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Epidemiology, risk factors and outcomes of Candida albicans vs. non-albicans candidaemia in adult patients in Northeast China

Published online by Cambridge University Press:  25 September 2019

Wei Zhang
Affiliation:
Department of Respiratory Medicine, Shengjing Hospital of China Medical University, No. 36 Sanhao Street, Heping District, Shenyang, Liaoning, 110004, China
Xingpeng Song
Affiliation:
Department of Respiratory Medicine, Shengjing Hospital of China Medical University, No. 36 Sanhao Street, Heping District, Shenyang, Liaoning, 110004, China
Hao Wu
Affiliation:
Department of Respiratory Medicine, Shengjing Hospital of China Medical University, No. 36 Sanhao Street, Heping District, Shenyang, Liaoning, 110004, China
Rui Zheng*
Affiliation:
Department of Respiratory Medicine, Shengjing Hospital of China Medical University, No. 36 Sanhao Street, Heping District, Shenyang, Liaoning, 110004, China
*
Author for correspondence: Rui Zheng, E-mail: [email protected]
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Abstract

This study aimed to evaluate the clinical characteristics, risk factors and outcomes of adult patients with candidaemia caused by C. albicans vs. non-albicans Candida spp. (NAC). All adult hospitalised cases of candidaemia (2012–2017) at a tertiary hospital in Shenyang were included in the retrospective study, and a total of 180 episodes were analysed. C. parapsilosis was the most frequently isolated species (38.3%), followed by C. albicans (35.6%), C. glabrata (13.9%), C. tropicalis (10%) and others (2.2%). As initial antifungal therapy, 75.0%, 3.9%, 5.6% and 2.2% of patients received fluconazole, caspofungin, micafungin and voriconazole, respectively. Multivariate analyses revealed that total parenteral nutrition was associated with an increased risk of NAC bloodstream infections (BSI) (OR 2.535, 95% CI (1.066–6.026)) vs. C. albicans BSI. Additionally, the presence of a urinary catheter was associated with an increased risk of C. albicans BSI (OR 2.295 (1.129–4.666)) vs. NAC BSI. Moreover, ICU stay (OR 4.013 (1.476–10.906)), renal failure (OR 3.24 (1.084–9.683)), thrombocytopaenia (OR 7.171 (2.152–23.892)) and C. albicans (OR 3.629 (1.352–9.743)) were independent risk factors for candidaemia-related 30-day mortality, while recent cancer surgery was associated with reduced mortality risk (OR 26.479 (2.550–274.918)). All these factors may provide useful information to select initial empirical antifungal agents.

Type
Original Paper
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution, and reproduction in any medium, provided the original work is properly cited.
Copyright
Copyright © The Author(s) 2019

Introduction

Candida is an important causative organism of bloodstream infections (BSIs). Over the last two decades, candidaemia has been reported as the fourth and seventh most common healthcare-associated BSI in US and European studies, respectively [Reference Wisplinghoff1, Reference Marchetti2]. In a recent multicentre point-prevalence survey, Candida species emerged as the most common bloodstream pathogen and accounted for up to 22% of healthcare-associated BSIs [Reference Magill3]. Additionally, candidaemia remains associated with high-mortality rates, prolonged hospital stays and increased healthcare costs [Reference Wisplinghoff1, Reference Zaoutis4Reference Hassan7]. Overall, mortality rates among patients range from 19.6% to 67% worldwide [Reference Wisplinghoff1, Reference Chakrabarti6, Reference Zhang8Reference Sbrana12] and the major risk factors for candidaemia include receipt of parenteral nutrition, exposure to broad spectrum antibiotics, presence of central venous catheter (CVC), prior surgery and ICU stay [Reference Das13, Reference Pappas14]. Even though C. albicans overall accounts for the majority of Candida spp. causing candidaemia, the proportion of non-albicans Candida (NAC) spp. is rising and has even exceeded that of C. albicans in some recent studies from Europe, Asia and America [Reference Zhang8Reference Diekema10, Reference Barchiesi15Reference Ding17].

In general, the most frequently isolated NAC spp. from candidaemia cases include C. glabrata, C. parapsilosis, C. tropicalis and C. krusei [Reference Puig-Asensio5, Reference Diekema10, Reference Guinea16, Reference Ding17]. Reduced in vitro susceptibility to antifungal agents has been observed among several NAC spp., which may present a therapeutic challenge. C. glabrata and C. krusei tend to be less susceptible to azole agents than other Candida spp., while C. parapsilosis shows the highest minimum inhibitory concentrations (MICs) to the echinocandins than other Candida spp. [Reference Wang, Xu and Hsueh18, Reference Bassetti19]. Several retrospective studies suggest that delayed initiation of antifungal therapy after the onset of candidaemia is associated with increased mortality, which highlights the importance of early appropriate antifungal therapy [Reference Garey20]. The local epidemiology and variable antifungal susceptibility profiles of different Candida spp. are critical for the selection of antifungal therapy prior to culture and susceptibility data being available.

However, risk factors related to NAC BSI, and the distribution and antifungal susceptibility of Candida spp. from BSI differ geographically, whereas data on risk factors, antifungal susceptibility and outcomes in C. albicans and NAC BSIs remain scarce in Northeast China. Therefore, this retrospective study was performed to compare clinical characteristics and outcomes between C. albicans and NAC candidaemia, analyse prognostic factors and determine risk factors related to C. albicans or NAC at a tertiary hospital in Shenyang.

Patients and methods

Subjects and study design

This retrospective observational study was undertaken from January 2012 to October 2017 at a tertiary grade A comprehensive hospital in Shenyang, China. The setting is a China Medical University-affiliated teaching hospital with over 6000 beds currently. All adult hospitalised cases of candidaemia were included in the study. The following data were collected from medical records: age, sex, major underlying diseases and predisposing factors, surgical and invasive procedures, complications, blood tests, isolated Candida spp., antifungal susceptibility, antifungal therapy, duration of hospitalisation and final outcome. The study was approved by the Medical Ethics Committee in Shengjing Hospital of China Medical University (reference number 2018PS506K).

Microbiological methods

Blood samples were drawn under sterile conditions and processed using a BD BACTEC 9120 or BD BACTEC FX400 (Becton Dickinson Diagnostic Instrument Systems, Sparks, USA) blood culture system. After the identification of Candida isolates utilising the VITEK 2 YST (bioMérieux, Durham, USA) card, antifungal susceptibility testing of fluconazole, itraconazole, voriconazole and amphotericin B was determined using a ATB FUNGUS 3 (BIOMERIEUX) strip following the manufacturer's instructions. The interpretation of antifungal susceptibility of fluconazole, itraconazole, voriconazole and amphotericin B against C. albicans, C. glabrata, C. parapsilosis, C. tropicalis and C. krusei was performed by applying clinical breakpoints (CBPs) defined by the Clinical Laboratory Standards Institute (CLSI) [21] or European Committee on Antimicrobial Susceptibility Testing (EUCAST) [22]. MIC CBPs for echinocandins and 5-fluorocytosine by the CLSI or EUCAST were not available at the time, and therefore are not reported in the current study.

Clinical definitions

An episode of candidaemia was defined as the isolation of a Candida spp. recovered from the first blood culture in a patient with accompanying clinical signs and symptoms. Subsequent positive cultures from the same patient were considered as a new episode if the interval between the two episodes was more than 30 days. The onset of candidaemia was taken as the day the first positive blood culture for Candida spp. was drawn from the patient. Except for recent surgery, defined as y within 3 months, the predisposing factors occurred within 30 days prior to the onset of candidaemia. Elderly patients were defined as those 65 years of age or older. Laboratory test results were obtained at the onset of candidaemia. Renal failure was defined as a serum creatinine above 104 µmol/l. Anaemia was defined as a haemoglobin level below 110 g/l for women and 130 g/l for men. Hypoalbuminaemia was defined as albumin <30 g/l and hyponatraemia as a serum sodium concentration <135 mmol/l. Leukopaenia was defined as a peripheral white blood cell count less than 4 × 109/l and thrombocytopaenia as a platelet count <100 × 109/l. Antifungal therapy was defined as empirical if started before susceptibility test results were obtained and as targeted thereafter. The outcome was registered after 30 days from the onset of candidaemia.

Statistical analysis

Continuous variables were expressed as the mean ± standard deviation in normally distributed data or as the median and interquartile range (25th–75th percentiles) in data with non-normal distributions, respectively. Categorical variables were reported as number (%). Continuous variables were compared using the Student's t-test or Mann–Whitney U-test according to the normality of distribution. Categorical variables were compared using the χ 2 test or χ 2 continuity correction test. Variables with P-values of ⩽0.10 including age, sex, underlying diseases and predisposing factors were entered into the multivariable logistic regression model to identify factors associated with NAC vs. C. albicans candidaemia. All variables with P-values of ⩽0.10 in the univariate analysis of factors associated with mortality were included in the multivariate logistic regression model to identify independent factors associated with mortality. Two-sided P-values of <0.05 were considered statistically significant. Statistical analyses were carried out with SPSS (IBM SPSS Statistics 21.0).

Results

During the study period, 188 episodes of candidaemia in 187 adult patients were initially identified. Two patients were excluded from further analysis because they had a single positive blood culture for Candida spp. without signs and symptoms of infection. One blood culture was considered to be contaminated due to simultaneous isolation of Staphylococcus epidermidis with C. glabrata. Five patients were lost to follow-up within 30 days from the onset of candidaemia and were therefore excluded. Thus, the remaining 180 episodes of candidaemia from 179 adult patients were included in the study. Over the study period, 74 patients developed candidaemia in the first 3-year period (2012–2014) (74/2845, 26.0/1000), which did not evidently differ from cases per hospitalisation-days in the second 3-year period (2015–2017) (106/3769, 28.1/1000) (P = 0.611).

Distribution of Candida spp. causing bloodstream infection

Among the 180 Candida isolates from blood cultures, C. parapsilosis was the predominant species (69/180, 38.3%), followed by C. albicans (64/180, 35.6%), C. glabrata (25/180, 13.9%), C. tropicalis (18/180, 10%), C. krusei (2/180, 1.1%) and C. famata (2/180, 1.1%). Mixed infections with two or more Candida spp. were not observed. Figure 1 shows the distribution of the Candida spp. from candidaemia cases from 2012 to 2017. NAC accounted for the majority and there were no substantial changes regarding species distribution patterns between C. albicans and NAC over the study period. The proportion of C. parapsilosis BSI in surgical patients evidently increased compared with non-surgical patients (59/138 (42.8%) vs. 10/42 (23.8%), P = 0.027) (Table 1).

Fig. 1. Distribution of Candida species isolates during the study period.

Table 1. Distribution of Candida species among patients according to prior surgery or history of solid tumours

Patient characteristics

The mean age of all episodes was 61.8 ± 15.9 years and 122/180 (67.8%) were male. C. albicans and NAC spp. were responsible for 64/180 (35.6%) and 116/180 (64.4%) cases, respectively. Among surgical patients, 138/180 (76.7%) episodes were documented. Other common predisposing factors for candidaemia included prior antibiotics exposure (163/180, 90.6%) and total parenteral nutrition (TPN) (152/180, 84.4%). Nonetheless, there were no statistical differences between C. albicans and NAC cases for the proportion of surgical patients and those who received prior antibiotics treatment. At the onset of candidaemia, 148/180 (82.2%) patients presented with anaemia. Moreover, the overall low frequency of fluconazole resistance to Candida BSI isolates (12/180, 6.7%) is noteworthy.

The comparison of demographics and clinical data of patients with C. albicans vs. NAC candidaemia is summarised in Table 2. NAC-infected patients were more likely to have hyponatraemia than those infected with C. albicans (50/116 (43.1%) vs. 18/64 (28.1%), P = 0.047). Likewise, significant differences between NAC and C. albicans patients with BSI were evident for the presence of a urinary catheter (68/116; 58.6% and 47/64; 73.4% P = 0.048), the in vitro susceptibility of isolates to fluconazole (72/116; 62.1% and 57/64; 89.1% P < 0.001) and the 30-day mortality (23/116; 19.8% and 23/64; 35.9% P = 0.018). Other statistically significant elevated differences between the two groups were the frequency of current and former smokers (40/116; 34.5%, and 14/64; 21.9% P = 0.077) and TPN (102/116; 88%, and 50/64; 78.1%, and P = 0.082).

Table 2. Demographics and clinical characteristics of patients with C. albicans and non-albicans candidaemia

ICU, intensive care unit; TPN, total parenteral nutrition; CVC, central venous catheter; LOS, length of hospital stay.

Multivariate analysis (Table 3) confirmed that TPN was significantly associated with an increased risk of NAC candidaemia (odds ratio (OR) 2.535; 95% confidence interval (CI) 1.066–6.026; P = 0.035), whereas the presence of a urinary catheter was distinctly associated with an increased risk of C. albicans infection (OR 2.295; CI 1.129–4.666; P = 0.022). Current and former smokers were more associated with NAC candidaemia (OR 1.824; CI 0.885–3.756; P = 0.103), but the trend did not reach statistical significance.

Table 3. Multivariate logistic regression analysis of factors associated with an increased risk of candidaemia due to NAC species vs. C. albicans

B, coefficient; s.e., standard error; Wald test statistic; OR, odds ratio; CI, confidence interval; TPN, total parenteral nutrition.

Antifungal susceptibility testing

Table 4 shows that of the 180 Candida isolates tested for antifungal susceptibility, 12 (6.7%) exhibited resistance to fluconazole, including C. albicans (2/64; 3.1%), C. parapsilosis (2/69; 2.9%), C. tropicalis (6/18; 33.3%) and both isolates of C. krusei. Overall, voriconazole resistance was uncommon (10/180; 5.6%) and except for one isolate of C. glabrata, all other Candida isolates were susceptible to amphotericin B. According to the species-specific CBPs, all 25 isolates of C. glabrata showed susceptible-dose dependence (SDD) to fluconazole.

Table 4. In vitro antifungal susceptibility of Candida species isolated from 180 candidaemia episodes

a Except lack of C. famata specific CBPs, CBPs for Candida susceptibility to fluconazole and voriconazole were obtained from CLSI [21], while CBPs for susceptibility of Candida against itraconazole and amphotericin B were from EUCAST [22].

b MIC 50 and 90 values were not calculated for antifungal drugs against C. krusei and C. famata due to the small number of C. krusei and C. famata cases.

c Isolates of C. krusei are considered to be intrinsically resistant to fluconazole. S, susceptible; I, intermediate; SDD, susceptible-dose dependent; R, resistant; NA, non-applicable.

Therapy, outcomes and risk factors associated with mortality

The majority of patients (135/180, 75.0%) received fluconazole as first line treatment; caspofungin, micafungin and voriconazole were prescribed initially in 7/180 (3.9%), 10/180 (5.6%) and 4/180 (2.2%) of episodes, respectively. The overall 30-day mortality rate was 25.6% and for patients receiving either targeted, empirical, or no antifungal therapy, the 30-day mortality rates were 24.3% (9/37), 24.6% (29/118) and 32.0% (8/25), respectively, with no statistical difference between the therapy groups (P = 0.728). However, the proportion of patients who had not received antifungal therapy did not significantly differ for those who died or survived within 30 days.

On univariate analysis (Table 5), a lower proportion of surgical patients (P = 0.085), and an increased proportion receiving mechanical ventilation (P = 0.096) were observed in patients dying within 30 days, although not statistically significant. By multivariate regression analysis, four independent risk factors for death were identified: ICU stay (OR 4.013; CI 1.476–10.906; P = 0.006), renal failure (OR 3.24; CI 1.084–9.683; P = 0.035), thrombocytopaenia (OR 7.171; CI 2.152–23.892; P = 0.001) and the isolation of C. albicans (OR 3.629; CI 1.352–9.743; P = 0.011), while recent cancer surgery was associated with decreased mortality (OR 0.038; CI 0.004–0.392; P = 0.006) (Table 6).

Table 5. Univariate analysis of factors associated with 30-day mortality of patients with candidaemia

ICU, intensive care unit; TPN, total parenteral nutrition; CVC, central venous catheter; LOS, length of hospital stay.

Table 6. Multivariate logistic regression analysis of risk factors associated with 30-day mortality of patients with candidaemia

B, coefficient; s.e., standard error; Wald test statistic; OR, odds ratio; CI, confidence interval; ICU, intensive care unit; CVC, central venous catheter.

Discussion

The distribution of Candida spp. associated with candidaemia varies greatly in different regions of the world. In recent years, some studies [Reference Zhang8Reference Diekema10, Reference Barchiesi15Reference Ding17] have observed a shift from the more antifungal susceptible type species C. albicans towards NAC spp., and this is corroborated by the findings of this 6-year study where NAC isolates accounted for the majority (64.4%) of all adult candidaemia episodes. Likewise, we found C. parapsilosis to be the most prevalent NAC species (38.3%) which accords with a report from Mexico of 37.9% in 398 patients of all ages during a 3-year surveillance program from five hospitals [Reference Gonzalez, Elizondo and Ayala23]. Moreover, there are several other reports of C. parapsilosis as the most frequent NAC species (20–25%) from blood cultures in Spain [Reference Puig-Asensio5, Reference Bassetti19], Italy [Reference Barchiesi15], Latin America [Reference Pfaller24] and Shanghai, China [Reference Yang9, Reference Wu25]. The second most common NAC spp. in the current study was C. glabrata (13.9%), which has also been commonly recorded in studies from the USA [Reference Diekema10], the UK [Reference Das13], Greece [Reference Dimopoulos26], Beijing, China [Reference Ding17] and Taiwan [Reference Chi27]. In contrast, C. tropicalis ranked as the third most common in our series (10%) but was the most frequent NAC isolate in other studies in China, notably Nanjing [Reference Ma28], Chongqing [Reference Zhang8], Shanghai [Reference Wu29], Shandong [Reference Wang30] and Taiwan [Reference Hii31]. The reasons for the varied species distribution and frequency remain unclear but patient demographics and underlying medical conditions are most likely contributory factors [Reference Guinea16, Reference Bassetti19]. The higher frequency of C. parapsilosis BSI recorded here in surgical patients clearly warrants further investigation.

Several possible risk factors have been previously identified for the development of NAC candidaemia and include prior antifungal exposure, malignancy, immunosuppressive therapy, abdominal surgery [Reference Al-Rawahi and Roscoe32], presence of CVCs [Reference Dimopoulos26], artificial surgical implants [Reference Ding17], head trauma and bacterial sepsis [Reference Wu29]. Our finding of an association of an indwelling urinary catheter and a higher risk of BSI caused by C. albicans vs. NAC is consistent with other studies [Reference Alp33]. Multivariate analysis also confirmed that TPN was associated with an increased risk of NAC spp., compared with C. albicans spp., but this is in contrast with Chow et al. [Reference Chow34] who linked TPN with a decreased risk of BSI caused by NAC spp., vs. C. albicans. In the current study, C. parapsilosis accounted for 59.5%, of all NAC isolates whereas in Chow's series [Reference Chow34], C. glabrata (49%) was more than twice as frequent as C. tropicalis (19%) or C. parapsilosis (18%), which may explain the different findings. Frequent usage of TPN has been linked with C. parapsilosis candidaemia compared with C. albicans, as well as a negative association with C. tropicalis [Reference Chen35]. Therefore, we speculate that the possible reason for divergent views may be the variable proportion of Candida spp. in the local epidemiological setting.

Smoking increases susceptibility to a wide range of bacterial and viral infections [Reference Bagaitkar, Demuth and Scott36] as well as oral candidiasis in HIV infected adults [Reference Chattopadhyay and Patton37]. Based on pooled data from contemporary cohort studies in the USA, the risk of death from infections in current smokers is more than twice that of individuals who have never smoked [Reference Carter38]. However, data on invasive candidiasis and candidaemia in adult smokers remain scarce. Here, we explored the role of smoking in NAC and C. albicans BSI. Although, by multivariate analysis, current and former smoking was not independently associated with the occurrence of NAC BSI, it was likely to be a predictive factor for NAC candidaemia as according to our data current and former smokers had an increased risk for NAC BSI, but no significant relationship was found between smoking and death due to candidaemia. More epidemiological, clinical and mechanistic approaches are needed to study further the impact of smoking in such patients.

C. albicans blood isolates showed significantly greater susceptibility to fluconazole (89.1%) than NAC isolates (62.1%) (P < 0.001) by applying the species-specific new CBPs. In contrast to the overall high-fluconazole susceptibility rate of C. parapsilosis (88.4%) and C. tropicalis (61.1%) recorded here, some studies from other cities in China have reported relatively reduced fluconazole susceptibility in their corresponding Candida spp. For example, a survey from Nanjing reported that only 74.2% of C. albicans, 57.7% of C. parapsilosis, 9.1% of C. glabrata and 31.6% of C. tropicalis were susceptible to fluconazole [Reference Ma28]. Based on the CBPs, all 25 isolates of C. glabrata in this study exhibited SDD to fluconazole, which supports the recommendations from the updated guideline for the management of candidiasis that transition to higher-dose fluconazole should be considered for patients with fluconazole-susceptible C. glabrata isolates [Reference Pappas14]. We identified only two patients with C. krusei, one of which was resistant to voriconazole; each was effectively treated with micafungin and caspofungin, respectively.

Treatment of candidaemia is increasingly problematic owing to accumulated resistance of Candida isolates to antifungal agents, especially fluconazole worldwide [Reference Pfaller24, Reference Cornely39]. Considering safety and efficacy aspects of treatment, echinocandins are now recommended especially in the early treatment of candidaemia, by both USA and European guidelines [Reference Pappas14, Reference Cornely39]. In the current study, fluconazole was the most frequently used antifungal agent for primary therapy, followed by echinocandins and voriconazole, although amphotericin B exhibited excellent in vitro activity overall against Candida spp. The plausible explanations for the prevalent use of fluconazole are the species distribution pattern of isolates, their high rates of susceptibility of C. albicans and C. parapsilosis to the agents, and its safety and tolerability compared with amphotericin B, as well as a significantly lower cost. Due to the lack of echinocandin susceptibility testing in the present study, these agents were used as initial empirical therapy for critically ill patients or those considered likely to have a fluconazole-resistant Candida spp. based on the recommendations of the USA and European guidelines. [Reference Pappas14, Reference Cornely39]

Several studies have reported discrepant results between outcomes of candidaemia and C. albicans spp. in comparison with NAC spp. Differences in mortality were not statistically significant in patient cohorts in the USA (58% vs. 57%) [Reference Chow34], Beijing (34.7% vs. 38.6%) [Reference Ding17] and Shanghai (37.3% vs. 27.9%) [Reference Wu29]. Here, we found that C. albicans BSI was an independent risk factor associated with the mortality rate compared with NAC BSI (OR 3.629; CI 1.352–9.743; P = 0.011), which mirrors data from Shandong and Nanjing in China [Reference Zhang8, Reference Wang30]. By contrast, in Greece, Dimopoulos et al., [Reference Dimopoulos26] reported NAC candidaemia to be associated with higher mortality than C. albicans in non-immunosuppressed, non-neutropenic patients after ICU admission (OR 6.7; 95% CI 1.2–37.7; P = 0.03), which could be attributed to inappropriate or delayed therapy owing to the slower growth of NAC isolates on primary culture; patients with NAC candidaemia may also have been more critically ill than those with C. albicans.

Mortality rates of candidaemia have been attributed to the relative virulence of different Candida spp., a failure of host-defence mechanisms, patient's underlying diseases and complications, inappropriate or delayed treatment and other factors [Reference Puig-Asensio5, Reference Garey20, Reference Krcmery and Barnes40]. In animal models, C. parapsilosis and C. krusei exhibit less virulence than C. albicans, C. tropicalis and C. glabrata [Reference Krcmery and Barnes40]. A meta review of dozens of studies concluded in terms of both overall and attributable mortality that C. tropicalis and C. glabrata are associated with the highest mortality (40 ± 70%), followed by C. krusei and C. albicans (20 ± 40%), the lowest being C. parapsilosis [Reference Krcmery and Barnes40]. Accordingly, the predominance of C. parapsilosis in our study may have partly contributed to the observed lower mortality in patients with NAC.

Apart from C. albicans, the other variables strongly associated with mortality were ICU stay, renal failure and thrombocytopaenia, which suggest that the more severely ill patients had a worse prognosis. Additionally, almost all clearance of candidaemia in survivors who did not receive antifungal treatment occurred in surgical patients following the removal of an indwelling CVC or drainage catheter. Our results indicated that recent cancer surgery was associated with a higher probability of survival but an explanation for this remains unclear. Cancer patients who were judged reasonably able to tolerate surgery, often lacked distant metastases and had less disease severity and fewer complications. Such host factors may therefore be contributory to a reduced mortality rate for recent cancer surgery, and may aid clinicians better to judge the prognosis of these patients with candidaemia.

Our study has several main limitations. Firstly, owing to its retrospective cohort design, factors such as the management of CVC, the use of appropriate antifungal treatments, immunosuppressive, cancer and glucocorticoid therapy, and underlying chronic lung and heart disease, were not evaluated owing to incomplete medical data acquisition. Secondly, in vitro echinocandin susceptibility testing of Candida isolates was not performed, and thirdly, the relatively small sample size may impact on the confidence intervals and analysis of risk factors. Lastly, the study was limited to a single centre and thus, the results may not be applicable to other settings.

In summary, over the last 6 years, NAC was predominant among Candida isolates from adult candidaemia at Shengjing Hospital in Shenyang. TPN was associated with an increased risk of developing NAC candidaemia compared with C. albicans and patients with a urinary catheter were clearly at an increased risk of BSI due to C. albicans. Four independent risk factors for candidaemia-related death were identified, namely, ICU stay, thrombocytopaenia, the isolation of C. albicans as a significant predictor of survival and recent cancer surgery.

Acknowledgements

We are grateful to Dr Zhijie Zhang and Dr Di Wang at the Department of Clinical Laboratory, Shengjing Hospital, for their valuable advice on microbiological methods to us and to Dr Liqiang Zheng at the Department of Clinical Epidemiology, Shengjing Hospital, for his critical assistance with statistical analysis.

Financial support

This research did not receive any specific grant from funding agencies in the public, commercial, or not-for-profit sectors.

Conflict of interest

The authors declare no financial or other competing interests. The authors alone are responsible for the content and the writing of the paper.

References

1.Wisplinghoff, H et al. (2004) Nosocomial bloodstream infections in US hospitals: analysis of 24,179 cases from a prospective nationwide surveillance study. Clinical Infectious Diseases 39, 309317.Google Scholar
2.Marchetti, O et al. (2004) Epidemiology of candidemia in Swiss tertiary care hospitals: secular trends, 1991–2000. Clinical Infectious Diseases 38, 311320.Google Scholar
3.Magill, SS et al. (2014) Multistate point-prevalence survey of health care-associated infections. New England Journal of Medicine 370, 11981208.Google Scholar
4.Zaoutis, TE et al. (2005) The epidemiology and attributable outcomes of candidemia in adults and children hospitalized in the United States: a propensity analysis. Clinical Infectious Diseases 41, 12321239.Google Scholar
5.Puig-Asensio, M et al. (2014) Epidemiology and predictive factors for early and late mortality in Candida bloodstream infections: a population-based surveillance in Spain. Clinical Microbiology and Infection 20, 245254.Google Scholar
6.Chakrabarti, A et al. (2015) Incidence, characteristics and outcome of ICU-acquired candidemia in India. Intensive Care Medicine 41, 285295.Google Scholar
7.Hassan, I et al. (2009) Excess mortality, length of stay and cost attributable to candidaemia. Journal of Infection 59, 360365.Google Scholar
8.Zhang, XB et al. (2012) Retrospective analysis of epidemiology and prognostic factors for candidemia at a hospital in China, 2000–2009. Japanese Journal of Infectious Diseases 65, 510515.Google Scholar
9.Yang, ZT et al. (2014) Epidemiology, species distribution and outcome of nosocomial Candida spp. bloodstream infection in Shanghai. BMC Infectious Diseases 14, 241.Google Scholar
10.Diekema, D et al. (2012) The changing epidemiology of healthcare-associated candidemia over three decades. Diagnostic Microbiology and Infectious Disease 73, 4548.Google Scholar
11.Gudlaugsson, O et al. (2003) Attributable mortality of nosocomial candidemia, revisited. Clinical Infectious Diseases 37, 11721177.Google Scholar
12.Sbrana, F et al. (2018) Independent risk factors for mortality in critically ill patients with candidemia on Italian Internal Medicine Wards. Internal and Emergency Medicine 13, 199204.Google Scholar
13.Das, I et al. (2011) Epidemiology, clinical characteristics, and outcome of candidemia: experience in a tertiary referral center in the UK. International Journal of Infectious Diseases 15, e759e763.Google Scholar
14.Pappas, PG et al. (2016) Clinical practice guideline for the management of candidiasis: 2016 update by the Infectious Diseases Society of America. Clinical Infectious Diseases 62, e150.Google Scholar
15.Barchiesi, F et al. (2016) Epidemiology, clinical characteristics, and outcome of candidemia in a tertiary referral center in Italy from 2010 to 2014. Infection 44, 205213.Google Scholar
16.Guinea, J (2014) Global trends in the distribution of Candida species causing candidemia. Clinical Microbiology and Infection 20(suppl. 6), 510.Google Scholar
17.Ding, X et al. (2015) Epidemiology and risk factors for nosocomial Non-Candida albicans candidemia in adult patients at a tertiary care hospital in North China. Medical Mycology 53, 684690.Google Scholar
18.Wang, H, Xu, YC and Hsueh, PR (2016) Epidemiology of candidemia and antifungal susceptibility in invasive Candida species in the Asia-Pacific region. Future Microbiology 11, 14611477.Google Scholar
19.Bassetti, M et al. (2013) Epidemiology, species distribution, antifungal susceptibility, and outcome of candidemia across five sites in Italy and Spain. Journal of Clinical Microbiology 51, 41674172.Google Scholar
20.Garey, KW et al. (2006) Time to initiation of fluconazole therapy impacts mortality in patients with candidemia: a multi-institutional study. Clinical Infectious Diseases 43, 2531.Google Scholar
21.Clinical Laboratory Standards Institute (2017) Performance Standards for Antifungal Susceptibility Testing of Yeasts, 1st Edn. CLSI document M60. Wayne, PA: Clinical and Laboratory Standards Institute. Available at https://clsi.org/standards/products/microbiology/documents/m60/ (Accessed 12 June 2019).Google Scholar
22.European Committee on Antimicrobial Susceptibility Testing. Antifungal Agents Breakpoint tables for interpretation of MICs, Version 9.0, valid from 2018-02-12. Available at http://www.eucast.org/clinical_breakpoints/ (Accessed 12 June 2019).Google Scholar
23.Gonzalez, GM, Elizondo, M and Ayala, J (2008) Trends in species distribution and susceptibility of bloodstream isolates of Candida collected in Monterrey, Mexico, to seven antifungal agents: results of a 3-year (2004 to 2007) surveillance study. Journal of Clinical Microbiology 46, 29022905.Google Scholar
24.Pfaller, MA et al. (2011) Geographic variations in species distribution and echinocandin and azole antifungal resistance rates among Candida bloodstream infection isolates: report from the SENTRY Antimicrobial Surveillance Program (2008 to 2009). Journal of Clinical Microbiology 49, 396399.Google Scholar
25.Wu, Z et al. (2014) Candidemia: incidence rates, type of species, and risk factors at a tertiary care academic hospital in China. International Journal of Infectious Diseases 22, 48.Google Scholar
26.Dimopoulos, G et al. (2008) Candida albicans versus non-albicans intensive care unit-acquired bloodstream infections: differences in risk factors and outcome. Anesthesia & Analgesia 106, 523529.Google Scholar
27.Chi, HW et al. (2011) Candida albicans versus non-albicans bloodstream infections: the comparison of risk factors and outcome. Journal of Microbiology, Immunology and Infection 44, 369375.Google Scholar
28.Ma, CF et al. (2013) Surveillance study of species distribution, antifungal susceptibility and mortality of nosocomial candidemia in a tertiary care hospital in China. BMC Infectious Diseases 13, 337.Google Scholar
29.Wu, JQ et al. (2011) Epidemiology and risk factors for non-Candida albicans candidemia in non-neutropenic patients at a Chinese teaching hospital. Medical Mycology 49, 552555.Google Scholar
30.Wang, H et al. (2014) Antibiotics exposure, risk factors, and outcomes with Candida albicans and non-Candida albicans candidemia. Results from a multi-center study. Saudi Medical Journal 35, 153158.Google Scholar
31.Hii, IM et al. (2015) Changing epidemiology of candidemia in a medical center in middle Taiwan. Journal of Microbiology, Immunology and Infection 48, 306315.Google Scholar
32.Al-Rawahi, GN and Roscoe, DL (2013) Ten-year review of candidemia in a Canadian tertiary care centre: Predominance of non-albicans Candida species. Canadian Journal of Infectious Diseases and Medical Microbiology 24, e65e68.Google Scholar
33.Alp, S et al. (2015) Epidemiology of candidaemia in a tertiary care university hospital: 10-year experience with 381 candidaemia episodes between 2001 and 2010. Mycoses 58, 498505.Google Scholar
34.Chow, JK et al. (2008) Factors associated with candidemia caused by non-albicans Candida species versus Candida albicans in the intensive care unit. Clinical Infectious Diseases 46, 12061213.Google Scholar
35.Chen, LY et al. (2013) Associated clinical characteristics of patients with candidemia among different Candida species. Journal of Microbiology, Immunology and Infection 46, 463468.Google Scholar
36.Bagaitkar, J, Demuth, DR and Scott, DA (2008) Tobacco use increases susceptibility to bacterial infection. Tobacco Induced Diseases 4, 12.Google Scholar
37.Chattopadhyay, A and Patton, LL (2013) Smoking as a risk factor for oral candidiasis in HIV-infected adults. Journal of Oral Pathology and Medicine 42, 302308.Google Scholar
38.Carter, BD et al. (2015) Smoking and mortality – beyond established causes. New England Journal of Medicine 372, 631640.Google Scholar
39.Cornely, OA et al. (2012) ESCMID* guideline for the diagnosis and management of Candida diseases 2012: non-neutropenic adult patients. Clinical Microbiology and Infection 18(suppl. 7), 1937.Google Scholar
40.Krcmery, V and Barnes, AJ (2002) Non-albicans Candida spp. causing fungaemia: pathogenicity and antifungal resistance. Journal of hospital infection 50, 243260.Google Scholar
Figure 0

Fig. 1. Distribution of Candida species isolates during the study period.

Figure 1

Table 1. Distribution of Candida species among patients according to prior surgery or history of solid tumours

Figure 2

Table 2. Demographics and clinical characteristics of patients with C. albicans and non-albicans candidaemia

Figure 3

Table 3. Multivariate logistic regression analysis of factors associated with an increased risk of candidaemia due to NAC species vs. C. albicans

Figure 4

Table 4. In vitro antifungal susceptibility of Candida species isolated from 180 candidaemia episodes

Figure 5

Table 5. Univariate analysis of factors associated with 30-day mortality of patients with candidaemia

Figure 6

Table 6. Multivariate logistic regression analysis of risk factors associated with 30-day mortality of patients with candidaemia