Jundishapur J Microbiol
Jundishapur J Microbiol

article information

Jundishapur Journal of Microbiology: Vol.15, issue 7; e126998
published online: July 27, 2022
article type: Research Article
received: April 17, 2022
revised: July 6, 2022
accepted: July 7, 2022
DOI: https://doi.org/10.5812/jjm-126998
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Three-Year Evaluation of Pseudomonas aeruginosa Bacteremia in Patients Admitted to a University-Affiliated Hospital, Mashhad, Iran

authors:

avatar Ali Akbar Heydari ORCID 1 , * , avatar Shima Jamialahmadi ORCID 2 , avatar Mahdi Kouhi Noghondar ORCID 3 , 4

Department of Infectious Diseases, Research Center for Infection Control & Hand Hygiene, Imam Reza Hospital, Mashhad University of Medical Sciences, Mashhad, Iran
School of Medicine, Mashhad University of Medical Sciences, Mashhad, Iran
Antimicrobial Resistance Research Center, Buali Research Institute, Mashhad University of Medical Sciences, Mashhad, Iran
Department of Microbiology and Virology, Faculty of Medicine, Mashhad University of Medical Sciences, Mashhad, Iran

how to cite: Heydari A A, Jamialahmadi S, Kouhi Noghondar M. Three-Year Evaluation of Pseudomonas aeruginosa Bacteremia in Patients Admitted to a University-Affiliated Hospital, Mashhad, Iran. Jundishapur J Microbiol. 2022;15(7):e126998. https://doi.org/10.5812/jjm-126998.

Abstract

Background:

Pseudomonas aeruginosa is an opportunistic gram-negative pathogen that can cause infection in almost any body part.

Objectives:

We aimed to evaluate the characteristics of patients with P. aeruginosa bloodstream infection (BSI).

Methods:

In this cross-sectional study, we retrospectively evaluated the records of 35 patients with P. aeruginosa BSI admitted to the Imam Reza Hospital, Mashhad, Iran, during 2012 - 2015. Age, sex, clinical symptoms, risk factors, underlying diseases, and the antibiogram test results were recorded and compared between nosocomial and community-acquired infection (CAI) dead and alive patients using the chi-square test. Data were analyzed using SPSS software, version 21.

Results:

The patients had a mean age of 54.57 ± 20.75 years, with 19 of them being men (54.3%). Intubation was only required in the deceased group (N = 19; P = 0.014). Tachypnea was more frequent (63.2% vs. 13.2%, P = 0.003), and appropriate treatment was less frequent (27.8% vs. 66.7%; P = 0.02) in the deceased group compared to the control group. Most patients with nosocomial infection (N = 24) passed away (66.7%; P = 0.03). All nine patients with a history of burning had a nosocomial infection (P = 0.01). Shivering and decreased consciousness were more frequent in patients with CAI (both P = 0.03) than in other patients. The antibiogram test results showed high resistance to multiple antibiotics.

Conclusions:

Considering the high mortality rate of P. aeruginosa BSI and resistance to multiple antibiotics, it is necessary to pay greater attention to the prevention of nosocomial infection with this pathogen, especially in patients admitted to burn centers and those with specific clinical signs, like tachypnea and leukocytosis.

1. Background

Pseudomonas aeruginosa is an opportunistic Gram-negative pathogen, considered the most common cause of nosocomial infection and one of the top causes of ventilator-associated pneumonia (VAP) (1). The source of P. aeruginosa pneumonia is mainly nosocomial, and it is a hospital-acquired infection. However, it can also be a community-acquired infection (CAI), primarily occurring in patients with underlying comorbidities (2, 3). Pseudomonas aeruginosa can cause infection in almost any body part; the one with the worst prognosis is blood, resulting in bloodstream infection (BSI) (4). BSI occurs mainly in immunodeficient patients and results in an annual mortality rate of 40% (5, 6). The pulmonary focus of infection, substance abuse, and comorbidities, such as cancer, cardiac, liver, and lung diseases, are considered the main risk factors for P. aeruginosa BSI and worse patients’ prognosis (7).

One of the main concerns about this pathogen is multidrug resistance (MDR), as it is the top cause of antibiotic prescription at intensive care units (ICUs) and requires adequate antibiotic therapy to reduce the mortality rate of these patients (8-10). Most combinations of antibiotics fail to treat P. aeruginosa BSI, and 70% are considered extensively drug-resistant (XDR) (11, 12). As inappropriate therapy is the central cause of mortality in patients with P. aeruginosa infection, it is suggested to perform a combination antibiogram test to identify the most possibly appropriate antibiotic, especially in patients with P. aeruginosa BSI (13, 14).

2. Objectives

In the present study, we aimed to evaluate the frequency of P. aeruginosa during a three-year period in a referral hospital in Northeast Iran and investigate its risk factors, clinical symptoms, and laboratory signs, as well as patients’ outcomes.

3. Methods

3.1. Study Design

This retrospective cross-sectional study included all cases of BSI with complete records admitted to different wards of the Imam Reza Hospital, affiliated with the Mashhad University of Medical Sciences, Mashhad, Iran, during 2012 - 2015. The researcher reviewed the laboratory records of patients, evaluated the results for finding eligible patients, and recorded their information in the study checklist. The patients' codes were recorded, and their names were not disclosed to maintain the confidentiality of their information. The recorded information included age, sex, clinical symptoms, risk factors, underlying diseases, antibiotic resistance, and infection sites. The evaluated risk factors included history of hospital admission, intubation, and surgery before blood culture, history of using injectable drugs at home (like insulin), and history of renal dialysis, corticosteroid and antibiotic therapy, and vascular catheter. The underlying diseases included hypertension (HTN), diabetes mellitus (DM), cardiovascular accident (CVA), ischemic heart disease (IHD), congestive heart failure (CHF), end-stage renal disease (ESRD), hyperlipidemia (HLP), tuberculosis, polymyositis, multiple myeloma (MM), cancer, hepatitis B, and human immunodeficiency virus (HIV).

The physician diagnosed BSI according to the results of clinical and laboratory examinations. The clinical symptoms included fever (> 37.7°C), shivering, cough, tachypnea, and impaired consciousness. The recorded laboratory parameters included leukocytosis (> 12000/mm3; normal 4,500 - 11,000), leukopenia (< 4000/mm3; normal: 4,500 - 11,000), neutropenia (< 500; normal: 1,500 - 8,000/mm3), positive C-reactive protein (CRP) (> 10 mg/L; normal ≤ 10 mg/L), and pyuria (< 10; normal 1 - 4 cells/h.p.f) with or without bacteriuria (> 105 CFU/mL in non-catheterized specimen; > 103 cfu/mL in catheterized specimen) in the urine examination. The estimated sedimentation ratio (ESR) with values ≤ 30 mm/h was considered normal, 30 - 70 mm/h moderately high, and ≥ 70 mm/h increased ESR. Appropriate treatment was defined as administering at least one of the antibiotics found sensitive in the antibiogram test. The patient admission ward and sensitivity or resistance of P. aeruginosa to antibiotics were recorded according to the results of the antibiogram test. The patients' outcome was recorded as dead or alive during hospitalization. The patients' P. aeruginosa BSI was considered nosocomial if hospitalized (at least two days before blood culture) and CAI otherwise.

3.2. Statistical Analysis

The descriptive results were presented as frequency (percentage) and mean ± standard deviation (SD) for categorical and numeric variables, respectively. The chi-square test was used to compare categorical variables between the subgroups. The statistical software IBM SPSS Statistics for Windows, version 21.0 (IBM Corp. 2012. Armonk, NY: IBM Corp) was used for the statistical analysis. P values < 0.05 were considered statistically significant.

4. Results

A total of 35 patients were included in the study, of whom 16 (45.7%) were women and 19 (54.3%) were men. Fever was the most common symptom (85.7%), followed by tachypnea (40%), shivering (22.9%), and reduced level of consciousness (22.9%). Among all the patients, 16 remained alive, and 19 died. The laboratory tests results showed that of the patients, 20 (57.1%) had leukocytosis, three (8.6%) had leukopenia, 14 (40%) had positive CRP; among patients with ESR test results, two (12.5%) had low ESR, six (37.5%) had moderate ESR, eight (50%) had high ESR levels, five (17.9%) had pyuria. Urine test showed that seven (25%) had pyuria + bacteriuria, and eight (22.9%) had positive urine culture. The frequency of the hospital wards and the admitted patients is shown in Figure 1. As shown, the burn unit was the most frequent ward in the hospital.

The frequency of the patients' underlying diseases is shown in Figure 2. As shown, HTN, CVA, and IHD had the highest frequency (34.3% each), followed by ESRD and DM (22.9% each). As shown in Figure 3 P. aeruginosa had a high resistance to multiple antibiotics (first-generation cephalosporin, non-anti pseudomonas cephalosporin, co-trimoxazole aminoglycoside, 4th generation cephalosporin, quinolone, anti-pseudomonas carbapenem (imipenem), anti-pseudomonas cephalosporin, piperacillin-tazobactam, and carbapenem (meropenem) in order of decreasing resistance) and was sensitive only to few antibiotics.

The frequency of wards in the study population
The frequency of wards in the study population
Figure 1.

The frequency of wards in the study population

The frequency of underlying diseases in the study population
The frequency of underlying diseases in the study population
Figure 2.

The frequency of underlying diseases in the study population

The frequency of A, the antibiotic resistance; and B, sensitivity of the study population based on the antibiogram test results.
The frequency of A, the antibiotic resistance; and B, sensitivity of the study population based on the antibiogram test results.
Figure 3.

The frequency of A, the antibiotic resistance; and B, sensitivity of the study population based on the antibiogram test results.

As indicated in Table 1, only the deceased group required intubation, while none of the patients in the alive group required intubation (P = 0.014). The frequency of appropriate treatment was significantly higher in the alive group than in the deceased group (66.7% vs. 27.8%; P = 0.02). However, the rest of the variables were not different between the dead and alive patients. Among the clinical symptoms, only the frequency of tachypnea was different between the groups and significantly higher in the deceased patients (P = 0.003; Table 1). Twenty-four patients (68.6%) had a nosocomial infection. As shown in Table 2, there was a significant difference in the frequency of death, and most patients with nosocomial infection passed away (66.7%), compared with 27.3% of patients with CAI (P = 0.03). All nine patients with a history of burning had a nosocomial infection, and none of the patients with CAI had a history of burning (P = 0.01). The frequency of shivering and decreased consciousness was also different between the groups (both P = 0.03; Table 2).

Table 1.

Comparison of Patients’ Characteristics Between Dead and Alive Patients a, b

Variables and CategoriesTotal (N = 35)Alive (N = 19)Deceased (N = 16)P Value c
Positive history of admission31 (89)14 (87.5)17 (89.5)0.85
Positive history of intubation6 (17.1)06 (31.6)0.014
Positive history of using injectable drugs at home (insulin)6 (17.1)2 (12.5)4 (21.1)0.50
Positive history of hemodialysis12 (34.3)5 (31.3)7 (36.8)0.72
Positive history of corticosteroid therapy2 (5.7)1 (6.3)1 (5.3)0.90
Positive history of antibiotic use in the past three months10 (28.6)5 (31.3)5 (26.3)0.74
Positive history of surgery18 (51.4)6 (37.5)12 (63.2)0.13
Positive history of burning9 (25.7)3 (18.8)6 (31.6)0.38
Positive history of vascular catheter before blood culture15 (42.9)6 (37.5)9 (47.4)0.55
Number of antibiotics received for treatment0.96
One6 (17.6)3 (20)3 (16.7)
Two20 (58.8)9 (60)11 (61.1)
Three7 (20.5)3 (20)4 (22.2)
Received appropriate treatment10 (66.7)5 (27.8)0.02
Clinical symptoms
Fever30 (85.7)14 (93.8)15 (78.9)0.21
Tachypnea14 (40)2 (13.2)12 (63.2)0.003
Decreased consciousness8 (22.9)3 (20)5 (26.3)0.66
Shivering8 (22.9)3 (15.8)5 (31.25)0.94
Cough5 (14.3)1 (6.7)4 (21.1)0.24

a Values are expressed as No. (%).

b Considered significant at P values < 0.05.

c The results of the chi-square test.

Table 2.

Comparison of Patients’ Characteristics Between Patients with Nosocomial and Community-Acquired Infection a, b

Variables and CategoriesCommunity-Acquired Infection (N = 11)Nosocomial Infection (N = 24)P Value c
Patients’ outcome0.03
Dead3 (27.3)16 (66.7)
Alive8 (72.7)8 (33.3)
Positive history of intubation06 (25)0.068
Positive history of using injectable drugs at home (insulin)3 (27.3)3 (12.5)0.28
Positive history of hemodialysis6 (54.5)6 (25)0.08
Positive history of corticosteroid therapy02 (8.3)0.32
Positive history of antibiotic use in the past three months5 (45.5)5 (20.8)0.13
Positive history of surgery4 (36.4)4 (58.3)0.22
Positive history of burning09 (37.5)0.01
Positive history of vascular catheter before blood culture5 (45.5)10 (41.7)0.83
Clinical symptoms
Fever11 (100)19 (79.2)0.10
Tachypnea4 (36.4)10 (41.7)0.76
Decreased consciousness5 (45.5)3 (12.5)0.03
Shivering5 (45.5)3 (12.5)0.03
Cough2 (18.2)3 (12.5)0.65
C-reactive protein0.07
Positive7 (100)7 (63.6)
Negative04 (36.4)
Estimated sedimentation ratio0.41
High4 (57.1)4 (44.4)
Moderate3 (42.9)3 (33.3)
Low0 (0)2 (22.2)

a Values are expressed as No. (%).

b Considered significant at P values < 0.05.

c The results of the chi-square test.

5. Discussion

The present study provided a broad spectrum of information about the characteristics of P. aeruginosa BSI and compared the critical items between dead and alive patients, as well as between those with nosocomial infection and CAI, which have been pointed out as two of the most important outcomes in patients with P. aeruginosa BSI (15-17). As indicated by the present study’s results, the all-cause mortality rate of the studied patients was 45.71%, similar to that reported by McCarthy and Paterson in one year (5). Others have also confirmed the high mortality rate in patients with P. aeruginosa BSI (18, 19). It has been confirmed that inappropriate initial treatment is associated with higher odds of in-hospital mortality and is more frequently observed in the deceased group (20, 21).

This finding aligns with the present study's results, emphasizing the significance of appropriate initial antibiotic treatment in such patients. All the studied cases were resistant to co-trimoxazole, gentamicin, amikacin, cefepime, and ciprofloxacin; more than half of them were sensitive to imipenem, meropenem, ceftazidime, and piperacillin-tazobactam. At the same time, all the 34 isolates were sensitive to colistin. These results are in line with the previous evidence and suggest that P. aeruginosa has become resistant to antibiotics (both MDR and XDR), especially to beta-lactams (7, 22).

The significant effect of appropriate initial empirical antibiotics in bacteremia with P. aeruginosa on patient mortality has been previously emphasized, especially in immunocompromised patients, like those with cancer or neutropenia (6, 23, 24). Some have suggested beta-lactams and amikacin, ciprofloxacin, or colistin as appropriate therapies, while the most appropriate treatment should be based on the local resistance rates (25).

The present study's results showed that all patients who required intubation died. These results propose the higher disease severity and higher MDR/XDR rates in intubated cases with P. aeruginosa BSI. As the most common pathogen causing VAP, P. aeruginosa can cause severe resistant infection and result in a high mortality rate in patients admitted to ICU, especially intubated patients (26, 27). Some have suggested that more resistant serotypes of P. aeruginosa inoculate in the endotracheal tubes, which require specific antibiotics, are responsible for these patients' higher mortality rate (28). Although these results confirm the significance of P. aeruginosa VAP, our results showed a much higher mortality rate in the intubated patients (100%) compared to previous reports (26, 29). The difference could be because they considered VAP while we included patients with bacteremia. Notably, tracheal aspiration cultures showed co-infection with other pathogens, which could be another reason for the high mortality rate of these patients.

About 70% of cases with P. aeruginosa BSI had a nosocomial infection. These results align with the previous evidence, suggesting P. aeruginosa as an important nosocomial pathogen (30). Further analysis in our study showed a significantly higher mortality rate in patients with nosocomial infection compared to those with CAI (66.7% vs. 27.3%). These results, in addition to the higher rate of decreased consciousness in patients with nosocomial infection, showed that patients with nosocomial P. aeruginosa BSI had a more severe resistant infection. Shi et al., in their five-year study showed that patients with nosocomial P. aeruginosa BSI had a significantly higher MDR rate and odds of mortality (18), which is consistent with the present study’s results. Others have also approved nosocomial P. aeruginosa BSI as a significant predictor of mortality (26), confirming the current study's results.

The higher mortality rate of our patients with nosocomial P. aeruginosa BSI compared to previous reports (18) might be attributed to the higher MDR of the pathogen in our study, which has been considered a significant cause of mortality in patients with nosocomial infection (31). Another notable finding in the present study was that all patients with burn had a nosocomial infection. Others have also suggested P. aeruginosa as the most common wound infection pathogen in patients with burns, with a high MDR rate in these cases (32, 33). This finding is in line with the present study’s results, emphasizing considering P. aeruginosa during wound care in patients with burns.

Another finding with a significant difference was the frequency of clinical symptoms, including a higher frequency of tachypnea in the deceased group and a higher rate of shivering in patients with CAI. A wide range of symptoms have been proposed for P. aeruginosa infection, most of which are non-specific (34); therefore, greater attention should be paid to the appropriate diagnosis of this infection and initiation of proper treatment as soon as possible. The first study limitation was the small sample size and selection of the participants from one center, which reduced the generalizability of the results. The second study limitation was the retrospective collection of data from the medical records; any bias during data recording could affect the study’s results. The short study duration was the last limitation of the study.

5.1. Conclusions

Considering the high mortality rate of P. aeruginosa BSI and resistance to multiple antibiotics, especially in patients with nosocomial infection, it is necessary to pay greater attention to the prevention of this infection in hospitals by frequently washing hands, following personal hygiene principles (met by doctors, nurses, visitors, and anyone in contact with the patient), disinfecting hospital environment/equipment, and avoiding unnecessary prescription of antibiotics.

Acknowledgements

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