ABSTRACT
Objective This study aimed to verify oral candidiasis, identify the causative species, and investigate the antifungal susceptibility of yeasts isolated from liver transplant patients.
Methods A descriptive analysis of 97 patients who underwent liver transplantation was conducted at a hospital. Two clinical examinations (Collections A and B) of the oral cavity were performed. Oral material was collected from all patients, inoculated in Sabouraud Dextrose Agar, and incubated at 35℃ for 48 hours. Samples were identified by molecular sequencing of the internal trascribed space region of rDNA.
Results An antifungal susceptibility test with fluconazole, amphotericin B, and micafungin was performed using the Clinical and Laboratory Standards Institute yeast broth microdilution method. Among the patients, 15 presented with oral candidiasis: eight in Collection A and seven in Collection B. The primary type of candidiasis was atrophic, followed by pseudomembranous candidiasis. The most prevalent species was Candida albicans (nine), followed by Candida glabrata (three), Candida tropicalis (two), and Candida dubliniensis (one). Regarding susceptibility to fluconazole, of the 15 samples, 11 were susceptible, three were susceptible in a dose-dependent manner, and one was resistant.
Conclusion The most commonly identified type of candidiasis was atrophic, with C. albicans and C. glabrata being the most prevalent causative species. One fluconazole-resistant isolate each of C. tropicalis and C. albicans were identified.
Keywords Antifungal agents; Candida ; Candidiasis; Liver transplantation; Candidiasis, oral
Highlights
Fifteen liver transplant patients presented with oral candidiasis.
The two prevalent types of candidiasis were atrophic and pseudomembranous
Candida albicans and Candida glabrata were the most prevalent species
Most isolates were susceptible to antifungal agents.
INTRODUCTION
Organ transplantation remains one of the most significant advances in modern medicine. In many cases, it is the only therapeutic option for treating diseases related to end-stage organ failure.(1) In recent decades, the occurrence of superficial and invasive fungal infections related to deaths and postoperative failure in transplant recipients has increased significantly, with candidiasis being the most common.(2) Organ recipients must use immunosuppressive therapy to prevent rejection; however, these drugs can harm the oral health of some patients, creating conditions conducive to infections.(1,3) Oral candidiasis is frequent in liver transplant recipients since these patients represent a higher risk category for oral infections due to the use of drugs that tend to weaken the immune system, as well as to the delay in diagnosis owing to the non-specificity of symptoms and methods for current diagnosis.(4)
Candida species are generally present as commensals in the oropharyngeal and gastrointestinal tracts and can cause a broad spectrum of serious diseases, ranging from local infections to disseminated diseases.(5,6)They are responsible for severe infections with a high rate of morbidity and mortality.(7-9) Lesions in the oral cavity may present with different characteristics, such as pseudomembranous, atrophic, hyperplastic, and angular cheilitis, which may be accompanied by pain and a burning mouth sensation.(10)
Candida albicans is the most common species that causes oral candidiasis. However, infections by other Candida species have been reported to be increasing in frequency. The most important include C. parapsilosis, C. glabrata, C. krusei, C. lusitaniae, C. tropicalis, C. dubliniensis, and C. auris.(9,11) Several of these species are resistant to commonly used antifungal drugs, and some have been proven to be highly virulent. Resistance to antifungal therapy in some Candida species makes managing oral candidiasis difficult.(4,12)
Knowledge and epidemiological data regarding the identification of Candida species and susceptibility to antifungal agents in patients who have undergone a liver transplant remains limited. Accurate identification of agents, antifungal resistance testing, and epidemiological surveys are essential for guiding therapy and determining the prognosis of fungal diseases.(13,14) This research is of extreme clinical importance because invasive fungi have emerged as a leading cause of disease in patients with compromised immune systems. Lack of knowledge of the species and sensitivity to antifungal agents may lead to delays in proper intervention.
OBJECTIVE
This study aimed to verify the presence of oral candidiasis, identify the species involved, and investigate the antifungal susceptibility profiles of yeasts isolated from patients who have undergone liver transplantation.
METHODS
Study participants and sampling
All the participants involved provided written informed consent. Ninety-seven patients who underwent liver transplantation and attended the transplant outpatient clinic of the Hospital São Vicente de Paula, Passo Fundo, RS, Brazil, between May 2017 and May 2019 participated in the study. The inclusion criteria were age >18 years, six months post-transplantation, and no use of antifungal agents. Sociodemographic data were recorded, and clinical examinations were performed on all patients who met the inclusion criteria for verifying infection in the oral cavity.
Oral material was collected twice after transplantation in all patients, within six months between them, with the first collection referred to as Collection “A” and the second as Collection “B”. Patients who did not present with oral candidiasis in any of the collections were excluded from the study, the results of which have been previously published by this working group.(15)
This study was approved by the Ethics and Research Committee of Universidade Federal de São Paulo (CAAE: 50413815.2.0000.5505; # 1.319.387).
Yeast isolation and molecular identification
Oral material from all patients was collected using a sterile swab and inoculated on Sabouraud Dextrose Agar (SDA) (Becton Dickinson & Co. Sparks, MD, USA) with chloramphenicol and incubated at 37 ℃ for 48 h. Samples that produced yeast colonies were stored at -80℃ in a YPD medium (1% yeast extract (BD), 2% BCA to peptone (BD), and 2% glucose-containing glycerol (15% p/v)).
Yeast cells stored at -80°C were inoculated on CHROMagarTM Candida plates (CHROMagar Microbiology, Paris, France) for 48 h at 37℃ to obtain pure colonies and presumptive identification of Candida spp. Molecular identification of Candida species was performed by sequencing the ITS region of rDNA. The genomic DNA of the isolates was extracted using the Ultra PrepMan Reagent® (Applied Biosystems, Inc., Foster City, CA, EUA) according to the manufacturer’s instructions. Polymerase chain reaction (PCR) for amplification of the ITS region was performed using primers V9G (5’-TTACGTCCCTGCCCTTGTA-3’) and LS266 (5’-GCATTCCCAAACAACTCGACTC-3’).(16) In the sequencing reaction, the same primers were used. Sequencher software (version 4.1.4) used two to four reads to obtain the consensus sequence. The sequences obtained were cross-referenced with the NCBI GenBank (https://www.ncbi.nlm.nih.gov/) using the nucleotide Basic Local Alignment Search Tool (BLASTn) to identify the isolates. An e-value <105 and identity ≥98% were considered accurate parameters for species identification.
Green colonies grown on CHROMagarTM Candida were subjected to molecular identification to differentiate between C. albicans and C. dubliniensis. The amplification of genomic DNA with species-specific primers for each species was performed as described by Ahmad et al. with slight modifications. For the amplification of the DNA fragments, 2µL of CALF primers (5›-TGGTAAGGCGGGATCG-CTT-3’) + CALR (5’GGTCAAAGTTTGAAGA TATAC) for C. albicans and CDUF (5’AAACTTGTCACGAGATTATTTTT) + CDUR (5’AAAGTTTGAAGAATAAAAA) TGG GC-3’) for C. dubliniensis were used at a concentration of 20µmol; 2µL of template DNA and 100µmol of each dNTP. Primer pairs were used to identify C. albicans and C. dubliniensis for separate PCR reactions. C-reactive protein products were analyzed by 2% agarose gel electrophoresis. The results were interpreted visually to verify the presence and size of the amplified fragments; 100- and 325-bp fragments were used to identify C. albicans and C. dubliniensis, respectively.(17)
Antifungal susceptibility test
Antifungal susceptibility tests were performed according to the Clinical and Laboratory Standards Institute (CLSI) protocol M27ED4(18) using the broth microdilution technique against the antifungal agents fluconazole, amphotericin B (SIGMA Pharma, USA), and micafungin (Astellas Pharma). Antifungal dilutions were performed with RPMI 1640 medium to obtain final concentrations ranging from 0.03-16μg/mL for amphotericin B and micafungin and from 0.125-64μg/mL for fluconazole.
The reading criteria included the minimum inhibitory concentration (MIC), which is the lowest concentration capable of visually inhibiting 50% of the growth of Candida spp. after treatment with fluconazole and micafungin and 100% after treatment with amphotericin B. Susceptibility test readings were performed 24 hours after incubation and interpreted following the CLSI document M6028(19) to determine the clinical breakpoints. According to this document, there is no defined breakpoint for amphotericin B. Therefore, the clinical breakpoint used in this study was described by Nguyen et al.(20)
Statistical analysis
The data obtained were analyzed using IBM SPSS™ (version 20.0, Armonk, New York, USA).
RESULTS
Of the 97 patients included in this study, 15 (15.5%) presented with oral candidiasis. The results of subsequent analyses were obtained from these 15 patients. The age range of the patients was 26 to 70 years, with an average of 57.2 (DP ±10.5). Most patients were male (73.4%), and post-transplantation time ranged from 1.5 to 17 years, with an average of 8.6) years. Hepatitis C was the main reason for transplantation (40%), followed by hepatitis B (33.5%). Sixty percent of the patients had skin lesions at the time of collection, 46.7% had infectious diseases in the post-transplantation period, and six had bacterial infections. All patients used cyclosporine as an immunosuppressant, and 80% used partial or total dentures.
Sample collections took place in two stages, with an interval of six months between them. In Collection A, eight of 15 patients presented with candidiasis, five had atrophic candidiasis (CA), and three had pseudomembranous candidiasis (PC). In Collection B, seven patients presented with candidiasis; five had AC, and one had PC. Patients not infected in one of the collections were colonized with yeast in the other collection.
The yeasts were identified using molecular sequencing. Of the five AC cases from Collection A, three were caused by C. glabrata, one by C. albicans, and one by C. tropicalis. Of the three PC cases, two were caused by C. albicans and one by C. tropicalis. Four of the five AC cases in Collection B were caused by C. albicans, one by C. dubliniensis, and 100% of the PC cases were caused by C. albicans. In summary, of the identified yeasts in the 15 patients, nine were C. albicans, three were C. glabrata, two were C. dubliniensis, and one was C. tropicalis. None of the patients had candidiasis in the Collection A or Collection B consecutive collection (Table 1). Notably, two patients had species substitutions between the Collection A and Collection B (Table 1).
Susceptibility tests were performed on 15 yeast isolates from Collections A and B, present in patients with candidiasis infection or colonization. All MIC variations, MIC50 and MIC90 values, and susceptibility categories are listed in table 2. The MIC90 values for C. glabrata, C. tropicalis, and C. dubliniensis were not determined because the number of isolates was deficient.
All the tested isolates showed low MICs for amphotericin B and micafungin, suggesting that Candida spp. have in vitro susceptibility to these two antifungal agents. There are no defined breakpoints for C. dubliniensis concerning micafungin; therefore, we used the breakpoint values of C. albicans complex as a reference to analyze the results,(20) thereby demonstrating that this species was susceptible to the drugs in both collections.
Fluconazole was the only antifungal agent with different susceptibility patterns in the studied yeasts. In Collection A, one isolate of C. albicans, three of C. glabrata, and one of C. tropicalis were susceptible to fluconazole in a dose-dependent manner, one C. tropicalis was resistant, and the others were susceptible to all antifungal agents.
In Collection B, two isolates of C. albicans, three of C. glabrata, and one of C. tropicalis were susceptible to fluconazole in a dose-dependent manner; one C. albicans isolate was resistant, and the others were susceptible to all antifungal agents. Although there are no defined breakpoints for C. dubliniensis, a rare and cryptic species, all MIC values suggest susceptibility.
All the patients with oral candidiasis were previously treated with topical nystatin for 30 days. One patient with CA presented with a fluconazole-resistant C. tropicalis isolate in the Collection A. Despite the nystatin treatment, in the Collection B, this patient presented with C. glabrata colonization after treatment with fluconazole (MIC = 8μg/mL).
In the Collection A, one patient presented with CA caused by C. glabrata and presented with a fluconazole-resistant isolate of C. albicans after six months. In another patient with PC, C. tropicalis isolates susceptible to fluconazole in a dose-dependent manner were identified in Collection A. After six months, the patient remained colonized by the same isolate of C. tropicalis.
DISCUSSION
This descriptive study aimed to verify the presence of candidiasis in patients who underwent liver transplantation, identify the species causing the disease, and test the efficacy of each class of antifungal agents commonly used in therapy for invasive fungal infections caused by yeasts. We analyzed 97 patients six months post-liver transplantation, and 15.47% of them presented with oral candidiasis during two collection periods within a six-month interval, showing that this is an opportunistic infection that can occur at any time post-transplantation. This finding aligns with a similar study conducted in Iran, which identified candidiasis in 16% of patients who underwent liver transplantation.(21) Furthermore, previous studies’ results demonstrated that the prevalence of oral candidiasis in patients who have undergone solid organ transplants ranges from 15-34%.(22-25) This study found a higher prevalence of candidiasis than López-Pintor et al.,(26) who reported candidiasis infection in 7.4% of patients who underwent kidney transplantation, indicating that the incidence of fungal infections is higher in patients receiving liver transplantation. Notably, the frequency of oral and oropharyngeal candidiasis infections has increased dramatically in recent decades, mainly because of an increase in the number of patients with compromised immune systems.(25)
In the present study, most patients (53.4%) had AC, similar to that observed in other studies. Zhang et al.(27) showed that patients with complete dentures who underwent kidney transplantation were more prone to candidiasis and angular cheilitis than healthy individuals with the same type of prosthesis. Candida albicans is responsible for most cases of oral candidiasis infections; however, other species, such as C. glabrata, C. krusei, C. tropicalis, C. parapsilosis, and C. dubliniensis, have been frequently identified as causing the disease.(28) In this study, of the 15 cases of candidiasis, C. albicans (63.9%) was the most prevalent species causing infections, followed by C. glabrata (18.5%). Similar data were found in previous studies in various regions worldwide.(3,25,27)
Candida glabrata and C. tropicalis are the second and third most prevalent species identified in this study (25.3%), similar to studies conducted by Sahebjamee et al.(21) and Zarei et al.,(25) which found that approximately 22% of candidiasis infections not caused by C. albicans are caused by these two species. The present study identified one case of candidiasis caused by C. dubliniensis, which is consistent with the findings of Chavasco et al.,(29) who also identified this species in two cases of oral candidiasis.(29)
A study of HIV-positive children in Chile showed that C. glabrata (33%), followed by C. albicans (27%), was the most common cause of oral candidiasis infection. Castillo-Martínez et al.(30) identified oral candidiasis in 14% of patients who underwent bone marrow transplantation, and Nishii et al.(31) identified oral candidiasis in 41.7% of patients who underwent radiotherapy in a study in Japan.
The number of C. albicans isolates decreased, and the number of C. glabrata and C. parapsilosis isolates increased over time in cases of invasive candidiasis.(14,32) The most prevalent species in the present study and most other studies was C. albicans, with it being responsible for approximately 50% of all infections; however, C. glabrata, C. tropicalis, C. parapsilosis, and C. krusei are also important infectious agents.(6,33-39)
The present study identified C. dubliniensis in 8.5% of patients using a species-specific PCR to differentiate this species from C. albicans. Chavasco et al.(29) identified C. dubliniensis in 5.4% of patients using PCR, in which samples had been mistakenly identified as C. albicans by the classical method, thus demonstrating that PCR is more effective in elucidating the epidemiology of C. dubliniensis and establishing its clinical significance.
Recently, antifungal susceptibility testing has revealed new agents and new standardized test methods have been developed by the Antifungal Susceptibility Testing Subcommittee of the CLSI(18) and European Committee of Antimicrobial Susceptibility Testing (EUCAST),(19) through which the knowledge of susceptibility can be improved, especially for opportunistic pathogens.(14)
In the present study, one colonizing isolate of C. albicans and C. tropicalis that caused infection showed resistance to fluconazole. Goular et al.(28) found fluconazole-resistant Candida species in 1% of all strains observed, which is consistent with the findings of this study. Orasch et al.(38) found fluconazole susceptibility in 90% of the strains of C. albicans, C. glabrata, C. tropicalis, and C. parapsilosis; Pfaller et al.(14) observed the highest rates of fluconazole-resistant isolates in C. glabrata in North America (10.6%) and in C. tropicalis in the Asia-Pacific region (9.2%), and reported a steady increase in fluconazole-resistant isolates of C. glabrata throughout 20 years of studies in the United States. For echinocandins, resistance results ranged from 3.5% for C. glabrata to 0.1% for C. albicans and C. parapsilosis, which were lower than those in this study. A study by Orasch et al.(38) reported high micafungin resistance in C. glabrata (2.8%) and C. tropicalis (1.3%). Modrzewska et al.(39) revealed that almost all strains were susceptible to nystatin (97.9%) and amphotericin B (72.3%) and resistant to fluconazole (72.3%) and ketoconazole (57.5%). Therefore, it is necessary to determine the fungal species and their antifungal susceptibility for more effective therapy. Prophylactic administration of fluconazole often leads to an increase in the number of fluconazole-resistant strains.(39) In this study, most isolates were susceptible to all antifungal agents; however, one isolate of C. tropicalis and C. albicans was resistant to fluconazole, suggesting a risk of invasive fungal infection by yeasts resistant to this drug, which were present in the oral cavity of patients.
Despite our promising results, this study had two limitations. First, it was not possible to standardize the time of the first post-transplant collection for all patients owing to the study design, and it was only possible to standardize the six-month interval between the two collection periods. Second, there was a lack of patient history and clinical information regarding the previous use of azoles. However, we believe this study makes a significant contribution to the existing literature, as it is the first regional investigation to determine the prevalence of oral candidiasis and accurately identify the species causing infections based on molecular methods, as well as their behavior against the action of azoles. In addition, this study offers insights for clinical staff on the emergence of in vitro-antifungal-resistant strains, which may enable more effective treatment of patients with oral candidiasis. Furthermore, this study reports the emergence of resistance in these species, which may result from increased use of azoles in prophylactic therapy.
CONCLUSION
The primary type of candidiasis identified in patients who underwent liver transplantation is atrophic candidiasis, with the most prevalent causative species being C. albicans and C. glabrata. Even in the absence of clinical signs of candidiasis, all patients had an oral cavity colonized by species of Candida, either before or after infection and treatment, demonstrating that this yeast was common in the patients who participated in this study. Most isolates were susceptible to antifungal agents; however, one isolate of C. tropicalis and C. albicans was resistant to fluconazole.
ACKNOWLEDGEMENTS
We would like to thank the Fundação de Amparo à Pesquisa do Estado de São Paulo (FAPESP) [Project No. 2017/08507-8] and Coordenação de Aperfeiçoamento de Pessoal de Nível Superior (CAPES) for financial support.
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Article extracted from the doctoral thesis of the student Clarice Elvira Saggin Sabadin, carried out in the Postgraduate Program in Health Sciences, Universidade Federal de São Paulo, São Paulo, SP, Brazil.
Edited by
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Associate Editor: Kenneth Gollob Hospital Israelita Albert Einstein, São Paulo, SP, Brazil ORCID: https://orcid.org/0000-0003-4184-3867
Publication Dates
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Publication in this collection
20 May 2024 -
Date of issue
2024
History
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Received
26 Apr 2022 -
Accepted
18 Sept 2023