ORIGINAL ARTICLE 10.1111/j.1469-0691.2005.01305.x Pandrug-resistant Pseudomonas aeruginosa among hospitalised patients: clinical features, risk-factors and outcomes C. Y. Wang 1, J. S. Jerng 1, K. Y. Cheng 1, L. N. Lee 1,2,C.J.Yu 1, P. R. Hsueh 1,2 and P. C. Yang 1 Departments of 1 Internal Medicine and 2 Laboratory Medicine, National Taiwan University Hospital, National Taiwan University College of Medicine, Taipei, Taiwan ABSTRACT Between 1 January 2003 and 31 December 2003, 37 patients had positive cultures of pandrug-resistant Pseudomonas aeruginosa (PDRPA) resistant to all commercially available anti-pseudomonal antimicrobial agents in Taiwan, including anti-pseudomonal penicillins, ceftazidime, fourth-generation cephalosporins, aztreonam, carbapenems, aminoglycosides and ciprofloxacin. Nineteen (51.4%) patients had PDRPA infections, including pneumonia (17 patients), catheter-related bacteraemia (one patient) and anal abscess (one patient). Eighteen patients were classified as having PDRPA colonisation, based on absence of clinical signs or symptoms of infection. In total, 92 isolates were recovered from various specimens, with the majority (85.9%) recovered from respiratory tract secretions (sputa, bronchial washings and pleural effusions), followed by urine (4.3%) and catheter tips (3.3%). Twenty-eight (75.7%) patients yielded cultures of non-pdr P. aeruginosa isolates before isolation of PDRPA, with a mean period between the first isolation of non-pdr P. aeruginosa and the isolation of PDRPA of 128.3 days. Most patients had received b-lactam antibiotics, fluoroquinolones or carbapenems for prolonged periods. Univariate analysis showed that PDRPA infection, male gender and the presence of fever at the time of PDRPA isolation were associated with increased mortality. Keywords Antimicrobial resistance, clinical features, hospitalised patients, pandrug resistance, Pseudomonas aeruginosa, risk-factors Original Submission: 10 April 2005; Revised Submission: 23 May 2005; Accepted: 24 June 2005 Clin Microbiol Infect 2006; 12: 63 68 INTRODUCTION Pseudomonas aeruginosa is one of the main organisms responsible for drug-resistant nosocomial infections, and is one of the leading causes of bacteraemia and pneumonia in hospitalised patients [1,2]. In addition to being intrinsically resistant to several antimicrobial agents, P. aeruginosa acquires resistance readily to conventional anti-pseudomonal antibiotics (i.e., anti-pseudomonal penicillins, ceftazidime, fourth-generation cephalosporins, aztreonam, carbapenems and ciprofloxacin) following prolonged use of these antibiotics in hospitalised patients, particularly patients in intensive care units (ICUs) [3 10]. Corresponding author and reprint requests: P. R. Hsueh, Departments of Internal Medicine and Laboratory Medicine, National Taiwan University Hospital, 7 Chung-Shan South Road, Taipei, Taiwan E-mail: hsporen@ha.mc.ntu.edu.tw Multidrug-resistant (resistant to at least three different classes of antibiotics) P. aeruginosa (MDRPA) strains were first reported in patients with cystic fibrosis [11], and dissemination of these resistant organisms has since been reported among hospitalised patients [12 15]. P. aeruginosa isolates resistant to carbapenems, or resistant to all antibiotics available for clinical use (PDRPA), have been reported to cause nosocomial infections and outbreaks among patients hospitalised in ICUs or burn units [16,17]. At National Taiwan University Hospital (NTUH), the first isolate of PDRPA (formerly MDRPA) was recovered from the wound of a burn patient in December 1996 [17]. Since then, PDRPA isolates have spread widely in NTUH [17,18]. A previous study of 26 PDRPA isolates revealed that 73% of these isolates possessed the bla VIM-3 gene, and that 96% harboured class I integrons [18]. Molecular investigations demonstrated the polyclonal nature of these isolates, Ó 2006 Copyright by the European Society of Clinical Microbiology and Infectious Diseases
64 Clinical Microbiology and Infection, Volume 12 Number 1, January 2006 although clonal dissemination of PDRPA isolates among patients had also occurred [18]. The present study describes the epidemiology, clinical features and outcomes of hospitalised patients colonised or infected with PDRPA, and assesses the risk-factors for acquisition of these pan-resistant organisms. MATERIALS AND METHODS Setting NTUH is a tertiary medical centre located in northern Taiwan. The hospital has 2000 beds, including 150 beds in the ICU. During 2003, 54 574 patients were admitted to the hospital, including 3953 patients admitted to the ICU. respiratory secretions (sputum or bronchial washes) was considered to be the aetiological agent of pneumonia if Gram s stain revealed >25 polymorphonuclear neutrophils (PMNs) and <10 epithelial cells low power field, a predominance of Gram-negative slender bacilli intracellularly or surrounding the PMNs, and if PDRPA was the predominant or pure isolate on blood agar plates. If these criteria were not met, PDRPA was considered to be a coloniser of the respiratory tract. Statistical analysis Proportions were compared using chi-square or univariate analysis to determine the factors influencing prognosis. Differences were considered significant if p was < 0.05. A multivariate analysis on the variables by the backward method was also performed for factors with p < 0.1 in the univariate analysis. Analyses were performed using SPSS v.10.0 software (SPSS Inc., Chicago, IL, USA). Bacterial isolates and susceptibility testing Microbiology records between 1 January 2003 and 31 December 2003 from the NTUH Clinical Bacteriology Laboratory were analysed to identify patients harbouring PDRPA isolates. A PDRPA isolate was defined as being resistant to all commercially available anti-pseudomonal antibiotics in Taiwan (i.e., ceftazidime, cefepime, ticarcillin clavulanate, piperacillin tazobactam, aztreonam, imipenem, meropenem, gentamicin, amikacin, levofloxacin and ciprofloxacin). Standard disk susceptibility tests were performed and interpreted as recommended by NCCLS guidelines [19]. Susceptibility of PDRPA isolates to colistin was also determined using the standard disk-diffusion method [18]. Ticarcillin, piperacillin, cefoperazone, cefoperazone-sulbactam and colistin are not available for clinical use in Taiwan. Patients The medical records of all patients with a PDRPA isolate were reviewed retrospectively. Clinical data collected included demographic characteristics, co-morbid diseases, clinical diagnoses, length of hospital stay, classes and duration of antibiotic use before notification of positive culture results for PDRPA. Data on clinical parameters included signs of sepsis, shock, use of an indwelling catheter, invasive diagnostic and therapeutic procedures, and laboratory examinations. The severity of each patient s clinical condition was evaluated using the multiple organ dysfunction score (MODS) [20]. Patients were classified as immunosuppressed if they had received steroids, chemotherapy for malignancy or immunomodulatory agents (for autoimmune disease or transplantation), or if they had diabetes mellitus, infection with human immunodeficiency virus (HIV), or a malignancy known to suppress autoimmune function (such as lymphoma). Classification of patients as infected or colonised was according to the criteria of the CDC National Nosocomial Infections Surveillance System (NNIS) [21]. Colonisation was defined as the isolation of a pathogen from any site without signs or symptoms of infection. Pneumonia was diagnosed based on the finding of a new or progressive infiltration following chest radiography in a patient meeting at least two of the following criteria: fever >38.3 C or hypothermia <36 C; leukopenia or leukocytosis; and purulent tracheal secretion. PDRPA recovered from RESULTS In total, 37 patients yielded a positive culture of PDRPA from various clinical specimens during the study period. The demographic and clinical characteristics of these patients are summarised in Table 1. Ninety-two isolates of PDRPA were obtained from 75 (81.5%) sputa, four (4.3%) urines, three (3.3%) catheter tips, three (3.3%) surgical wounds, three (3.3%) bronchial washes, two (2.2%) anal swab or stool cultures, one (1.1%) pleural effusion, and one (1.1%) blood culture. Grouped according to the source of the first isolate of PDRPA, the organisms were obtained from 29 (78.4%) sputa, three (8.1%) urines, two (5.4%) catheter tips, one (2.7%) surgical wound, one (2.7%) anal swab or stool culture, and one (2.7%) pleural effusion. Data concerning treatment with specific antibiotics before acquisition of PDRPA are shown in Table 2. The antibiotic used most frequently was ciprofloxacin (20 patients; 54.1%), followed by imipenem (18 patients; 48.6%) and cefepime or ceftazidime (15 patients; 45%). The antibiotics with the longest mean duration of usage were ciprofloxacin (34.4 days), imipenem (29.1 days) and amikacin (25.6 days). All PDRPA isolates were susceptible to colistin, with inhibition zone diameters around the colistin disks of 12 14 mm. Significant factors predicting in-hospital mortality after positive PDRPA culture were gender, infection or colonisation, and fever (Table 3). Age, diabetes mellitus, cancer, heart disease, haemodialysis, renal disease, leukocytosis, shock, disseminated intravascular coagulation, MODS >6 and
C. Y. Wang et al. Pandrug-resistant Pseudomonas aeruginosa 65 Table 1. Demographic and clinical characteristics of 37 patients infected or colonised with pandrug-resistant Pseudomonas aeruginosa (PDRPA) treated at National Taiwan University Hospital in 2003 Characteristic (no. of patients) Infection (n = 19) Colonisation (n = 18) Total (n = 37) Sex (n = 37) Male female, n (%) 15 (78.9) 4 (21.1) 9 (50.0) 9 (50.0) 24 (64.9) 13 (35.1) Age, mean range (years) 62.8 39 90 63.6 19 83 63.2 19 90 Setting ICU non-icu, n (%) 18 (94.7) 1 (5.3) 16 (99.9) 2 (11.1) 34 (91.9) 3 (8.1) SICU MICU SICU MICU, n (%) 9 (47.4) 5 (26.3) 3 (15.8) 8 (44.4) 7 (38.9) 1 (5.6) 18 (48.6) 13 (35.1) 3 (8.1) Underlying disease Immunosuppression, n (%) 12 (63.2) 8 (44.4) 20 (54.1) Malignancy, n (%) 6 (31.6) 4 (22.2) 10 (27.0) Cardiac disease, n (%) 6 (31.6) 7 (38.9) 13 (35.1) Renal disease, n (%) 10 (52.6) 7 (38.9) 17 (45.9) Diabetes mellitus, n (%) 5 (26.3) 7 (38.9) 12 (32.4) Mechanical ventilation, n (%) 14 (73.3) 10 (55.6) 24 (64.9) Type of infection Pneumonia, n (%) 17 (45.9) 17 (45.9) Catheter-related bacteraemia, n (%) 1 (2.7) 1 (2.7) Anal infection, n (%) 1 (2.7) 1 (2.7) Colonisation 18 (48.6) 18 (48.6) PDRPA as the first P. aeruginosa isolate, n (%) 1 (5.3) 8 (44.4) 9 (24.3) Previous P. aeruginosa isolate, n (%) 18 (94.7) 10 (55.6) 28 (75.7) Days between non-pdr P. aeruginosa and PDRPA 173.2 24 914 47.4 14 91 128.3 14 914 isolation, mean range (days) Hospitalisation data Initial ICU admission, n (%) 5 (26.3) 7 (38.9) 12 (32.4) Initial general ward admission, n (%) 14 (73.7) 11 (61.1) 25 (67.6) Total days of hospitalisation, mean range (days) 87.4 33 1045 45.1 11 218 132.5 11 1045 Total days of ICU hospitalisation, mean range (days) 19.4 8 554 18.1 5 135 58.1 5 554 Days of hospitalisation before PDRPA culture positive, 67.1 3 927 20.2 1 135 87.3 1 927 mean range (days) Days of hospitalisation after PDRPA culture positive, 19.8 1 117 24.4 4 193 44.2 1 193 mean range (days) Clinical manifestations Leukocytosis, n (%) 15 (78.9) 11 (61.1) 26 (70.2) Fever, n (%) 11 (57.9) 4 (22.2) 15 (40.5) Shock, n (%) 3 (15.8) 1 (5.6) 4 (10.8) DIC, n (%) 2 (10.5) 0 (0.0) 2 (5.4) Mean MODS on the day of PDRPA culture range 5 0 15 2 0 7 4 0 15 Hospital mortality, n (%) 14 (73.7) 2 (11.1) 16 (43.2) Invasive procedures before PDRPA Urinary catheter, n (%) 18 (94.7) 18 (100.0) 36 (97.3) Central venous catheter, n (%) 18 (94.7) 17 (94.4) 35 (94.6) Arterial catheter, n (%) 16 (84.2) 17 (94.4) 33 (89.2) Pulmonary artery catheter, n (%) 2 (10.5) 2 (11.1) 4 (10.8) Chest tube, n (%) 2 (10.5) 2 (11) 4 (10.8) ICU, intensive care unit; SICU, surgical intensive care unit; MICU, medical intensive care unit; DIC, disseminated intravascular coagulation; MODS, multiple organ dysfunction score. mechanical ventilation were not significant predictors of hospital death. Fig. 1 compares the survival probability of patients with PDRPA infection and patients with PDRPA colonisation. Multivariate analysis (Table 4) showed that fever was the only significant factor predicting in-hospital mortality after removing the gender factor in the backward method. Fever tended to be seen more frequently in males than in females (52% vs. 21%; p 0.090). DISCUSSION Significant predictors of in-hospital mortality after positive PDRPA culture were gender, infection or colonisation, and fever. The greater number of male patients with PDRPA infection may be related to the relatively smaller body size of female patients. In this study, most patients with PDRPA infection were male (15 19; 78.4%) and had fever (11 19; 57.9%) during the infection. In contrast, there was no gender predominance among patients with PDRPA colonisation (male:female ratio = 9 : 9), and fever was also less frequent in this group (4 18; 22.2%). Most of the patients with PDRPA infection had yielded a previous culture of P. aeruginosa (18 19; 94.7%); only one patient yielded PDRPA as the first P. aeruginosa isolate. The time from first isolation of P. aeruginosa to the culture of PDRPA was c. 173 days. Patients with PDRPA infection had a higher mortality rate (14 19; 73.7%), and those who died had an average survival duration of 19 days following a positive PDRPA culture. Most of the fatal cases had received multiple long-course treatments with anti-pseudomonal
66 Clinical Microbiology and Infection, Volume 12 Number 1, January 2006 Table 2. Receipt of antimicrobial agents before notification of a positive culture of pandrug-resistant Pseudomonas aeruginosa Patients with PDRPA colonisation Antimicrobial agent (s) received No. (%) of patients Duration of antibiotic usage, mean range (days) Anti-pseudomonal penicillins Piperacillin-tazobactam 12 (32.4) 10.9 1 27 Ticarcillin-clavulanate 9 (24.3) 9 2 21 Third-generation cephalosporins Ceftazidime 15 (40.5) 23.3 3 90 Flomoxef 7 (18.9) 8.4 2 19 Ceftriaxone 3 (8.1) 4 1 8 Cefotaxime 1 (2.7) 3 Fourth-generation cephalosporins Cefepime 15 (40.5) 24.3 2 179 Cefpirome 2 (5.4) 6.5 4 9 Carbapenems Imipenem 18 (48.6) 29.1 1 146 Meropenem 14 (37.8) 23.2 1 81 Monobactam Aztreonam 4 (10.8) 24.5 3 43 Aminoglycosides Amikacin 13 (35.1) 25.6 3 147 Gentamicin 10 (27.0) 7.8 2 20 Tobramycin 1 (2.7) 20 Fluoroquinolones Ciprofloxacin 20 (54.1) 34.4 2 355 Levofloxacin 4 (10.8) 6.3 1 10 Metronidazole 11 (29.7) 12.1 4 42 Survival probability Hospitalisation days Patients with PDRPA infection Fig. 1. Survival probability for patients with pandrugresistant Pseudomonas aeruginosa (PDRPA) infection and patients with PDRPA colonisation Table 3. Univariate analysis of factors influencing mortality among 37 patients infected or colonised with pandrugresistant Pseudomonas aeruginosa Variable Death total (%) OR of death (95% CI) p Age >60 years 10 23 (43.5) 1.026 (0.268 3.923) 1.00 60 years 6 14 (42.9) 1 Gender Male 13 23 (56.5) 4.767 (1.043 21.787) 0.048 Female 3 14 (21.4) 1 Diabetes mellitus Yes 5 12 (41.7) 0.909 (0.226 3.661) 1.00 No 11 25 (44) 1 Cancer Yes 5 10 (50) 1.455 (0.338 6.251) 0.716 No 11 27 (40.7) 1 Heart disease Yes 4 13 (30.8) 0.444 (0.107 1.846) 0.315 No 12 24 (50) 1 Haemodialysis Yes 8 12 (66.7) 4.250 (0.982 18.395) 0.077 No 8 23 (32) 1 Renal disease Yes 10 17 (58.8) 3.333 (0.856 12.978) 0.104 No 6 20 (30) 1 Infection Yes 14 19 (73.7) 22.400 (3.741 134.141) < 0.001 No 2 18 (11.1) 1 Fever Yes 10 15 (66.7) 5.333 (1.282 22.192) 0.023 No 6 22 (27.3) 1 Leukocytosis Yes 13 26 (50) 2.667 (0.575 12.358) 0.285 No 3 11 (27.3) 1 Shock Yes 3 4 (75) 4.615 (0.432 49.296) 0.296 No 13 33 (39.4) 1 DIC Yes 2 2 (100) 0.400 (0.267 0.600) 0.180 No 14 35 (40) 1 MODS >6 4 7 (57.112) 2.000 (0.378 10.578) 0.437 6 12 30 (40) 1 Mechanical ventilation Yes 11 24 (45.8) 1.354 (0.342 5.360) 0.739 No 5 13 (38.5) 1 DIC, disseminated intravascular coagulation; MODS, multiple organ dysfunction score. Table 4. Multivariate analysis (backward method) of factors influencing mortality among 37 patients with pandrug-resistant Pseudomaonas aeruginosa Variables in the equation p OR of death (95% CI) Step 1 Gender 0.384 2.269 (0.359 14.346) Haemodialysis 0.316 1.753 (0.586 5.245) Infection 0.228 2.891 (0.515 16.241) Fever 0.101 2.901 (0.811 10.370) Step 2 Haemodialysis 0.330 1.717 (0.578 5.096) Infection 0.081 4.049 (0.841 19.501) Fever 0.029 3.774 (1.148 12.406) Step 3 Infection 0.093 3.799 (0.800 18.036) Fever 0.016 4.218 (1.305 13.635) antibiotics before the isolation of PDRPA. These findings suggest that PDRPA infections are mostly endogenous, with relatively few exogenous cases. Previous treatment with anti-pseudomonal antibiotics can suppress P. aeruginosa infection, but fail to eradicate the pathogen completely. As P. aeruginosa develops resistance to antibiotics after a long period of treatment, a lack of response suggests the need for a change to antibiotics to which the organism is still sensitive. In a prospective observational study, Rello et al. [22] reported that most recurrent episodes of P. aeruginosa pneumonia in ventilated patients are associated with the persistence of a strain present in a previous infection. In the present study, nine of 18 colonised patients yielded PDRPA as the first isolate of a P. aeruginosa strain. Patients who were only colonised initially with PDRPA had a far lower mortality rate (2 18; 11.1%), and both of the fatal cases died because of underlying disease, not PDRPA. There appears to be an association
C. Y. Wang et al. Pandrug-resistant Pseudomonas aeruginosa 67 between acquisition of PDRPA and long-term usage of anti-pseudomonal agents and a history of ICU admission. Persistence of a multidrugresistant P. aeruginosa clone in the burns ICU of NTUH hospital has been reported previously [17], which may explain the higher risk of colonisation and infection in this patient group. The use of anti-pseudomonal antibiotics, particularly ciprofloxacin, has been reported previously to be a risk-factor for the emergence of MDRPA in the ICU [23]. Data supportive of this association were also found in the present study. The antibiotics used most widely before positive culture of PDRPA were ciprofloxacin (20 patients; 54.1%), imipenem (18 patients; 48.6%) and meropenem (14 patients; 37.8%). It can be speculated that there is a relationship between the emergence of PDRPA and the use of ciprofloxacin and carbapenems [24], but further investigation of the resistance mechanisms in these isolates is required. Previous studies of risk-factors for multidrugresistant P. aeruginosa nosocomial infection have found that age, a high severity index, a bedridden condition, transfer from other units, nasogastric feeding, urinary catheterisation, and exposure to b-lactams (OR 2.5) or fluoroquinolones (OR 4.1) in the preceding 7 days were linked to nosocomial MDRPA infection among hospitalised patients [25,26]. Exposure to fluoroquinolones (OR 4.7) or surgical procedures (OR 0.5) were linked to the isolation of MDRPA among patients infected by P. aeruginosa. Cao et al. [27] found that mechanical ventilation and previous use of imipenem or meropenem were independent risk-factors for MDRPA infection. These data suggest there may be a relationship between prolonged use of b-lactams, fluoroquinolones and carbapenems, and the development of pandrug resistance in P. aeruginosa. In the present study, pandrug resistance was defined as resistance to all commercially available antibiotics tested (i.e., ceftazidime, cefepime, ticarcillin clavulanate, piperacillin tazobactam, aztreonam, imipenem, meropenem, gentamicin, amikacin, levofloxacin and ciprofloxacin). Colistin has anti-pseudomonal activity and has been used previously, either intravenously or in an aerosol form, for treatment of pneumonia caused by MDRPA [28,29]. Colistin was not available in Taiwanese hospitals at the time of this study, and is mostly used in Taiwan in veterinary practice, and in livestock and poultry farming. The PDRPA isolates tested in this study were all susceptible to colistin, indicating that this agent may be an alternative for the treatment of PDRPA infections. 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