Rapid discrimination among dermatophytes, Scytalidium spp., and other fungi with a PCR-restriction fragment length polymorphism ribotyping method

Comparison of Samples of Blister Fluid and Scales in the diagnosis of dermatomycosis

BACKGROUND

The successful diagnosis of dermatomycosis depends on specimen collection. Dermatomycosis is sampled mainly for scales, but there is a lack of research on specimens of blister fluid.

OBJECTIVES

To explore whether blister fluid can diagnose dermatomycosis and compare blister fluid and scale specimens for dermatomycosis diagnosis.

METHODS

From April to July 2021, we prospectively gathered 34 patients who needed to meet all inclusion criteria simultaneously and collected their blister fluid and scales as specimens. The two samples were tested by fluorescent stain microscopy, fungal culture, and PCR, and the diagnosis results were compared.

RESULTS

The blister fluid sample's sensitivity, specificity, and accuracy were 90%, 100%, and 94.1%, respectively, whereas the scales sample were 60%, 100%, and 76.5%, respectively. The positive likelihood ratios were>10 for both blister fluid and scales specimen, and the negative likelihood ratios were not < 0.1. On the Youden's index, the blister fluid specimen was 90%, and the scales specimen was 60%. As for the diagnostic odds ratio, both of them were >1. By fungal culture, we detected 14 cases of fungi in blister fluid and eight in scales. On PCR, 22 cases of fungi in blister fluid and ten in scales were identified.

CONCLUSIONS

This study demonstrated that a sample of blister fluid had better sensitivity, accuracy, and Youden's index in diagnosing dermatomycosis with blister fluid. Collection of blister fluid might compensate for the inadequacy of collecting only scales specimens for mycological testing.

Utility of polymerase chain reaction for assessment of onychomycosis during topical therapy

BACKGROUND

Increased detection of fungi including non-dermatophyte molds (NDMs) using polymerase chain reaction (PCR) methods is well-established. However, the use of PCR to evaluate ongoing onychomycosis treatment outcome has not been investigated.

METHODS

Nail samples from 28 patients receiving topical efinaconazole were evaluated by both KOH/culture and PCR methods across the study period. Detection of microorganisms by PCR was compared to the culture at baseline and end of study at month 24 (M24). Fungal detection by both methods was evaluated with respect to clinical cure observed as 100% visual clearance of the target toenail.

RESULTS

By culture, all 28 subjects were dermatophyte-positive at pre-treatment; only 4/28 also exhibited an NDM microorganism. According to PCR, 24/28 subjects were dermatophyte-positive pre-treatment, with 25/28 also exhibiting NDMs. At M24, 18/28 (64.3%) participants had negative KOH/culture results, in contrast to 4/28 (14.3%) negative PCR results. PCR showed higher rates of NDM detection than the culture at baseline as well as M24. Calculations to compare the diagnostic utility of KOH/culture versus PCR found that positive tests with both methods reliably indicate the presence of onychomycosis, but negative PCR correlated better with onychomycosis cure than did KOH/culture.

DISCUSSION

PCR confirmed a high presence of NDMs pre-treatment, and continued presence of NDMs to M24, with unknown significance requiring further investigation. Though both KOH/culture and PCR have diagnostic limitations, PCR showed better overall utility than culture in predicting onychomycosis topical treatment outcome and should be more strongly considered for evaluation of topical therapies.

Recent trends in rapid diagnostic techniques for dermatophytosis

Dermatophytosis is a common contagious disease of both humans and animals. It is caused by a group of filamentous fungi known as dermatophytes, including several genera and various species. An accurate diagnosis of dermatophytes as a causative agent of a skin lesion requires up to one month of conventional laboratory diagnostics. The conventional gold standard diagnostic method is a direct microscopic examination followed by 3 to 4 weeks of Sabouraud's dextrose agar (SDA) culturing, and it may require further post-culturing identification through biochemical tests or microculture technique application. The laborious, exhaustive, and time-consuming gold standard method was a real challenge facing all dermatologists to achieve a rapid, accurate dermatophytosis diagnosis. Various studies developed more rapid, accurate, reliable, sensitive, and specific diagnostic tools. All developed techniques showed more rapidity than the classical method but variable specificities and sensitivities. An extensive bibliography is included and discussed through this review, showing recent variable dermatophytes diagnostic categories with an illustration of weaknesses, strengths, and prospects.

Trichophyton rubrum DNA Strains in Patients with Onychomycosis with Persistent Mixed Infections Involving a Nondermatophyte Mold

BACKGROUND

Onychomycosis is estimated to occur in approximately 10% of the global population, with most cases caused by Trichophyton rubrum. Some persistent onychomycosis is caused by mixed infections of T rubrum and one or more co-infecting nondermatophyte molds (NDMs). In onychomycosis, T rubrum strain types may naturally switch and may also be triggered to switch in response to antifungal therapy. T rubrum strain types in mixed infections of onychomycosis have not been characterized.

METHODS

T rubrum DNA strains in mixed infections of onychomycosis containing co-infecting NDMs were compared with a baseline North American population through polymerase chain reaction amplification of ribosomal DNA tandemly repetitive subelements (TRSs) 1 and 2. The baseline DNA strain types were determined from 102 clinical isolates of T rubrum. The T rubrum DNA strain types from mixed infections were determined from 63 repeated toenail samples from 15 patients.

RESULTS

Two unique TRS-2 types among the clinical isolates contributed to four unique TRS-1 and TRS-2 strain types. Six TRS-1 and TRS-2 strain types represented 92% of the clinical isolates of T rubrum. Four TRS-1 and TRS-2 strain types accounted for 100% of the T rubrum within mixed infections.

CONCLUSIONS

Four unique North American T rubrum strains were identified. In support of a shared ancestry, the T rubrum DNA strain types found in mixed infections with NDMs were among the most abundant types. A population of T rubrum strains in mixed infections of onychomycosis has been characterized, with more than one strain detected in some nails. The presence of a co-infecting NDM in mixed infections may contribute to failed therapy by stabilizing the T rubrum strain type, possibly preventing the antifungal therapy-induced strain type switching observed with infections caused by T rubrum alone.

High prevalence of mixed infections in global onychomycosis

Onychomycosis is estimated at a prevalence of 10% worldwide with the infecting organism most commonly Trichophyton rubrum (T. rubrum). Traditional culture identification of causative organisms has inherent risks of overestimating dermatophytes, like T. rubrum, by inhibiting the growth of possible nondermatophyte mould (NDM) environmental contaminants which could be causative agents. Recently, molecular methods have revealed that a proportion of onychomycosis cases in North America may be caused by mixed infections of T. rubrum as an agent co-infecting with one or more NDM. Determining the global burden of mixed infections is a necessary step to evaluating the best therapies for this difficult-to-treat disease. To determine the prevalence of mixed infections in a global population, nail samples from onychomycosis patients in Brazil, Canada, and Israel (n = 216) were analyzed by molecular methods for the presence of dermatophytes and five NDMs. If an NDM was detected, repeat sampling was performed to confirm the NDM. T. rubrum was detected in 98% (211/216) of infections with 39% mixed (84/216). The infection type was more likely to be mixed in samples from Brazil, but more likely to be a dermatophyte in samples from Canada and Israel (Χ² = 16.92, df = 2, P<0.001). The most common cause of onychomycosis was T. rubrum. In all countries (Brazil, Canada and Israel combined) the prevalence of dermatophyte (Χ² = 211.15, df = 3, P<0.001) and mixed (dermatophyte and NDM; Χ² = 166.38, df = 3, P<0.001) infection increased with patient age. Our data suggest that mixed infection onychomycosis is more prevalent than previously reported with the aging population being at increased risk for mixed infections.

Recent advances in the diagnosis of dermatophytosis

Dermatophytosis is a disease of global significance caused by pathogenic keratinolytic fungi called dermatophytes in both animals and humans. The recent taxonomy of dermatophytes classifies them into six pathogenic genera, namely Microsporum, Trichophyton, Epidermophyton, Nannizzia, Lophophyton and Arthroderma. It is because of the delayed diagnostic nature and low accuracy of dermatophyte detection by conventional methods that paved the path for the evolution of molecular diagnostic techniques, which provide the accurate and rapid diagnosis of dermatophytosis for an appropriate, timely antifungal therapy that prevents the nonspecific over-the-counter self-medication. This review focuses on the importance of rapid and accurate diagnosis of dermatophytosis, limitations of conventional methods, selection of targets in diagnosis, and factors affecting sensitivity and specificity of various molecular diagnostic technologies in the diagnosis of dermatophytosis. Generally, all the molecular techniques have a significant edge over the conventional methods of culture and microscopy in the dermatophytosis diagnosis. However, in mycology laboratory, the suitability of any molecular diagnostic technique in the diagnosis of dermatophytosis is driven by the requirement of time, economy, complexity, the range of species spectrum detected and the scale of diagnostic output required. Thus, various choices involved in the pursuit of a diagnosis of dermatophytosis are determined by the available conditions and the facilities in the laboratory.

Padronização de uma PCR para diagnóstico molecular de Microsporum canis em amostras de pelos e crostas de cães e gatos

RESUMO Objetivou-se neste estudo padronizar um protocolo de reação em cadeia da polimerase (PCR) para detecção de Microsporum canis em amostras de pelos e/ou crostas de cães e gatos. Foram selecionadas 48 amostras previamente identificadas por meio de cultura. Destas, 23 foram positivas para dermatófitos no cultivo. Padronizou-se a PCR a partir de primers desenhados para o alvo M. canis. Sessenta e um por cento (14/23) das amostras positivas para dermatófitos foram identificadas como M. canis em cultura. Desse total, 71,4% (10/14) apresentaram um fragmento de 218pb compatível com o esperado para a espécie fúngica alvo dessa reação. Observou-se uma sensibilidade de 71,4% e especificidade de 100% na PCR, além de uma boa concordância entre essas técnicas de diagnóstico (Kappa: 0,78; P<0,0001). O protocolo utilizado neste estudo apresentou alta especificidade na detecção de M. canis diretamente de amostras de pelos e/ou crostas de cães e gatos, viabilizando um diagnóstico mais rápido e específico, podendo esse protocolo ser empregado como um método confirmatório para agilizar a detecção de M. canis.

Clinical evaluation of the DermaGenius® Nail real-time PCR assay for the detection of dermatophytes and Candida albicans in nails

Onychomycosis represents one of the most frequent mycoses in the world. Causative agents are mainly dermatophytes, but yeasts and nondermatophyte moulds can also be involved. Conventional diagnostic methods include direct microscopy (or histology) and culturing. However, molecular methods are becoming increasingly popular in this field. The DermaGenius® (DG) Nail multiplex assay (PathoNostics, The Netherlands) is a new commercial real-time polymerase chain reaction (PCR) kit, which can detect Trichophyton rubrum, Trichophyton interdigitale and Candida albicans directly in nails. The present study is a retrospective evaluation of the kit applied to 138 finger and toenail clippings in comparison to histology and culture methods. The sensitivity and specificity of the PCR assay are 80% (76/95) and 74.4% (32/43), respectively, when histology and culture are used as reference to define onychomycosis. DG performance is not different from histology combined with culture (P = .11) but the best diagnostic efficacy (88.4%, 122/138) is obtained by the combination of histology and DG. In conclusion, this study emphasizes the clinical usefulness of the DG in diagnostics. The high specificity of this test guarantees a better identification compared to culture that can lead to dermatophyte misidentifications. It is a reliable PCR assay that shortens the time to diagnosis and can unmask the presence of nongrowing fungal pathogens in nails.

Onychomycosis InfectionsDo Polymerase Chain Reaction and Culture Reports Agree?

BACKGROUND

Mycological culture is the traditional method for identifying infecting agents of onychomycosis despite high false-negative results, slower processing, and complications surrounding nondermatophyte mold (NDM) infections. Molecular polymerase chain reaction (PCR) methods are faster and suited for ascertaining NDM infections.

METHODS

To measure agreement between culture and PCR methods for identification of infecting species of suspected onychomycosis, single toenail samples from 167 patients and repeated serial samples from 43 patients with suspected onychomycosis were processed by culture and PCR for identification of 16 dermatophytes and five NDMs. Agreement between methods was quantified using the kappa statistic (κ).

RESULTS

The methods exhibited fair agreement for the identification of all infecting organisms (single samples: κ = 0.32; repeated samples: κ = 0.38). For dermatophytes, agreement was moderate (single samples: κ = 0.44; repeated samples: κ = 0.42). For NDMs, agreement was poor with single samples (κ = 0.16) but fair with repeated samples (κ = 0.25). Excluding false-negative reports from analyses improved agreement between methods in all cases except the identification of NDMs from single samples.

CONCLUSIONS

Culture was three or four times more likely to report a false-negative result compared with PCR. The increased agreement between methods observed by excluding false-negative reports statistically clarifies and highlights the major discord caused by false-negative cultures. The increased agreement of NDM identification from poor to fair with repeated sampling along with their poor agreement in the single samples, with and without false-negatives, affirms the complications of NDM identification and supports the recommendation that serial samples help confirm the diagnosis of NDM infections.

Diagnosis of Dermatophytosis Using Molecular Biology

Identification of fungi in dermatological samples using PCR is reliable and provides significantly improved results in comparison with cultures. It is possible to identify the infectious agent when negative results are obtained from cultures. In addition, identification of the infectious agent can be obtained in 1 day. Conventional and real-time PCR methods used for direct fungus identification in collected samples vary by DNA extraction methods, targeted DNA and primers, and the way of analysing the PCR products. The choice of a unique method in a laboratory is complicated because the results expected from skin and hair sample analysis are different from those expected in cases of onychomycosis. In skin and hair samples, one dermatophyte among about a dozen possible species has to be identified. In onychomycosis, the infectious agents are mainly Trichophyton rubrum and, to a lesser extent, Trichophyton interdigitale, but also moulds insensitive to oral treatments used for dermatophytes, which renders fungal identification mandatory. The benefits obtained with the use of PCR methods for routine analysis of dermatological samples have to be put in balance with the relative importance of getting a result in a short time, the price of molecular biology reagents and equipment, and especially the time spent conducting laboratory manipulations.

Molecular diagnosis of onychomycosis

Onychomycosis is a frequent cause of nail infections due to dermatophytes. Molds and yeast may also be responsible of these pathologies. Antifungal treatments are frequently given without a mycological diagnosis, partly because of the requisite time for obtaining the biological results. The mycological diagnosis requires a direct microscopic examination and a culture in order to accurately identify the fungal genus and species. Nevertheless, this conventional diagnosis is often time consuming due to the delay of fungal cultures and presents disadvantages that make it not sufficient enough to give a precise and confident response to the clinicians. Therefore additional tests have been developed to help distinguish onychomycosis from other nail disorders. Among them, molecular biology techniques offer modern and rapid tools to improve traditional microbiological diagnosis. In this review, we first present the conventional diagnosis methods for onychomycosis and then we describe the main molecular biology tools and the currently available commercial kits that allow a rapid detection of the pathology.

Molecular determination of mixed infections of dermatophytes and nondermatophyte molds in individuals with onychomycosis

BACKGROUND

Reports of mixed infections with nondermatophyte molds (NDMs) and dermatophytes in onychomycosis are rare, possibly owing to the inhibition of NDM growth during traditional culture. We sought to determine the prevalence of mixed infections in onychomycosis using molecular identification.

METHODS

Molecular analyses were used to identify infecting organisms directly from at least two serial great toenail samples from each of the 44 patients.

RESULTS

Mixed infections were present in 41% of the patients (18 of 44). A single coinfecting NDM was the most common mixed infection and was detected in 34% of patients with onychomycosis (15 of 44), with Fusarium oxysporum present in 14% (6 of 44), Scopulariopsis brevicaulis in 9% (4 of 44), Acremonium spp in 2% (1 of 44), Aspergillus spp in 4.5% (2 of 44), and Scytalidium spp in 4.5% (2 of 44). Mixed infections with two NDMs were found in 7% of patients (3 of 44).

CONCLUSIONS

Mixed onychomycosis infections may be more prevalent than previously reported.

Optimization of PCR-RFLP Directly from the Skin and Nails in Cases of Dermatophytosis, Targeting the ITS and the 18S Ribosomal DNA Regions

PURPOSE

A pan fungal primer targeting the Internal Transcribed Spacer (ITS) region and optimization of PCR-RFLP using a dermatophyte specific primer targeted the 18S ribosomal DNA (rDNA) region were performed for the identification of dermatophyte species and strains directly from clinical specimens.

MATERIALS AND METHODS

One hundred and thirty eight specimens (129 skin scrapings and 9 nail clippings) from clinically suspected cases of dermatophytosis were collected and subjected to direct microscopy and culture. Among them, 66 skin scrapings and 3 nail clippings were processed for genotyping by PCR-RFLP analysis using the Mva I, Hae III and the Dde I restriction enzymes.

RESULTS

Of the 138 specimens, 81 specimens were positive for dermatophytosis, the most common one being Trichophyton rubrum (47), followed by Trichophyton mentagrophytes (25) and Epidermophyton floccosum (9). Of the 47 T. rubrum isolates, 10 were T. rubrum var. raubitschekii which were identified phenotypically as urease positive and by DNA sequencing. Since they exhibited minor morphological and physiological features, they have currently been synonymized with T. rubrum. Of the 25 T. mentagrophytes isolates, three were Trichophyton interdigitale, which were identified by DNA sequencing. Among the 66 skin specimens smear, culture and PCR showed the presence of dermatophytes in 36 (54.54%), 42 (63.63%) and 47 (71.21%) cases respectively. Among the three nail specimens, only one was found to be positive for dermatophytosis by smear, culture and PCR.

CONCLUSION

Amplification of the dermatophyte specific primer is appropriate in the identification of dermatophytes directly from the clinical material. PCR targeting the ITS region by using the Mva I and the Dde I enzymes was equally good for the RFLP analysis. However, by using the above three restriction enzymes, no strain variations were detected among the T. rubrum and the T. mentagrophytes strains.

Confocal laser scanning microscopy as a new valuable tool in the diagnosis of onychomycosis - comparison of six diagnostic methods

Onychomycosis is common and can mimic several different nail disorders. Accurate diagnosis is essential to choose the optimum antifungal therapy. The aim of this study was to evaluate the use of confocal laser scanning microscopy (CLSM) and optical coherence tomography (OCT) as new non-invasive diagnostic tools in onychomycosis and to compare them with the established techniques. In a prospective trial, 50 patients with suspected onychomycosis and 10 controls were examined by CLSM and OCT. Parallel KOH preparation, culture, PAS-staining and PCR were performed. PCR showed the highest sensitivity, followed by CLSM, PAS and KOH preparation. OCT offered the second best sensitivity but displayed the lowest specificity. CLSM and KOH preparation showed a high specificity and CLSM offered the best positive predictive value, similar to KOH preparation and OCT. Fungal culture showed the lowest sensitivity and the worst negative predictive value, yet culture and PCR are the only techniques able to identify genus and species. In summary, CLSM was comparable to PAS staining and superior to KOH preparation. Due to the low specificity we assess OCT not as appropriate. In the differentiation of species PCR outplays the fungal culture in terms of time and sensitivity.

Identification of infectious agents in onychomycoses by PCR-terminal restriction fragment length polymorphism

A fast and reliable assay for the identification of dermatophyte fungi and nondermatophyte fungi (NDF) in onychomycosis is essential, since NDF are especially difficult to cure using standard treatment. Diagnosis is usually based on both direct microscopic examination of nail scrapings and macroscopic and microscopic identification of the infectious fungus in culture assays. In the last decade, PCR assays have been developed for the direct detection of fungi in nail samples. In this study, we describe a PCR-terminal restriction fragment length polymorphism (TRFLP) assay to directly and routinely identify the infecting fungi in nails. Fungal DNA was easily extracted using a commercial kit after dissolving nail fragments in an Na(2)S solution. Trichophyton spp., as well as 12 NDF, could be unambiguously identified by the specific restriction fragment size of 5'-end-labeled amplified 28S DNA. This assay enables the distinction of different fungal infectious agents and their identification in mixed infections. Infectious agents could be identified in 74% (162/219) of cases in which the culture results were negative. The PCR-TRFLP assay described here is simple and reliable. Furthermore, it has the possibility to be automated and thus routinely applied to the rapid diagnosis of a large number of clinical specimens in dermatology laboratories.

Rapid screening for genotypes as possible markers of virulence in the neurotropic black yeast Exophiala dermatitidis using PCR-RFLP

A simple method for fungal genotype screening was developed for the black yeast Exophiala dermatitidis based on RFLP of ribosomal ITS regions currently used as potential virulence markers. In a study set of 502 strains of the species, two main genotypes were recognized. Only 0.97% of lanes were difficult to interpret as they did not clearly present one of the expected genotypes. Twenty strains were deviating and proved to be E. spinifera after sequencing. Eight common, related species (based on SSU data) with clinical significance yielded different patterns with TaqI digestion, and thus the method is also usable for routine diagnostics.

Conventional methods for the diagnosis of dermatophytosis

Dermatophytes are keratinolytic fungi responsible for a large variety of diseases that can affect glabrous skin, nails and hair. In many cases, the diagnosis is not clinically obvious, and mycological analysis is required. This includes both direct microscopic examination and cultures. First of all, clinical specimens have to be sampled according to localization and characteristics of the lesions. Direct microscopic examination is usually performed using clearing reagents (KOH or Amman's chloral-lactophenol), but its sensitivity may be greatly enhanced by the use of stains or fluorochromes such as Congo red or Calcofluor white. Histological analysis is an efficient method, but it is constraining for the patients and, as direct examination, it does not allow precise identification of the pathogen. Cultures are therefore needed, and specific culture media may be used to overcome the growth of rapidly growing contaminating moulds which may hamper the recovery of dermatophytes. Identification at the species level which may be useful to initiate an appropriate treatment or for setting prophylactic measures, relies on macroscopic and microscopic morphology. Subcultures on culture media which stimulate conidiation and, for some species, the production of pigments, are often necessary. Additionally, in case of atypical isolates, some biochemical or physiological tests may be performed such as the search for urease activity or the in vitro hair perforation test. However, their contribution to species identification is rather limited, and progress is still needed for the development of biochemical or immunological tests allowing an accurate identification at the species level, pending for the availability of molecular biology-based kits.

Application of polymerase chain reaction (PCR) and PCR based restriction fragment length polymorphism for detection and identification of dermatophytes from dermatological specimens

OBJECTIVE

To develop and optimize polymerase chain reaction-based restriction fragment length polymorphism (PCR-RFLP) targeting 18S rDNA and internal transcribed spacer (ITS) region of fungi for rapid detection and identification of dermatophytes.

MATERIALS AND METHODS

Two PCR-RFLP methods targeting 18S rDNA and ITS regions of fungi were optimized using standard and laboratory isolates of dermatophytes and other fungi. Sixty-eight dermatological clinical specimens (nail clippings (56), material obtained from blisters (8), hair root (2), scraping from scaly plaque of foot (1) and skin scraping (1) collected by the dermatologist were subjected to both the optimized PCR-RFLP and conventional mycological (smear and culture) methods.

RESULTS

PCRs targeting 18S rDNA and the ITS region were sensitive to detect 10 picograms and 1 femtogram of T. rubrum DNA, respectively. PCR targeting 18S rDNA was specific for dermatophytes and subsequent RFLP identified them to species level. PCR-RFLP targeting the ITS region differentiated dermatophytes from other fungi with identification to species level. Among the 68 clinical specimens tested, both PCR-RFLP methods revealed the presence of dermatophytes in 27 cases (39.7%), whereas culture revealed the same only in 2 cases (7.40%), increasing the clinical sensitivity by 32.3%. Among 20 smear positive specimens, both PCR-RFLP methods detected dermatophytes in 12 (17.6%). Both the methods detected the presence of dermatophytes in 13 (19.11%) smear and culture negative specimens, increasing the clinical sensitivity by 36.1%.

CONCLUSION

PCR-RFLP methods targeting 18S rDNA and the ITS regions of fungi were specific and highly sensitive for detection and speciation of dermatophytes.

Diagnosis of common dermatophyte infections by a novel multiplex real-time polymerase chain reaction detection/identification scheme

BACKGROUND

In the absence of a functional dermatophyte-specific polymerase chain reaction (PCR), current diagnosis of dermatophytoses, which constitute the commonest communicable diseases worldwide, relies on microscopy and culture. This combination of techniques is time-consuming and notoriously low in sensitivity.

OBJECTIVES

Recent dermatophyte gene sequence records were used to design a real-time PCR assay for detection and identification of dermatophytes in clinical specimens in less than 24 h.

PATIENTS AND METHODS

Two assays based on amplification of ribosomal internal transcribed spacer regions and on the use of probes specific to relevant species and species-complexes were designed, optimised and clinically evaluated. One assay was for detecting the Trichophyton mentagrophytes species complex plus T. tonsurans and T. violaceum. The second assayed for the T. rubrum species complex, Microsporum canis and M. audouinii.

RESULTS

The analytical sensitivity of both assays was 0.1 pg DNA per reaction, corresponding to 2.5-3.3 genomes per sample. The protocol was clinically evaluated over 6 months by testing 92 skin, nail and hair specimens from 67 patients with suspected dermatophytosis. Real-time PCR detected and correctly identified the causal agent in specimens from which T. rubrum, T. interdigitale, M. audouinii or T. violaceum grew in culture, and also identified a dermatophyte species in an additional seven specimens that were negative in microscopy and culture.

CONCLUSIONS

This highly sensitive assay also proved to have high positive and negative predictive values (95.7% and 100%), facilitating the accurate, rapid diagnosis conducive to targeted rather than empirical therapy for dermatophytoses.

Identification of Microsporum canis from dermatophytic pseudomycetoma in paraffin-embedded veterinary specimens using a common PCR protocol

The effectiveness of a simple PCR protocol performed on paraffin-embedded tissues, obtained from histopathologically and culturally diagnosed cases of dermatophytic pseudomycetoma DPM was tested. The specimens were investigated using previously described primers (DH1L and DH1R) targeting the 18S rDNA gene and amplifying a 183-bp fragment. Microsporum canis was identified from all samples. The PCR protocol described in the present work demonstrated a 100% concordant result comparing the molecular characterisation with phenotypic characterisation of dermatophytes. Molecular biology could represent a valid identification tool in dermatophytic deep infections, when diagnosis cannot be achieved by cultural methods.

Multicenter evaluation of a commercial PCR-enzyme-linked immunosorbent assay diagnostic kit (Onychodiag) for diagnosis of dermatophytic onychomycosis

We prospectively evaluated a new PCR-enzyme-linked immunosorbent assay kit (Onychodiag; BioAdvance, France) for the diagnosis of dermatophytic onychomycosis by testing nail samples from 438 patients with suspected onychomycosis and from 108 healthy controls in three independent laboratories. In two laboratories, samples were collected by trained mycologists as close as possible to the lesions (proximal samples). In one laboratory, samples were collected by other physicians. All samples were processed by conventional mycological techniques and by Onychodiag, blindly to the mycological results. An additional distal sample, collected by clipping the nail plate, was obtained from 75 patients and tested with Onychodiag alone. In patients with culture-proven dermatophytic onychomycosis, the sensitivity of Onychodiag was 83.6% (87.9% including the gray zone) and ranged from 75 to 100% according to the laboratory and the sampling conditions. The specificity was 100% when healthy subjects were considered true negative controls. Onychodiag was positive on 68 patient samples that were sterile or yielded nondermatophyte species in culture. Based on the results of Onychodiag for mycologically proven positive samples and true-negative samples, these results were considered true positives, and the poor performance of mycology on these samples was attributed to inconvenient sampling conditions or to contaminants. When tested on distal samples, Onychodiag was positive in 49/53 (92%) cases of proven dermatophytic onychomycosis. Finally, with either proximal or distal samples, Onychodiag provided a diagnosis of dermatophytic onychomycosis within 24 to 48 h after sampling, and its sensitivity was close to that of mycological techniques applied to proximal samples.

Scytalidium Keratitis

PURPOSE

To describe the presentation and treatment of a case of an atypical reticular corneal infiltrate with surrounding immune-like ring in a young woman caused by Scytalidium fungal species.

METHODS

Interventional case report describing the clinical appearance, course, and treatment of Scytalidium keratitis.

RESULTS

A 21-year-old female equestrian with a history of soft contact lens wear was noted to have persistent keratitis and photophobia of the right eye after an injury with a volleyball. Although initially culture negative and responsive to topical steroids, the keratitis persisted, and repeat corneal scrapings and cultures revealed Scytalidium species. Treatment with topical amphotericin B 0.15% and oral fluconazole 200 mg twice daily eradicated the infection, and the patient had a final best-corrected visual acuity of 20/20.

CONCLUSION

Scytalidium species fungal organisms can cause an indolent keratitis. Intensive oral and topical antifungal therapy was successful in eradicating the infection.

Molecular analysis of fungal microbiota in samples from healthy human skin and psoriatic lesions

Psoriasis, a common cutaneous disease of unknown etiology, may be triggered by infections, including those due to fungi. Since the fungal community of human skin is poorly characterized, we aimed to analyze the mycological microbiota in healthy skin and psoriatic lesions. Twenty-five skin samples from five healthy subjects (flexor forearm) and three patients with psoriasis were analyzed using broad-range 18S ribosomal DNA (rDNA) and 5.8S rDNA/internal transcribed spacer 2 (ITS2) Malassezia-specific PCR primers. Broad-range PCR analysis indicated that most organisms resembled Malassezia. Malassezia-specific 5.8S/ITS2 analysis of 1,374 clones identified five species and four unknown phylotypes, potentially representing new species. The species distribution appears largely host specific and conserved in different sites of healthy skin. In three subjects, the Malassezia microbiota composition appeared relatively stable over time. Samples of Malassezia microbiota from healthy skin and psoriatic lesions were similar in one patient but substantially different in two others. These data indicate the predominance of Malassezia organisms in healthy human skin, host-specific variation, stability over time, and as yet, no consistent patterns differentiating psoriatic skin from healthy skin.

Trichophyton species: use of volatile fingerprints for rapid identification and discrimination

BACKGROUND

Fungal infection of the skin is a common clinical problem, and laboratory confirmation of the diagnosis is important to ensure appropriate treatment. The identification of the species of fungus is also important, because different fungal species have different modes of transmission, and this may be of importance both in preventing re-infection and in avoidance of infection of others.

OBJECTIVES

This study examined the potential of using volatile production patterns for the detection and discrimination between four Trichophyton species (T. mentagrophytes, T. rubrum, T. verrucosum and T. violaceum) in vitro on solid media and in broth culture.

METHODS

Two different sensor array systems (conducting polymer and metal oxide sensors) were examined for comparing the qualitative volatile fingerprints produced in the headspace by these species over periods of 24-120 h. The relative sensitivity of detection of two of the species (T. mentagrophytes, T. rubrum) was determined for log 1 to log 7 inoculum levels over the same time period.

RESULTS

The conducting polymer-based system was unable to differentiate between species based on volatile fingerprints over the experimental period. However, metal oxide-based sensor arrays were found to be able to differentiate between the four species within 96 h of growth using principal component analysis which accounted for approximately 94% of the data in principal components 1 and 2 based on the qualitative volatile production patterns. This differentiation was confirmed by cluster analysis of the data using Euclidean distance and Ward's linkage. Studies of the sensitivity of detection showed that for T. mentagrophytes and T. rubrum it was possible to differentiate between log 3, log 5 and log 7 inoculum levels within 96 h.

CONCLUSIONS

This is the first detailed study of the use of qualitative volatile fingerprints for identification and discrimination of dermatophytes. This approach could have potential for rapid identification of patient samples, reducing significantly the time to treatment.

Fast and reliable PCR/sequencing/RFLP assay for identification of fungi in onychomycoses

Fusarium spp. and other non-dermatophyte fungi are repeatedly isolated from abnormal nails. To investigate whether these fungi are the aetiological agents of infection or simply transient contaminants, a PCR/sequencing/RFLP assay was developed for direct and routine identification of the infecting fungi in onychomycosis. Fungal DNA was readily extracted using a commercial kit after dissolving nail fragments in a Na2S solution. Amplification of part of the 28S rDNA by PCR was performed with universal primers and the fungal species were identified by sequencing. The PCR/sequencing results were comparable with microbiological identification from the same nail sample. In addition to dermatophytes, Fusarium spp. and other less frequently isolated non-dermatophyte fungi were identified as single fungal agents in onychomycosis. Moreover, mixed infections were clearly demonstrated in 10 % of cases by RFLP analysis of PCR products. Identification of infectious agents could be obtained in 2 days, whilst results from fungal cultures take 1–3 weeks. Rapid and reliable molecular identification of the infectious fungus expedites the choice of appropriate antifungal therapy, thereby improving the cure rate of onychomycosis.

Diagnosing Onychomycosis

Onychomycosis is the most prevalent nail disease, representing nearly half of all clinically diagnosed onychopathies. Given the pervasive nature of the disease and that successful treatment depends on the proper identification of the causative organism,accurate and reliable methods of diagnosis are necessary. This article discusses the efficacy of the various methods used for the diagnosis of onychomycosis.

Rapid identification and differentiation of fungal DNA in dermatological specimens by LightCycler PCR

The aim was to develop a LightCycler PCR method for the rapid detection and differentiation of fungal DNA in dermatological specimens such as skin scales and skin swabs. LightCycler PCR assays were established for seven primer sets specific for fungal DNA. For each primer set LightCycler melting points were defined by amplification of DNA from 21 fungi and sensitivity was determined by amplification of serial dilutions of fungal DNA. A protocol was established that allows detection and differentiation of mould and yeast DNA with one highly sensitive PCR reaction by assessment of LightCycler melting points. Two subsequent LightCycler PCR reactions and one RFLP reaction allowed the differentiation of dermatophytes and non-dermatophyte moulds and the subclassification of yeasts. Analysis of clinical samples from 38 patients with fungal skin diseases provided conclusive new diagnostic information in 9/38 cases (23.7 %) by this PCR protocol that was not equally provided by direct microscopy and mycological culture. Thus the LightCycler PCR protocol established here represents a rapid diagnostic tool that aids in the diagnosis of fungal skin disease in a substantial number of patients.

Molecular detection and typing of fungal pathogens

A major goal of molecular testing is to develop a cost-effective as well as sensitive and specific assay that can detect microbial DNA in clinical samples early in the course of disease. Additionally, the ability to analyze the genetic relatedness of fungi on a timelier basis using molecular methods will have a positive impact on epidemiologic investigating. As technology advances, it seems apparent that commercially available molecular assays will become available in the near future for the management of patients with suspected fungal infections.

Identification of the pathogenic Aspergillus species by nested PCR using a mixture of specific primers to DNA topoisomerase II gene

For PCR-based identification of Aspergillus species, a common primer of the DNA topoisomerase II genes of Candida, Aspergillus and Penicillium, and species-specific primers of the genomic sequences of DNA topoisomerase II of A. fumigatus, A. niger, A. flavus (A. oryzae), A. nidulans and A. terreus were tested for their specificities in PCR amplifications. The method consisted of amplification of the genomic DNA topoisomerase II gene by a common primer set, followed by a second PCR with a primer mix consisting of 5 species-specific primer pairs for each Aspergillus species. By using the common primer pair, a DNA fragment of approximately 1,200 bp was amplified from the Aspergillus and Penicillium genomic DNAs. Using each species-specific primer pair, unique sizes of PCR products were amplified, all of which corresponded to a species of Aspergillus even in the presence of DNAs of several fungal species. The sensitivity of A. fumigatus to the nested PCR was found to be 100 fg of DNA in the reaction mixture. In the nested PCR obtained by using the primer mix (PsIV), the specific DNA fragment of A. fumigatus was amplified from clinical specimens. These results suggest that this nested PCR method is rapid, simple and available as a tool for identification of pathogenic Aspergillus to a species level.

Nucleotide structure of the Scytalidium hyalinum and Scytalidium dimidiatum 18S subunit ribosomal RNA gene: evidence for the insertion of a group IE intron in the rDNA gene of S. dimidiatum

The molds Scytalidium dimidiatum (Nattrassia mangiferae synanamorph) and Scytalidium hyalinum are responsible for dermatomycosis in humans. We sequenced their 18S subunit ribosomal RNA gene to identify these species with molecular biology-based methods. The coding sequences differed by a single polymorphism (A in S. dimidiatum, G in S. hyalinum). Moreover, we found an insert at position 1199 in the 18S rRNA gene sequence of S. dimidiatum. Its potential secondary structure was characteristic of a group IE intron. Bioinformatic and phylogenic group IE intron analyses generated four main homogeneous clusters. The S. dimidiatum intron is original and not related with other known IE group introns.