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Intra-abdominal candidiasis in surgical intensive care unit – epidemiology characteristics and trends


Nitrobřišní kandidóza na chirurgické jednotce intenzivní péče – epidemiologické rysy a trendy

Cíl: Nitrobřišní kandidóza (NK) patří mezi nejčastější invazivní kandidové infekce na chirurgické jednotce intenzivní péče (JIP). V poslední době byla celosvětově pozorována změna v mikrobiální etiologii invazivních kandidových infekcí a postupný nárůst rezistence na antimykotické přípravky. Zaměřili jsme se proto na epidemiologii NK na chirurgické JIP.

Materiál a metodika: Retrospektivní analýza 64 pacientů s NK přijatých na chirurgickou JIP v průběhu 4 let (2013–2016) se zaměřením na vyhodnocení incidence NK, výsledků mikrobiologického vyšetření, antimykotické léčby a letality.

Výsledky: Kumulativní incidence NK činila 18,4 případů/1000 JIP pacientů (2013: 12,6; 2014: 17,7; 2015: 16,8; 2016: 24,5). Separovaně byla vyhodnocena incidence nozokomiální NK (2013: 9,8; 2014: 13,3; 2015: 10,1; 2016: 13,3) a incidence komunitní NK (2013: 2,8; 2014: 4,4; 2015: 6,7; 2016: 11,2). Nejčastěji izolovanou kvasinkou byla Candida albicans (35x; 50,0 %), Candida glabrata (15x; 21,4 %) a Candida tropicalis (6x; 8,6 %), ostatní druhy byly zachyceny ojediněle (< 5,0 %). Byly pozorovány rozdílné trendy v prevalenci kmenů C. albicans (2013: 7(78 %); 2014: 10(59 %); 2015: 6(35 %); 2016: 12(44 %)) a kmenů C. non-albicans (2013: 2(22 %); 2014: 7(41 %); 2015: 9(53 %); 2016: 14(52 %)). Všechny izoláty kvasinek byly citlivé na echinokandiny, amfotericin B a vorikonazol. V případě flukonazolu byly 3 izoláty C. krusei přirozeně rezistentní a 9 izolátů C. glabrata mělo na dávce závislou citlivost (DZC). Podíl izolátů C. glabrata s DZC na flukonazol ke všem kmenům C. glabrata byl 60% (9/15) (2013: 0/2; 2014: 0/2; 2015: 1/3; 2016: 8/8). Izoláty C. glabrata se sníženou citlivosti na flukonazol jsme zaznamenali nejen u nozokomiálních NK (6x), ale také u komunitních NK (3x). 30denní letalita v našem souboru byla 25 % (16/64).

Závěry: Celková incidence NK měla mírně vzestupný trend, přičemž příkrý nárůst incidence byl patrný zejména u komunitní NK, zatímco incidence nozokomiální NK byla spíše setrvalá. V průběhu let 2013–2016 jsme zaznamenali změnu v mikrobiální etiologii NK ve smyslu postupného zvýšení výskytu non-albicans Candida kmenů, konkrétně pak nárůst počtu kmenů C. glabrata. Snížená citlivost na flukonazol byla pozorována právě v souvislosti s kmeny C. glabrata. Zvýšení výskytu kmenů Candida non-albicans tak časově předcházelo objevení se kvasinek se sníženou citlivostí na flukonazol.

Klíčová slova:

nitrobřišní kandidóza – abdominální chirurgie – citlivost na antimykotika – antimykotická léčba – letalita


Authors: J. Ulrych 1;  V. Adámková 2 ;  J. Matek 1;  M. Komarc 3;  V. Frýba 1;  D. Schmidt 1;  P. Koželský 1;  A. Studená 2;  J. Bříza 1;  Z. Krška 1
Authors place of work: First Faculty of Medicine, Charles University in Prague and General University Hospital in Prague, Czech Republic ;  Clinical Microbiology and ATB Center, Institute of Medical Biochemistry and Laboratory Diagnostics, General University Hospital, Charles University, Prague, Czech Republic 2;  Institute of Biophysics and Informatics, First Faculty of Medicine, Charles University in Prague, Czech Republic 3;  st Department of Surgery – Department of Abdominal, Thoracic Surgery and Traumatology 11
Published in the journal: Epidemiol. Mikrobiol. Imunol. 69, 2020, č. 2, s. 57-63
Category: Původní práce

Summary

Objectives: Intra-abdominal candidiasis (IAC) is an invasive fungal infection representing the most common type of invasive Candida infection in surgical intensive care units (ICUs). Recently, decreased antifungal susceptibility and progressive shift in the aetiology of invasive candidiasis has been observed worldwide. We explored IAC epidemiology in surgical ICU.

Material and Methods: We retrospectively reviewed the records of 64 patients with IAC admitted at our surgical ICU over a 4-year period (2013-2016). IAC incidence, microbiological results, antifungal therapy, and mortality were analysed.

Results: The cumulative IAC incidence was 18.4 cases per 1000 admissions (2013: 12.6; 2014: 17.7; 2015: 16.8; 2016: 24.5), including hospital-acquired IAC incidence (2013: 9.8; 2014: 13.3; 2015 10.1; 2016: 13.3) and community-acquired IAC incidence (2013: 2.8; 2014: 4.4; 2015: 6.7; 2016: 11.2). Candida albicans represented the most common species (n = 35, 50.0%) followed by Candida glabrata (n = 15, 21.4%), Candida tropicalis (n = 6, 8.6%) and other yeasts (each < 5.0%). Incidence rate of C. albicans (2013: 7(78%); 2014: 10(59%); 2015: 6(35%); 2016: 12(44%)) and incidence rate of C. non-albicans (2013: 2(22%); 2014: 7(41%); 2015: 9(53%); 2016: 14(52%)) were different in trend. All fungal isolates were susceptible to echinocandins, amphotericin B and voriconazole. Regarding fluconazole susceptibility, C. krusei (n = 3) was resistant and C. glabrata (n = 9) was susceptible-dose dependent (SDD). The ratio of SDD C. glabrata isolates to all isolated C. glabrata strains was 9/15 (60%) (2013: 0/2; 2014: 0/2; 2015: 1/3; 2016: 8/8). Decreased fluconazole susceptibility for C. glabrata isolates was reported in both community-acquired IAC (n = 3) and hospital-acquired IAC (n = 6). Overall 30-day mortality rate was 25.0% (16/64).

Conclusions: We have revealed slowly raising of overall IAC incidence, more increasing trend in incidence of community-acquired IAC compared to rather steady incidence of hospital-acquired IAC. During period 2013–2016 we have observed a significant shift in the aetiology of IAC towards an increased proportion of non-albicans Candida species, particularly C. glabrata. Acquired decreased fluconazole susceptibility was related to C. glabrata isolates exclusively. Emergence of decreased antifungal susceptibility has been preceded by increase of non-albicans Candida isolates.

Keywords:

intra-abdominal candidiasis – Abdominal surgery – antifungal susceptibility – antifungal therapy – mortality

INTRODUCTION

Invasive fungal infections in critically ill patients in the intensive care unit (ICU) are associated with considerable morbidity and mortality. The predominant type of invasive candidiasis is candidemia [1]. However, intra-abdominal candidiasis (IAC) is a frequent invasive Candida infection in surgical patients, representing the most common type of invasive candidiasis in surgical ICUs [2, 3]. Candida strains are obtained from an intraoperative intra-abdominal specimen in approximately 20–50% of patients with intra-abdominal perforation non-appendicular aetiology [4, 5, 6]. C. albicans is the most common causative agent of invasive candidiasis, but a shift towards non-albicans Candida species has been recently observed worldwide [7, 8, 9, 10, 11]. Moreover, global epidemiology trend is characterised by an increased prevalence of triazole-resistant Candida species, such as C. glabrata and C. krusei.

In 2016 emergence of decreased antifungal susceptibility for Candida species has been observed in culture isolates of Candida species in our surgical patients after abdominal surgery [12]. Therefore, this retrospective study was initiated to reveal the IAC epidemiology characteristics and trends in our surgical ICU patients over the period 2013–2016.

MATERIAL AND METHODS

We performed a retrospective observational single-centre cohort study analysing patients which were hospitalized in the ICU of First Department of Surgery, First Faculty of Medicine, Charles University and General University Hospital in Prague within a period from January 1st 2013 till December 31st 2016. All patients admitted to ICU in the period mentioned above were identified via a search of the hospital medical database. Individuals with a positive culture for Candida species in the peritoneal fluid obtained during surgery or in the abdominal drain fluid during the post-operative period were included. A report form was completed for each study patient based on a review of the medical charts.

The following data were collected: demographic characteristics, underlying disease, antifungal therapy (antifungal agents, length of administration), length of stay in ICU, length of stay in hospital, 30-day mortality.

The mycological and microbiological results of cultured peritoneal fluid and drain fluid were recorded. Microbiological techniques applied for culture and identification of bacteria and fungi, as well as antibiotic susceptibility testing, were those routinely used in the microbiology laboratory. In the laboratory, culture for aerobic, anaerobic bacteria and fungi was performed. For bacterial isolation blood agar and chromogenic agar UriSelect4 (BioRad) was used. The plates were incubated at 36 ± 1 °C for 24–48 hours. Cultures positive for bacterial growth were identified by MALDI-TOF mass spectrometer (Bruker). An antimicrobial susceptibility test of the identified bacteria was performed using the Kirby Bauer Disc Diffusion method following CLSI guidelines [13]. Sabouraud dextrose agar (SDA), as selective medium, was used for isolation of fungi and incubation was done at 36 ± 1 °C for 48 hours. Positive cultures on SDA were identified by MALDI-TOF mass spectrometer (Bruker). Antifungal susceptibility tests were done by using an E-test on RPMI 1640 medium supplemented with glucose to a final concentration of 2% following CLSI criteria [14].

In accordance with recently proposed criteria, Candida isolation was classified as intra-abdominal candidiasis in patients with clinical evidence of intra-abdominal infection and isolation of Candida species in a sample collected from an intra-abdominal site or from abdominal drains that were in place < 24 hours [15, 16]. Community-acquired IAC (C-IAC) was defined as intra-abdominal Candida infection characterised by onset of clinical abdominal manifestation before hospital admission or ≤ 48 hours after admission. Hospital-acquired IAC (H-IAC) was defined as Candida infection of abdominal cavity not present on admission that became evident > 48 hours after admission in hospitalised patients.

Statistical analysis

Continuous normally distributed data are expressed as the mean and standard deviation (SD) and compared using independent group t test. Categorical data are expressed as the number and percentage and compared using χ2 or the Fisher’s exact tests. In all comparisons, p-values bellow 0.05 were considered to be statistically significant. Statistical analyses were performed using SPSS version 23 (SPSS Inc., Chicago, IL, USA).

RESULTS

Demographics, basic characteristics of study group and microbiological results

In the period 2013–2016, we identified altogether 101 patients with a positive culture for fungi from the peritoneal fluid collected during abdominal surgery or from abdominal drain postoperatively. Criteria for IAC were met in 64 patients. Basic characteristics, site of IAC origin, in hospital characteristics and mortality are reported in Table 1.

Tab. 1. Basic characteristics, site of IAC origin, in hospital characteristics and mortality
Basic characteristics, site of IAC origin, in hospital characteristics and mortality
Legends: n – number of patients; BMI – body mass index; HPB – hepatopancreatobiliary; IAC – intra-abdominal candidiasis (C – community-acquired, H – hospital-acquired); ICU – intensive care unit; p value – statistically significant < 0.05; SD – standard deviation; * C-IAC vs. H-IAC.

In the 64 samples, 70 fungi isolates were identified. Candida species (n = 67) was the most frequent species followed by Saccharomyces (n = 3). Although Candida albicans (CAAL) was the most frequent Candida pathogen, the incidence rate of non-albicans Candida species (non-CAAL) was nearly the same (CAAL 50.0%; non-CAAL 45.7%). Yeast species were the only organism cultured in 14% cases. Bacterial co-infection was present in 85.9% patients. In addition to fungi, 142 bacteria isolates were identified in the microbiological specimens of 55 patients with up to six different species per patient. The mean number of isolated bacteria was 2.2 isolates per sample. Detailed microbiological results, including the comparison of microbial aetiology in C-IAC and H-IAC, are reported in Table 2.

Tab. 2. Microbiological results in IAC, including C-IAC and H-IAC
Microbiological results in IAC, including C-IAC and H-IAC
Legends: ESBL – extended spectrum beta-lactamase; FLU-SDD – fluconazole susceptible-dose dependent; IAC – intra-abdominal candidiasis (C – community-acquired, H – hospital-acquired); n – number of patients; p value – statistically significant bellow 0.05; *C-IAC vs. H-IAC.

Incidence

In the period 2013–2016, altogether 3487 patients were admitted to surgical ICU and there were a total 64 episodes of IAC. The cumulative IAC incidence in ICU was 18.4 cases per 1000 admissions. The trend in incidence of IAC in abdominal surgery patients, including C-IAC and H-IAC, is shown in Figure 1.

Fig. 1. Trend in Incidence of IAC
Trend in Incidence of IAC

Antifungal susceptibility testing

All fungal isolates were susceptible to echinocandins, amphotericin B and voriconazole, however antifungal susceptibility testing revealed decreased fluconazole susceptibility in 12 (17.1%) Candida isolates. All Candida albicans isolates were susceptible to fluconazole. The three C. krusei isolates were resistant to fluconazole (intrinsic resistance) and the nine C. glabrata isolates had fluconazole MIC 32 mg/l, thus, reported as susceptible-dose dependent (SDD). Other non-albicans Candida species were susceptible to fluconazole. Of all tested Candida glabrata isolates, 60% (9/15) were fluconazole SDD.

Microbiological results and trends

Detailed analysis of Candida species incidence during the observed period is reported in Table 3. The ratio of fluconazole SDD C. glabrata isolates to all isolated C. glabrata strains was reported in 4-year period (2013: 0/2, 0.0%; 2014: 0/2, 0.0%; 2015: 1/3, 33.3%; 2016: 8/8, 100.0%). Statistically significant increased incidence of C. glabrata isolates with decreased susceptibility to fluconazole was reported in the period 2015–2016 (9/11, 81.8%) compared to the period 2013–2014 (0/4, 0.0%) (p = 0.006). Moreover, in 2016 all isolates of C. glabrata (8/8) were SDD to fluconazole and decreased fluconazole susceptibility for C. glabrata isolates was reported in both C-IAC (3/3) and H-IAC (5/5).  

Tab. 3. Incidence of yeast species in the period 2013–2016
Incidence of yeast species in the period 2013–2016

Antifungal therapy and mortality

Only 39.1% (25/64) of patients with IAC received antifungal therapy. However, antifungal therapy was more frequently administered in cases of H-IAC (21/42, 51.2%) compared to cases of C-IAC (4/23, 17.4%) (p = 0.008). In 25 patients, empiric monotherapy was administered using fluconazole (n = 19), voriconazole (n = 1), anidulafungin (n = 4) and micafungin (n = 1). In four cases de-escalation therapy was performed, echinocandin was replaced by fluconazole. Per the Candida species identification and susceptibility results, empiric antifungal treatment appeared as inadequate in 20.0% (5/25) of patients. Inadequate antifungal therapy was administered more frequently in the period 2015–2016 (5/14; 35.7%) compared to the period 2013–2014 (0/11; 0.0%).

Overall 30-day mortality rate was 25.0% (16/64), including mortality of 32.0% (8/25) in the period 2013–2014 and mortality of 20.5% (8/39) in the period 2015–2016 (p = 0.300). The mortality in the subgroups of patients with C-IAC and H-IAC was 26.1% (6/23) and 24.4% (10/41), respectively (p = 0.880). 

DISCUSSION

Invasive fungal infection in ICUs ranges from 4.7 to 28.0 episodes per 1000 admissions; however, most studies have reported the incidence of candidemia while the incidence of intra-abdominal candidiasis has remained unknown [2, 3, 17, 18, 19]. In the Czech Republic multicentre study assessing epidemiology of invasive candidiasis in 2012–2015 authors analysed only episodes of candidemia [20]. We have revealed cumulative incidence of IAC of 18.4 cases per 1000 admissions in our surgical ICU. It means that IAC incidence in surgical ICUs is comparable to the incidence of candidemia in medical ICUs (6.7–34.3 episodes per 1000 ICU admissions) [17, 18, 21, 22]. In addition, we observed a trend towards slow increase in IAC incidence during period. It should be mentioned that significant difference in incidence trend was observed in C-IAC compared to H-IAC. Incidence rate of H-IAC was steady within the whole period while C-IAC demonstrated increasing incidence during this 4-year period. In 2016 C-IAC incidence reached nearly same level as H-IAC incidence. Based on this data, Candida species should be considered in aetiology of hospital-acquired intra-abdominal infections as well as in aetiology of community acquired intra-abdominal infections. There is no doubt that healthcare exposure is the most important risk factor for IAC, including recent abdominal surgery, anastomotic leaks, or necrotizing pancreatitis. However, there is a lack of data regarding risk factors for C-IAC. Increasing incidence of C-IAC supports the theory that the abdomen may be an important reservoir of Candida species in community. Unfortunately, the fungal colonization of otherwise healthy hosts and characteristic of human gut mycobiome have not been yet completely explored. We need to better identify and define the significant risk factors for C-IAC particularly.

Many different Candida species are known to be aetiological agents of invasive fungal infection, however, 90% of invasive infections are caused by C. albicans, C. glabrata, C. parapsilosis, C. tropicalis and C. krusei [19, 23, 24]. Our epidemiology study is consistent with the literature, C. albicans followed by C. glabrata and C. tropicalis were the most frequently isolated species from the peritoneal specimens. It is well recognized that just C. glabrata predominates as the second most frequent pathogen of invasive candidiasis in the North and Centre of Europe [25, 26, 27]. Moreover, non-CAAL species, including C. glabrata, C. tropicalis and C. krusei, were repeatedly reported in older patients in association with recent major abdominal surgery [25, 28, 29]. Regarding epidemiology trends, shift in the aetiology of IAC was observed in our surgical ICU. The first half of the period (2013–2014) was characterized by a predominance of C. albicans species. In the second half of the period (2015–2016) C. albicans decreased proportionally and non--CAAL species accounted for more than 50% of isolates.

Antifungal susceptibility/resistance is really important epidemiology characteristic. Generally, azole resistance for Candida species is more frequent than echinocandin resistance. In Europe the reported rate of Candida species with reduced susceptibility to fluconazole is 11–28% in patients with IAC [2, 16, 30]. Echinocandins demonstrate excellent activity for Candida species, accounting < 4% Candida isolates resistant to echinocandins worldwide [31, 32]. Bassetti et al. observed in 481 patients included in a multicentre study of abdominal candidiasis a total of 98% of Candida strains susceptible to echinocandins [16]. Candida species exhibit varying rates of susceptibility to the azole agents. C. albicans and some non-CAAL species, such as C. tropicalis, C. parapsilosis, C. lusitaniae, C. kefyr and C. dubliniensis, remain highly susceptible to fluconazole (susceptibility rate > 98.0% and > 90.0%, respectively) [33, 34]. By contrast, decreased fluconazole susceptibility for C. glabrata (susceptibility rate 92–68.7%) has been reported and C. krusei is associated with intrinsic fluconazole resistance [33, 34]. Concerning antifungal resistance pattern in our surgical ICU, decreased antifungal susceptibility to azole drugs and excellent activity of echinocandins have been demonstrated. Prior fluconazole exposure and echinocandin sparing strategy may explain this shift towards to decreased fluconazole susceptibility. Acquired decreased fluconazole susceptibility was reported for C. glabrata exclusively. We have observed reduced susceptibility to fluconazole in association with increased prevalence of non-CAAL species. Moreover, aetiology shift towards to increase of non-CAAL isolates preceded sudden emergence of decreased fluconazole susceptibility in 2016. Therefore, we propound that changing antifungal susceptibility was predictable based on the shift in aetiology. Interestingly, increased prevalence of fluconazole SDD C. glabrata has been observed in H-IAC as well as in C-IAC. Prior fluconazole exposure explains the emergence of decreased fluconazole susceptibility in H-IAC. However, reason of emergence of fluconazole SDD C. glabrata in C-IAC is obscure.

Characteristics of patients and IAC risk factors were statistically analysed just for the purpose of comparisons of C-IAC and H-IAC. Both subgroups of patients were comparable in most characteristics (gender, age, BMI, comorbidity, etc.) (see Table 1). Targeted analysis of risk factor correlations was out of the interest. Concerning antifungal therapy and mortality, there is limited evidence of study outcomes due to the retrospective design of the study and missing considerable variables. Except many variables, mismatched aetiology is major limitation of analysis of therapy, mortality and prognosis in IAC. The clinical significance of Candida species recovered from intra-abdominal peritoneal fluid is the most controversial factor. The role of Candida species in the pathophysiology of polymicrobial peritonitis has not been conclusively defined. The differentiation between contamination, colonization and infection remains the main diagnostic challenge. Colonisation index and Candida score are used for identifying high risk patients for IAC and non-culture-based methods including (1→3)-β-d-glucan, mannan antigen, anti-mannan antibodies are recommended for detection of Candida species [35]. However, more studies are needed to assess the optimal criteria in high-risk patients and the efficiency of fungal biomarkers in the differentiation of colonisation and infection. This is a keystone of the unconvincing outcomes of most IAC studies. Empirical antifungal therapy has been demonstrated to decrease mortality significantly in a specific patient population. Bassetti et al. reported association between the absence of an adequate initial antifungal therapy and increased mortality in patients with adequate source control of IAC and septic shock [16]. Similarly, in a retrospective multi-centric analysis of 258 patients with intra-abdominal candidiasis in Spain, ICU patients that did not receive antifungal therapy for an IAC episode had a ∼6-fold increase in mortality; however, the benefit of antifungal therapy was not observed in non-ICU patients [36]. Conversely, the current evidence does not demonstrate efficacy of antifungal therapy in improving outcomes in patients with IAC caused by perforated peptic ulcer [37]. Antifungal therapy in these patients may be considered overtreatment altering the outcomes. Prospective multicentre study and multivariable analysis are required for identification of IAC risk factors and determination of causative relationships of antifungal therapy and mortality.

Considering this study, the main limitation is the low number of included patients with IAC, which has resulted in a lower power of statistical significance of statistical analysis. However, our study outcomes underscore the importance of knowledge of the local epidemiology and resistance patterns for Candida species. Local epidemiology is crucial for guiding therapeutic decision making.

CONCLUSIONS

We have revealed slowly raising of overall IAC incidence. Interestingly, more increasing trend in incidence of C-IAC compared to rather steady incidence of H-IAC has been discovered. During period 2013–2016 we have observed a significant shift in the aetiology of IAC towards to an increased proportion of non-CAAL species, particularly C. glabrata. Acquired decreased susceptibility to fluconazole was related to C. glabrata isolates exclusively. Emergence of decreased antifungal susceptibility has been preceded by increase of incidence of non-CAAL isolates. Therefore, we assume that emergence of antifungal resistance may be predictable based on the shift in aetiology. In terms of antifungal susceptibility, significant risk of antifungal resistance may be related to H-IAC as well as C-IAC. Knowledge of local epidemiology is crucial for guiding therapeutic decision making.

Declaration

This work was supported by Ministry of Health, Czech Republic (Conceptual development of research organization 64165, General University Hospital in Prague).

Do redakce došlo dne 22. 1. 2020.

Adresa pro korespondenci:

MUDr. Jan Ulrych, Ph.D.

I. chirurgická klinika – hrudní, břišní a úrazové chirurgie 1. LF UK a VFN

U Nemocnice 2

128 00 Praha 2

e-mail: Jan.Ulrych@vfn.cz


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Štítky
Hygiena a epidemiológia Infekčné lekárstvo Mikrobiológia

Článok vyšiel v časopise

Epidemiologie, mikrobiologie, imunologie

Číslo 2

2020 Číslo 2
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Aktuální možnosti diagnostiky a léčby litiáz
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Autori: MUDr. Tomáš Ürge, PhD.

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