Abstract
Candida albicans causes life-threatening systemic infections in immunosuppressed patients. These infections are commonly treated with fluconazole, an antifungal agent targeting the ergosterol biosynthesis pathway. Current Antifungal Susceptibility Testing (AFST) methods are time-consuming and are often subjective. Moreover, they cannot reliably detect the tolerance phenomenon, a breeding ground for the resistance. An alternative to the classical AFST methods could use Matrix-Assisted Laser Desorption/Ionization Time-of-Flight (MALDI-TOF) Mass spectrometry (MS). This tool, already used in clinical microbiology for microbial species identification, has already offered promising results to detect antifungal resistance on non-azole tolerant yeasts. Here, we propose a machine-learning approach, adapted to MALDI-TOF MS data, to qualitatively detect fluconazole resistance in the azole tolerant species C. albicans. MALDI-TOF MS spectra were acquired from 33 C. albicans clinical strains isolated from 15 patients. Those strains were exposed for 3 h to 3 fluconazole concentrations (256, 16, 0 μg/mL) and with (5 μg/mL) or without cyclosporin A, an azole tolerance inhibitor, leading to six different experimental conditions. We then optimized a protein extraction protocol allowing the acquisition of high-quality spectra, which were further filtered through two quality controls. The first one consisted of discarding not identified spectra and the second one selected only the most similar spectra among replicates. Quality-controlled spectra were divided into six sets, following the sample preparation’s protocols. Each set was then processed through an R based script using pre-defined housekeeping peaks allowing peak spectra positioning. Finally, 32 machine-learning algorithms applied on the six sets of spectra were compared, leading to 192 different pipelines of analysis. We selected the most robust pipeline with the best accuracy. This LDA model applied to the samples prepared in presence of tolerance inhibitor but in absence of fluconazole reached a specificity of 88.89% and a sensitivity of 83.33%, leading to an overall accuracy of 85.71%. Overall, this work demonstrated that combining MALDI-TOF MS and machine-learning could represent an innovative mycology diagnostic tool.
Highlights
Candida albicans is one of the most common opportunistic pathogens in humans (Naglik et al, 2011)
The aim of this study is to develop a MALDI-TOF MS procedure using machine learning to detect fluconazole resistance in C. albicans strains despite the tolerance phenomenon
Of the fungal suspension (FS) and formic acid (FA) volumes used, the beadbased extraction allowed the acquisition of better-quality spectra (Welch two sample t-test: p-value = 3.0 × 10−11), with 87.10% of the spectra being correctly identified as belonging to C. albicans, against only 49.62% for the FA-based extraction (Supplementary Figure S2A)
Summary
Candida albicans is one of the most common opportunistic pathogens in humans (Naglik et al, 2011). C. albicans superficial infection are not life threatening, systemic infections can lead to a mortality up to 50% (Brown et al, 2012). A recent study, based on data collected in the United States, concluded that even if it does not statistically improve patient outcome, an appropriate antifungal stewardship allows a significant reduction in antifungal use (Hart et al, 2019). Early detection of antifungal susceptibility is required to improve antifungal stewardship and to act against antifungal resistance rising. This is pertinent regarding the recent emergence of the highly drugresistant C. auris (Spivak and Hanson, 2018; Kordalewska and Perlin, 2019)
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