Clinical Microbiology and Infectious Diseases Department, Hospital General Universitario Gregorio Marañón, Doctor Esquerdo 47, 28006 Madrid, Spain
Received 1 July 2004; returned 24 August 2004; revised 9 November 2004; accepted 10 November 2004
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Abstract |
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Candida krusei fungaemia is an uncommon entity described in immunocompromised patients previously exposed to azole agents.
Methods:
From 1988 to 2003, 13 episodes of C. krusei fungaemia (2.3% of all fungaemias) were detected in our institution and compared with 39 Candida albicans controls. Susceptibility testing was carried out with the modified microdilution method according to NCCLS recommendations.
Results:
Underlying conditions were: HIV infection (4), haematological malignancies (4), organ transplantation (2), abdominal surgery (2) and lactose intolerance (1). Nine patients (69%) were not neutropenic. In comparison with C. albicans, patients with C. krusei infection had more commonly received antifungal agents (54% versus 15%, P=0.006), had a haematological disease (31% versus 3%, P=0.03), or a transplant (15% versus 3%, P=0.08), were on corticosteroids (47% versus 13%, P=0.01) and were neutropenic (31% versus 0%, P < 0.001). Patients with C. albicans had more surgical interventions (41% versus 15%, P=0.09) and bladder catheters (61% versus 31%, P=0.05). The most common origin for C. albicans was a catheter (41% versus 0%; P=0.006) whereas for C. krusei the most common origin was unknown (69% versus 20%; P=0.001). C. krusei presented more commonly with skin lesions in neutropenic patients (23% versus 5%; P=0.05). Multivariate analysis of these differential characteristics showed that the only factor that independently predicted the presence of C. krusei fungaemia was the administration of antifungal agents before the fungaemia (RR: 6.4; P=0.009; 95%CI 1.625.99). Overall mortality of C. krusei fungaemia was 38% (C. albicans 49%). Except for voriconazole (MIC90 0.125 mg/L), azoles and 5-flucytosine had poor activity against C. krusei, whereas amphotericin (MIC90 1 mg/L) and LY-303366 (MIC90 0.06 mg/L) showed good activity.
Conclusion:
C. krusei fungaemia incidence remains low despite widespread use of azoles. It may occur outside the setting of cancer patients with previous antifungal use. The presence of skin lesions should be a warning sign.
Keywords: candidosis , candidaemia , transplantation , HIV , neutropenia
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Introduction |
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In recent years, a sharp increase in the incidence of infections caused by non-albicans Candida (NAC) species has been reported.4 C. krusei has been described in severely ill patients previously exposed to azole agents. It is claimed to be intrinsically resistant to fluconazole and may have reduced susceptibility to amphotericin B. Few series have specifically addressed the epidemiological and clinical characteristics of C. krusei and most included only patients with cancer57 or bone marrow transplantation (BMT).8 We compared all our C. krusei patients with C. albicans fungaemia patients (controls) in order to identify the risk factors and clinical characteristics of C. krusei fungaemia. We randomly selected three controls for each case only matched by year of occurrence.
The antifungal susceptibility pattern of C. krusei is also provided.
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Materials and methods |
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Between 1988 and 2003, 569 episodes of significant fungaemias were detected in our 1750 bed institution, and 13 cases corresponded to C. krusei (2.3%). These isolates of Candida krusei recovered from blood cultures (stored at 70°C) in our microbiology laboratory were included in the study.
Clinical reports of the patients with an isolate of C. krusei were reviewed according to a pre-established protocol and each one was compared with three cases of C. albicans fungaemia. The controls were only matched with respect to year of positive blood culture and selected by means of a random number table.
A patient was considered to have significant candidaemia if C. krusei or C. albicans was isolated from at least one blood culture specimen associated with fever or signs of infection. Source of fungaemia was defined as a culture-positive site or a clinically evident site of infection. Neutropenia was defined as an absolute neutrophil count < 500 cells/mm3. Complications of fungaemia were defined as endocarditis, endophthalmitis, skin infiltrates etc. following fungaemia. Related mortality was defined as death occurring within 5 days of the fungaemia with concurrent signs of active infection and no other apparent cause.
From 1988 to October 1995, blood samples were processed by using the automated system BACTEC-NR (Becton Dickinson, MD, USA) and thereafter, with the BACTER-9240 instrument (Becton Dickinson). In the first period, all vials were incubated at 35°C for 7 days, while in the second period vials were shaken continuously for 5 days.
Statistical methods
Categorical data were analysed using a 2 or Fisher exact test (two-tailed), and the unpaired Student's t-test was used for continuous variables. Stepwise logistic multivariate analysis to identify differential characteristics of C. krusei fungaemia was carried out. Variables with a P value < 0.1 in the univariate analysis were included in the multivariate model. All comparisons were considered statistically significant for P values of 0.05 or less. Statistical analysis was carried out using the SPSS software system.
Susceptibility analysis
Isolates were thawed and subcultured onto CHROMagar Candida plates (Tec-Laim, Madrid, Spain) for 5 days at 35°C to identify possible mixed infections and to assure purity. Identification was confirmed by the Vitek and API ID 32 C (bioMérieux, St. Louis, MO, USA) systems as recommended by the manufacturer. The following antifungals were included in the study: amphotericin B, 5-flucytosine, ketoconazole, fluconazole, itraconazole, voriconazole and LY-303366. The susceptibility study was carried out using a modified microdilution method according to NCCLS recommendations (document M-27A),9 using antibiotic medium 3 for amphotericin B and RPMI-2% glucose medium for the remaining antifungals.10,11 The micropanels were incubated for 2448 h at 35°C. Endpoint readings were defined visually as a full (amphotericin B) or prominent inhibition of growth (for the remaining antifungals). The interpretive breakpoints defined by NCCLS for antifungals are as follows: 5-flucytosine (susceptible, <8 mg/L; intermediate, 816 mg/L; and resistant, >16 mg/L), fluconazole (susceptible, <16 mg/L; susceptible dependent upon dose, 1632 mg/L; and resistant, >32 mg/L) and itraconazole (susceptible, <0.25 mg/L; susceptible dependent upon dose, 0.250.5 mg/L; and resistant, >0.5 mg/L). For the remaining antifungals, the following interpretative breakpoints were used: amphotericin (susceptible, <4 mg/L; and resistant, >2 mg/L) and ketoconazole (susceptible, <0.25 mg/L; susceptible dependent upon dose, 0.250.5 mg/L; and resistant, >0.5 mg/L). No breakpoints were used for voriconazole and LY-303366.
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Results |
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Susceptibility testing was carried out on the 13 C. krusei strains. The MICs are shown in Table 1. With the exception of voriconazole (MIC90 0.125 mg/L), azoles and 5-flucytosine did not have good activity against C. krusei (for fluconazole, all isolates have to be considered resistant irrespective of the MIC). On the other hand, amphotericin (MIC90 1 mg/L) and the antifungal LY-303366 (MIC90 0.06 mg/L) showed good activity (Table 1).
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Seven patients had received antifungal drugs (non-absorbable or systemic) before the fungaemia (three nystatin, three fluconazole, and one developed a breakthrough fungaemia while receiving itraconazole). Therapy consisted of amphotericin B (nine patients) and four patients did not receive treatment. Therapy was started a median of 2.3 ± 2.6 days after blood cultures were obtained. Three patients recovered despite not receiving antifungal therapy: a neonate with diarrhoea and lactose intolerance, an HIV patient who developed a transient fungaemia after a self-administration of illegal intravenous (iv) drugs and a patient with a urinary tract infection.
Overall mortality was 38.5%, but one out of five deaths was unrelated to the fungaemia (related mortality 30.7%) (Table 1).
For the identification of differential characteristics of C. krusei fungaemia, we compared each C. krusei patient with three randomly selected C. albicans patients (controls). The differences found in the univariate analysis are shown in Table 3. Patients with C. krusei had more commonly received antifungal agents before the fungaemia (54% versus 15%, P=0.006), had an underlying haematological disease (31% versus 3%, P=0.03), or a transplant (15% versus 3%, P=0.08), were on corticosteroids (47% versus 13%, P=0.01) and were neutropenic (31% versus 0%, P < 0.001). Patients with C. albicans had more frequently undergone a surgical intervention (41% versus 15%, P=0.09) and had indwelling bladder catheters (61% versus 31%, P=0.05).
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There were no significant differences regarding therapy and evolution. We could not find significant differences between the overall mortality rate of C. albicans and C. krusei fungaemias (49% versus 38%; P=0.5), nor between their related mortality (36% versus 31%, P=0.7). Overall, the presence of skin lesions due to Candida fungaemia was a protective factor (no mortality versus 49%, P=0.03), whereas indwelling bladder catheter (mortality rate 57% versus 29% P=0.04), intravenous catheter (50% versus 12%, P=0.04) and septic shock (100% versus 34%; P=0.001) were related to a poorer outcome. Patients with previous surgery (61% versus 35%, P=0.07) and total parenteral nutrition (60% versus 34%, P=0.07) also showed a trend towards higher mortality.
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Discussion |
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Most reports of C. krusei fungaemia are from cancer centres or units and neutropenia is present in more than 70% of such patients.5,8 Very few cases have been described in non-cancer patients. In a retrospective 5 year review, Iwen et al. identified 203 cases of invasive candidiasis of which eight cases were caused by C. krusei. Four of the patients involved had leukaemia, two had breast cancer, one had end-stage liver disease, and one had suffered abdominal trauma.14 C. krusei fungaemia is extremely rare in intensive care units2 and after solid organ transplantation (SOT). We describe two cases in SOT recipients and have been able to find another three in the literature.1517 In our series, we had three episodes in HIV-positive patients and four others have been reported.18,19 Our episode in a baby with massive diarrhoea and lactose intolerance is exceptional. Fungal overgrowth has been related to diarrhoea, mainly in children,20,21 and intestinal mucosal lesions may be the origin of the fungaemia.
The clinical condition of our patients probably represents the overall spectrum of C. krusei fungaemia in a large institution better than series from cancer centres. When we compared patients with C. krusei and C. albicans fungaemia, patients with C. krusei had more commonly received previous antifungal agents (54% versus 15%, P=0.006), suffered more haematological diseases (31% versus 3%, P=0.03), had received a transplant (15% versus 3%, P=0.08), were on corticosteroids (47% versus 13%, P=0.01) and were neutropenic (31% versus 0%, P < 0.001). Patients with C. albicans had more frequently undergone a surgical intervention (41% versus 15%, P=0.09) and had indwelling bladder catheters (61% versus 31%, P=0.05).
In our series, C. krusei fungaemia was predominantly nosocomial (69%) and was acquired in the community in four cases (three iv drug abusers and one baby with diarrhoea and lactose intolerance). Abbas et al. reported that eight (14%) episodes of C. krusei fungaemia in cancer patients were considered to be community-acquired.5 C. krusei has been detected on the hands of healthcare workers (potential reservoirs for nosocomial transmission),22 but there is no evidence of nosocomial dissemination.23
It is difficult to argue against the role of prior prophylaxis with azole derivatives (mainly fluconazole) as a predisposing condition for C. krusei infection.12,24 Prophylaxis with fluconazole increases colonization by C. krusei.6,12 The proportion of patients with C. krusei fungaemia that had received previous fluconazole ranges from 50% to 90% in different series,5,13,23,25,26 whereas only 510% of patients with C. albicans fungaemia had received fluconazole in other studies.7,23 In our series, seven patients had received antifungals before the fungaemia (3 nystatin, 3 fluconazole, and one developed a breakthrough fungaemia while receiving itraconazole). Nevertheless, in our opinion and that of other authors, the absence of prior fluconazole treatment should not lead physicians to exclude C. krusei fungaemia.8,14,23,2729
Clinical presentation of C. krusei differed according to the underlying condition. Haematological patients had a higher incidence of metastatic lesions than HIV-infected or SOT patients. When we compared patients with C. krusei and C. albicans fungaemia, we found significant differences in the clinical presentation. C. krusei presented more commonly with skin lesions (23% versus 5%; P=0.05) or other septic metastases (23% versus 5%; P=0.05). Other authors have also found a high proportion (37%) of disseminated infections when C. krusei fungaemia is detected in cancer patients.5 However, the significantly higher proportion of patients with skin lesions among C. krusei infections may have been influenced by the different underlying conditions in the two groups, since other Candida species have also been described to cause skin dissemination in neutropenic patients.
The portal of entry of C. krusei fungaemia was different from that of the C. albicans patients. Vascular catheter-related fungaemia predominated in C. albicans cases (41% versus 0%; P=0.006) and primary fungaemia in those caused by C. krusei (69% versus 20%; P=0.001), which suggests that the gastrointestinal tract was the most probable source. However, GI-tract colonization data were not available.
All our C. krusei isolates were intrinsically fluconazole-resistant, the amphotericin B MIC90 was 1 mg/L and the voriconazole MIC90 was 0.12 mg/L. In our study, eight patients received amphotericin B for therapy (two deaths). C. krusei has been reported to cause breakthrough fungaemia during treatment with fluconazole or ketoconazole,30 even in patients treated with amphotericin B (0.30.5 mg/kg per day for a mean of 13 days).5
Some authors have suggested that C. krusei may be less virulent than C. albicans, but in most series C. krusei has a higher mortality than the other species.5,7,13 Mortality is particularly high in patients with persistent fungaemia, persistent neutropenia and septic shock.5,8
We could not find significant differences regarding therapy and evolution between C. krusei and C. albicans fungaemia. The overall mortality rate of C. albicans fungaemia was 49% and for C. krusei, it was 38% (P=0.2). Our analysis of both C. albicans and C. krusei fungaemia revealed that the underlying conditions that were poor prognostic factors were the presence of bladder and intravenous catheters and septic shock.
The limitations of our study are that only C. albicans and C. krusei were compared and that we could not match patients by the presence of neutropenia, since C. albicans has completely disappeared from haematological patients in our centre, probably due to the use of prophylaxis.
In summary, our study suggests that the evolution of C. krusei fungaemia may be stable in the overall perspective of non-selected units for the care of cancer patients. Clinical hints enable it to be distinguished from C. albicans fungaemia and, at least in our experience, mortality is comparable to that caused by C. albicans fungaemia.
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Acknowledgements |
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References |
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