overall and immunosuppressed patients. |
For patients with CRO-BSI, regardless of immune status, Charlson comorbidity index (CCI), intensive care unit (ICU)-acquired infection and thrombocytopenia at CRO-BSI onset were associated with increased mortality. |
Introduction
Antimicrobial resistance is universally recognized as one of the most serious public health challenges of the twenty-first century [1]. According to the latest data, the additional cost caused by a single episode of carbapenem-resistant organism (CRO) bacteremia was $72,051 [2], significantly higher than that of other multidrug-resistant organisms. CRO infection has also been reported to be associated with increased mortality [3], exceeding 50% in cases of bloodstream infections (BSI) [4, 5]. Immunosuppressed individuals are prone to hospitalization because of their underlying diseases, and they often receive broad-spectrum antibiotic treatment, thus increasing the risk for developing multidrug-resistant bacteria [6]. Many studies have shown that immunosuppression is related to a higher incidence of infection with multidrug-resistant pathogens, including CRO [7,8,9].
Immunosuppressed status has been shown to have a close relationship with poor clinical prognosis [10]. Previous studies identified immunosuppression as an independent risk factor for mortality in CRO carriers and infections [3, 11]. However, few have focused on CRO-BSI in immunosuppressed patients. The relationship between immunosuppression and mortality in cases of CRO-BSI, as well as the factors affecting the mortality of immunosuppressed patients, remains unclear.
Focused on CRO-BSI, this retrospective study aimed to describe the characteristics and outcomes of immunosuppressed patients compared with the immunocompetent to identify whether the immunosuppression was an independent risk factor for mortality and to analyze the predictors for mortality in immunosuppressed patients.
Methods
Design and Setting
This retrospective cohort study was conducted at Peking Union Medical College Hospital, a tertiary care teaching hospital with more than 2000 beds, from 1 January 2018 to 31 March 2023. Patients > 18 years old with positive blood cultures of CRO and meeting the diagnostic criteria for BSI based on Infectious Diseases Society of America standard were screened from the electronic records in the electronic database [12]. This study only included the first positive sample of each patient. Exclusion criteria included any of the following: patients with key variables unavailable or with bacteria other than CRO or fungi cultured in blood.
We categorized the patients with CRO-BSI into immunosuppressed group and immunocompetent group to compare the clinical characteristics and outcomes. Risk factors associated with 30-day mortality were identified in the overall population and the subgroup of immunosuppressed patients.
Definition
CRO was defined as microorganisms resistant to any of the carbapenems, such as imipenem, meropenem or ertapenem, based on CLSI 2018 breakpoints criteria [13]. BSI referred to at least one detection of pathogenic microorganisms in blood culture. We determined the source of bacteremia based on the criteria of the Center for Disease Control and Prevention [14]. Immunosuppression was defined as: active hematologic malignancy, solid tumor (active or in remission for less than 3 years), autoimmune diseases with long-term (≥ 28 days) use of steroids (≥ 20 mg of prednisone per day or equivalent) or other immunosuppressant drugs, human immunodeficiency virus infection, solid-organ transplant or hematopoietic stem cell transplantation [15]. Bacteremia onset was defined as the day of positive blood culture collection. Thrombocytopenia, neutropenia, lymphopenia and hypoalbuminemia referred to peripheral blood platelet count < 100 × 109/l, neutrophils < 1 × 109/l, lymphocytes < 0.5 × 109/l and albumin < 30 g/l, respectively. Mortality was defined as all-cause mortality, and length of stay indicated length of stay after BSI onset.
Appropriate empirical therapy was defined as administration of at least one antimicrobial in vitro activity against the isolates within 24 h of infection onset and for at least 48 h. Early appropriate therapy and appropriate therapy were defined as administering one or more in vitro active antimicrobials within 3 days and 7 days of infection onset and for at least 48 h, respectively. As for the antimicrobial therapies, monotherapy indicated the application of only one antibiotic which was sensitive in vitro, and combination antimicrobial therapy meant the use of at least two types of active antibiotics with combined application times > 48 h.
Data Collection
We retrospectively reviewed hospital’s electronic medical record system and collected the demographic characteristics, comorbidities including Charlson comorbidity index (CCI) and information on immunosuppression [16]. We also recorded laboratory results and disease severity including Pitt bacteremia score [17], intensive care unit (ICU) admission and organ support information on the day onset. In addition, we documented microbiologic data such as infection site, source of infection, species and antibiotic susceptibility results, antimicrobial therapy and outcomes including mortality and length of stay.
Statistical Analysis
We used descriptive analysis to describe each variable. Categorical variables were shown as counts and percentages and were compared by chi-squared test or Fisher’s exact test. Continuous variables were presented as the mean ± SD or median with interquartile range (IQR) and were compared by Student’s t-test or Mann-Whitney U test, based on whether the variable conformed to a normal distribution.
In multivariable logistic regression model, we included variables with P < 0.05 in the univariable analysis. We used the variance inflation factor (VIF) to check multicollinearity among all variables and considered the model acceptable if VIF values were < 10. Hosmer-Lemeshow test was performed to evaluate the goodness of fit for the logistic regression model. The odds ratios (ORs) and the 95% confidence intervals (CIs) for variables were calculated. To avoid collinearity, we only included appropriate treatment in the multivariate analysis in terms of antimicrobial treatment. Sensitivity analyses for 30-day mortality were performed in specific subgroups.
We performed propensity score matching (PSM) to reduce bias by adjusting for the following five variables: age, sex, ICU-acquired infection, Pitt bacteremia score and appropriate therapy. PSM was implemented with a nearest-neighbor strategy. Immunosuppressed and immunocompetent patients were paired based on the propensity scores using exact matching with a paired ratio of 1:1 and a caliper size of 0.02. During the process of matching, we lost a considerable number of patients. So, we also performed inverse probability of treatment weighting (IPTW) by using propensity score analysis to estimate the effects on mortality of immunosuppression including all eligible patients.
All statistical analyses were performed using R version 4.2.2. P < 0.05 was considered statistically significant.
Ethics
The retrospective study was approved by the Ethics Committee of Peking Union Medical College Hospital (K23C3906) and was conducted in accordance with the 1964 Declaration of Helsinki and its later amendments. As this was a retrospective study, informed consent was waived.
Results
Patient Characteristics
Characteristics of All Patients
A total of 334 episodes of 317 patients were screened, and finally 279 patients were included in the study, among whom 88 (31.5%) were immunocompetent and 191 (68.5%) were immunosuppressed (Fig. 1). Patients were mostly male (63.4%), with a median age of 61 (IQR 49–70) years. Hospital- and ICU-acquired infections accounted for 90.7% and 45.5%, respectively. Carbapenem-resistant Acinetobacter baumannii (CRAB) accounted for the highest proportion of 42.7%, followed by Carbapenem-resistant Enterobacterales (CRE) (36.9%). More than half of patients (57.0%) were admitted to ICU on the day of bacteremia, and 60.9% experienced septic shock. The proportions of appropriate empirical therapy and early appropriate therapy were 37.6% and 51.3%, respectively. Most patients (62.0%) received appropriate antimicrobial therapy (Table 1). Regrading the antibiotic susceptibility results of CRO species, 93.1% of all isolates were sensitive to polymyxin, and 68.2% of non-Pseudomonas aeruginosa species were sensitive to tigecycline. Except for CRAB, 80.4% of isolates were sensitive to ceftazidime avibactam (Supplementary Material 1).
In terms of outcomes, 3-day, 7-day and 30-day mortality were 30.8%, 40.9% and 58.8%, respectively. The median length of stay after CRO-BSI onset was 29 (IQR 16–49) days.
Characteristics Between Immunocompetent and Immunosuppressed Patients
Compared with the immunocompetent patients, the immunosuppressed patients had higher CCI scores (6 vs. 4, P = 0.001) and higher proportions of ICU-acquired infections (49.2% vs. 37.5%, P = 0.090). There was no significant difference in types of bacteria, source of BSI or severity of disease between the two groups. As for laboratory results, patients in the immunosuppressed group had lower lymphocyte (0.35 vs. 0.54 × 109/l, P < 0.001) and platelet (65 vs. 120 × 109/l, P < 0.001) values compared with the immunocompetent group.
There was no significant difference in 7-day mortality (33.0% vs. 44.5%, P = 0.091) and length of stay (30 vs. 29 days, P = 0.524) between immunocompetent and immunosuppressed populations, but the 30-day mortality rate was significantly higher in the immunosuppressed group (46.6% vs. 64.4%, P = 0.007). According to the bacterial species, the 30-day mortality rate of CRAB BSI was the highest, reaching 70.6% (84/119), which was significantly higher in the immunosuppressed group (79.1% vs. 48.5%, P = 0.001). The proportion of patients receiving appropriate therapy was similar between the two groups (61.4% vs. 62.3%, P = 0.986). There was no significant difference in 30-day mortality between the immunosuppressed group and immunocompetent group in patients receiving either monotherapy (52.1% vs. 38.2%, P = 0.183) or combination therapy (54.3% vs. 30.0%, P = 0.069).
Immunosuppression Was Not an Independent Risk Factor for 30-Day Mortality
Univariate Analysis and Multivariate Logistic Regression Analysis
A comparison of the survival and non-survival group is shown in Table 1. The proportion of immunosuppressed population in the non-survival group was 75.0% (123/164), while it was only 59.1% (68/115) in the survival group (P = 0.007). The proportion of ICU-acquired infections in the non-survival group was statistically higher (55.5% vs. 31.3%, P < 0.001). For laboratory results, patients in the non-survival group had a higher proportion of lymphopenia (62.8% vs. 46.1%, P = 0.008) and thrombocytopenia (72.6% vs. 40.0%, P < 0.001) compared with the survival group. There was no significant difference in the proportion of appropriate empirical therapy between the survival and non-survival group, but the proportion of early appropriate therapy and appropriate therapy in the non-survival group was significantly lower.
There was no significant difference in 30-day mortality between monotherapy and combination therapy among patients receiving appropriate therapy (47.7% vs. 47.0%, P = 0.929). Active antibiotic treatments for patients with appropriate antimicrobial therapy are shown in Table 2.
Multivariable logistic regression showed that the independent risk factors for 30-day mortality of CRO-BSI included CCI (OR 1.23, 95% CI 1.06–1.44), ICU-acquired infection (OR 2.59, 95% CI 1.12–6.13) and thrombocytopenia (OR 4.09, 95% CI 1.85–9.34), while appropriate therapy (OR 0.27, 95% CI 0.12–0.62) was associated with decreased mortality (Table 3). Immunosuppression was not an independent risk factor associated with 30-day mortality of CRO-BSI (OR 1.14, 95% CI 0.48–2.66).
Sensitivity Analysis
We conducted two additional sensitivity analyses to explore the impact of immunosuppression on the mortality of CRO-BSI and obtained consistent results. Immunosuppression was not an independent risk factor for 30-day mortality in either sensitivity analysis: one excluding patients with solid tumors featuring the lowest mortality rate (OR 2.21, 95% CI 0.84–5.91; P 0.109) and the other considering only patients with hematologic malignancies as the immunosuppressed population (OR 3.53, 95% CI 0.74–18.89; P 0.123).
Propensity Score Matching and Inverse Probability of Treatment Weighting
The PSM resulted in 58 immunosuppressed patients matched to 58 immunocompetent patients. More participants were immunosuppressed; thus, 133 immunosuppressed patients were unmatched in contrast to 30 immunocompetent patients. Then, IPTW assessed from patients with all covariate data was included in the propensity analysis (n = 279). The results showed that immunosuppression was not an independent risk factor associated with 30-day mortality in CRO-BSI in either the PSM cohort (OR 1.38, 95% CI 0.60–3.18; P 0.449) or IPTW cohort (OR 1.40, 95% CI 0.58–3.36; P 0.447).
Risk Factors for 30-Day Mortality in Immunosuppressed Patients
In immunosuppressed patients, the 30-day mortality was 64.4% (123/164). The CCI (6 vs. 5, P < 0.001) and Pitt bacteremia score (4 vs. 1, P < 0.001) were statistically higher, and the blood culture time to positivity was significantly lower in the non-survival group (12 vs. 13.5 h, P = 0.009). More patients in the survival group received appropriate therapy (82.4% vs. 51.2%, P < 0.001) (Supplementary Material 2).
Results of multivariable logistic regression analysis showed that the independent risk factors for mortality in CRO-BSI included CCI (OR 1.45, 95% CI 1.16–1.88), glucocorticoid use (OR 15.78, 95% CI 2.32–152.12), ICU-acquired infection (OR 7.15, 95% CI 1.96–31.15), thrombocytopenia (OR 4.33, 95% CI 1.18–17.32) and Pitt bacteremia score (OR 1.51, 95% CI 1.16–2.09), while appropriate therapy (OR 0.10, 95% CI 0.02–0.42) was associated with decreased mortality (Table 4).
No specific type of immunosuppression was an independent risk factor for 30-day mortality among immunosuppressed patients.
Among patients receiving appropriate antimicrobial treatment, 30-day mortality between monotherapy and combination therapy did not show a significant difference (52.1% vs. 54.3%, P = 0.807).
Discussion
Focused on CRO-BSI, this study showed that there was no significant difference in the types of bacteria, source of bacteremia, severity of the disease and proportion of appropriate therapy between immunosuppressed and immunocompetent patients. Although the 30-day mortality was significantly higher in the immunosuppressed patients than immunocompetent ones, immunosuppression was not an independent risk factor associated with 30-day mortality. The factors associated with prognosis in immunosuppressed patients included CCI, glucocorticoid use, ICU-acquired infection, thrombocytopenia, Pitt bacteremia score and appropriate therapy.
To date, many studies have been concerned with different microbial infections in immunosuppressed patients. However, the populations of those studies were patients with several certain types of immunosuppression, or the researchers focused on specific microbial infections in diverse types of immunosuppression [18,19,20,21]. Studies on CRO-BSI in the overall immunosuppressed patients and their comparison with immunocompetent populations are still rare. Compared with immunocompetent patients, this study described the clinical characteristics of immunosuppressed patients with CRO-BSI and identified that immunosuppression was not an independent predictor of mortality.
There is no consistent conclusion on whether immunosuppression is associated with death in sepsis-related studies [22, 23]. In a large study of extremely drug-resistant organism infections in ICU patients, immunosuppression was identified as an independent risk factor associated with 7-, 15- and 30-day mortality [9]. Rivera-Villegas and colleagues also suggested immunosuppression as an independent risk factor for mortality in CRO infections [3]. However, neither of these studies limited the site of infection, with BSI accounting for only 10–35%. However, BSI presented the highest severity and mortality rate among various infections, which requires special attention and research. In this study focused on CRO-BSI, we used several methods (such as multivariate analysis, PSM and IPTW) and conducted sensitivity analysis considering the lowest mortality in patients with solid tumors and hematology malignancy as a classic immunosuppressed population to control bias and adjust confounding factors and then reached the same conclusion. Our results showed that immunosuppression was not an independent risk factor for death in CRO-BSI.
A number of studies have shown that inappropriate antibiotics are associated with increased mortality in CRO-BSI [3, 24, 25]. Previous studies found that the patients who received inappropriate antibiotic therapy demonstrated close to a two- to threefold higher rate of death [26, 27]. Appropriate antibiotic treatment would be more crucial in immunosuppressed populations. Micozzi and colleagues found that 80% of fatal CRO-BSI in hematologic patients occurred on inappropriate therapy, and initial adequate antibiotic therapy was the single independent protective factor against death [28]. This study also demonstrated that appropriate antimicrobial therapy was associated with decreased mortality in CRO-BSI patients regardless of overall or immunosuppressed patients.
Regarding antimicrobial-resistant bacterial infections, clinicians will be most interested in whether combination therapy can improve prognosis. There is currently no consensus based on existing research results. Kim and colleagues suggested that combination therapy had no significant effect on mortality compared with monotherapy [29]. However, several studies suggested combination therapy for CRO infection [25, 30, 31], and combination antibiotic therapy showed a lower mortality rate independently compared with monotherapy, whether empirical or definitive [32]. As for immunosuppressed patients, previous study found that appropriate combination therapy led to decreased mortality [29]. Our study showed that, among patients receiving monotherapy, there was no significant difference in 30-day mortality between immunosuppressed and immunocompetent patients, neither for combination therapy. Furthermore, among patients receiving appropriate antimicrobial treatments, combination antimicrobial therapy showed no significant effect on 30-day mortality compared with monotherapy, regardless of overall population or immunosuppressed patients.
Different types of immunosuppression may have an effect on different mortality. Tolsma et al. [33] included diverse immunosuppressed patients diagnosed with sepsis and found that AIDS, nonneutropenic solid tumor, nonneutropenic hematologic malignancies and all-cause neutropenia were independently associated with death, while inflammatory or immune disorder, solid organ transplant and primary immunodeficiency were not. Another study showed that only patients with solid tumors exhibited higher mortality rates compared to other immunosuppressed patients in septic shock [34]. However, in this study focused on CRO-BSI, we also included various immunosuppressed patients, and no specific type of immunosuppression was an independent risk factor for 30-day mortality in CRO-BSI.
Our study had some limitations. First, our study was a single-center study, which may have affected its generalizability. However, we included multiple types of immunosuppressed populations without any being predominant. In addition, we only used common types of disease to classify the immunosuppressed populations and used lymphocyte count to reflect the degree of immunosuppression rather than more precise immune markers because of the retrospective nature of this study.
Conclusion
Focused on CRO-BSI, this study revealed that there was no significant difference in types of bacteria, source of bacteremia, severity of the disease and proportion of appropriate therapy in immunosuppressed patients compared to immunocompetent population. Though the 30-day mortality of CRO-BSI was significantly higher in the immunosuppressed patients than immunocompetent ones, immunosuppression was not an independent risk factor for mortality. For patients with CRO-BSI, regardless of immune status, CCI, ICU-acquired infection and thrombocytopenia at CRO-BSI onset were associated with increased mortality, while appropriate antibiotic therapy was associated with decreased 30-day mortality. Besides, among patients receiving appropriate antimicrobial therapy, there was no significance difference in 30-day mortality between monotherapy and combination antimicrobial therapy in both the overall population and immunosuppressed patients.
Data Availability
The datasets generated and/or analyzed during the current study are available from the corresponding author on reasonable request.
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Acknowledgements
We thank Chao Xu, Lu Liu, Hong-Chun Lv and Xi-Jie Duan for help in data collection.
Funding
We acknowledge the support from: National key clinical specialty construction projects from National Health Commission; National Key Research and Development Program of China from Ministry of Science and Technology of the People's Republic of China (2021YFC2500804, 2022YFC2304601); Commission CAMS Innovation Fund for Medical Sciences (CIFMS) 2021-I2M-1-062 from Chinese Academy of Medical Sciences; National High Level Hospital Clinical Research Funding (2022-PUMCH-B-111, 2022-PUMCH-B-126). The Rapid Service Fee was funded by the authors.
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Bin Du, Jin-Min Peng and Yuan-Yuan Li designed the study. Yuan-Yuan Li, Yan-Chen, Yuan-Yuan Li and Shan Li were in charge of data collection. Ran An, Xiao-Yun Hu, Wei Jiang, Chun-Yao Wang, Run Dong and Qi-Wen Yang interpreted the clinical data. Yuan-Yuan Li and Yan-Chen performed the statistical analyses. Jin-Min Peng, Bin Du and Li Weng directed the writing and revised the first version of the manuscript. The first draft of the manuscript was written by Yuan-Yuan Li, and all authors commented on previous versions of the manuscript. All authors read and approved the final manuscript.
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Yuan-Yuan Li, Yan Chen, Shan Li, Yuan-Yuan Li, Ran An, Xiao-Yun Hu, Wei Jiang, Chun-Yao Wang, Run Dong, Qi-Wen Yang, Li Weng, Jin-Min Peng and Bin Du declare that they have no conflicts of interest regarding this work.
Ethical Approval
This study was conducted in accordance with the 1964 Declaration of Helsinki and its later amendments and was approved by the Ethics Committee of Peking Union Medical College Hospital (no. K23C3906). Informed consent was waived because this is a retrospective study.
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Li, YY., Chen, Y., Li, S. et al. Impact of Immunosuppressed Status on Prognosis of Carbapenem-Resistant Organisms Bloodstream Infections. Infect Dis Ther 13, 861–874 (2024). https://doi.org/10.1007/s40121-024-00956-9
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DOI: https://doi.org/10.1007/s40121-024-00956-9