Molecular Mycological Diagnosis and Correct Antimycotic Treatments

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case of a Scedosporium apiospermum soft tissue infection in an immunocompromised .... dosporium prolificans and Scedosporium apiospermum. J. Antimicrob.
JOURNAL OF CLINICAL MICROBIOLOGY, July 2005, p. 3584–3585 0095-1137/05/$08.00⫹0 doi:10.1128/JCM.43.7.3584–3585.2005

Vol. 43, No. 7

Molecular Mycological Diagnosis and Correct Antimycotic Treatments In a recent report, Schaenman and colleagues (5) describe a case of a Scedosporium apiospermum soft tissue infection in an immunocompromised patient successfully treated with voriconazole. The article focuses on one of the hottest topics in current medical mycology, the emergence of antimycotic-resistant fungal isolates (3). Indeed, Scedosporium apiospermum is, also in our direct experience, one of the emerging fungal pathogens frequently endowed with resistance against drugs used as first-line agents (i.e., amphotericin B and fluconazole) (2). Therefore, we agree to the general message of the paper regarding the need of a prompt and well designed antifungal therapy. However, we would like to address a major point on how this could be achieved. In fact, we disagree that presumptive fungal identification based on aspecific morphological aspects is sufficient to take into account a new drug such as voriconazole as a first-line agent in the management of fungal infections. As admitted by the authors and clearly shown in Fig. 2 of their case report, many fungal genera feature morphological characteristics difficult to discriminate and the identification is not straightforward, especially if specific structures are not usually evident, as may be the case upon direct examination of clinical samples. A clinician making the same assumption as the authors might feel free to treat critically ill patients with voriconazole in the majority of cases, thus putting the whole community at risk for the emergence of new resistances to this valuable drug, as has already and inevitably happened for narrow-spectrum triazoles. Moreover it is still far from being proven that the toxicity profile of the new extended-spectrum triazoles is really safer than that of narrow-spectrum drugs, with severe side effects reported in up to 10% of patients receiving voriconazole (1). We think that a rapid and precise identification, at least at the genus level, is crucial for the prescription of a well designed empirical therapy, but we are convinced that it should be based on objective data. Recently, we addressed the diagnosis of mycotic keratitis using, in parallel with cultural methodologies, a molecular approach based on direct amplification from the biological sample and sequencing, by means of universal fungal primers (4, 6), of genus- and species-specific targets on the fungal genome. In our opinion this molecular approach allowing unequivocal identification of a fungal pathogen, at least at the genus level, in only one day is, together with a more thorough understanding of mechanisms of drug resistance, a real improvement of the conventional mycological diagnosis and represents a correct answer to the clinical questions posed by the availability of multiple classes of antifungal agents.

tential pitfalls in the transition from intravenous to oral therapy. J. Clin. Microbiol. 43:973–977. 6. White, T., T. Burns, S. Lee, and J. Taylor. 1990. Amplification and direct sequencing of fungal ribosomal RNA genes for phylogenetics, p. 315–322. In M. A. Innis, D. H. Gelfand, J. J. Sninsky, and T. J. White (ed.), PCR protocols. Academic Press, San Diego, Calif.

Nicasio Mancini* Cristina M. Ossi Mario Perotti Massimo Clementi Laboratorio di Microbiologia Diagnostica e Ricerca San Raffaele Via Olgettina, 60 20132 Milan, Italy *Phone: 39 02 2643 2301 Fax: 39 02 2643 2640 E-mail: [email protected]

Authors’ Reply Mancini and colleagues raise a number of issues regarding the diagnosis and treatment of fungal infections. They suggest, for example, that fungal morphology lacks sufficient specificity to guide antifungal therapy. However, morphological features that lack adequate specificity for precise fungal identification may still provide clinically useful information. For example, Fig. 2 in our report depicts two filamentous fungi (Scedosporium apiospermum and Aspergillus fumigatus) that exhibit a similar morphology of thin septate hyphae branching at acute angles (9). Although no antifungal agent has reliable efficacy against all molds that share this morphology, amphotericin B has historically proven to be ineffective for the treatment of S. apiospermum infection, whereas voriconazole has a spectrum of in vitro antifungal activity that includes both S. apiospermum and Aspergillus spp. (1, 3). For the immunocompromised patient whose case was described in our report, the selection of voriconazole on the basis of this morphology proved to be expedient as the isolated mold was later identified as S. apiospermum. Despite the usefulness of fungal morphology in some cases, we agree with Mancini and coauthors that improved tests for the early microbiologic diagnosis of invasive mycoses are needed. New assays, however, require proper validation before their introduction into routine clinical use. Mancini and colleagues write that they have modified the broad-range fungal PCR protocol of Pryce et al. (8) for direct amplification of an rRNA gene from clinical samples in the diagnosis of mycotic keratitis. The validation and day-to-day use of fungal PCR, however, is not straightforward. These assays may be particularly prone to false-positive results due to the ubiquity of airborne fungal spores as well as the potential for contaminating fungal DNA in commercial lots of common reagents (5). In addition, a direct amplification approach brings with it issues of DNA extraction efficiency, PCR inhibition, and commensal DNA contamination which may vary with respect to tissue type (4). The substantial scientific rigor required to validate new molecular assays has been documented by national laboratory standard committees (6, 7) and by independent investigators (2, 4). It appears that Mancini et al. have not yet published their study; therefore, we are unable to determine to what degree validation has been addressed.

REFERENCES 1. Maertens, J. A. 2004. History of the development of azole derivatives. Clin. Microbiol. Infect. 10(Suppl. 1):1–10. 2. Meletiadis, J., J. F. Meis, J. W. Mouton, J. L. Rodriquez-Tudela, J. P. Donnelly, and P. E. Verweij. 2002. In vitro activities of new and conventional antifungal agents against clinical Scedosporium isolates. Antimicrob. Agents Chemother. 46:62–68. 3. Pfaller, M. A., and D. J. Diekema. 2004. Rare and emerging opportunistic fungal pathogens: concern for resistance beyond Candida albicans and Aspergillus fumigatus. J. Clin. Microbiol. 42:4419–4431. 4. Pryce, T. M., S. Palladino, I. D. Kay, and G. W. Coombs. 2003. Rapid identification of fungi by sequencing the ITS1 and ITS2 regions using an automated capillary electrophoresis system. Med. Mycol. 41:369–381. 5. Schaenman, J. M., D. B. Digiulio, L. F. Mirels, N. M. McClenny, G. J. Berry, A. W. Fothergill, M. G. Rinaldi, and J. G. Montoya. 2005. Scedosporium apiospermum soft tissue infection successfully treated with voriconazole: po-

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LETTERS TO THE EDITOR

Even if all validation issues were resolved, the nucleic acid sequencing required by a broad-range PCR approach is not currently performed by most clinical microbiology laboratories. This effectively curtails the present usefulness of broadrange assays for the vast majority of clinicians. In their study, Pryce and colleagues had access to the West Australian Genome Resource Centre for their sequencing needs (8). For those with similar resources, we encourage the continued investigation of molecular assays to facilitate their potential validation for clinical use. For example, we are evaluating inhouse broad-range fungal PCR and real-time PCR assays for analysis of clinical samples under a research protocol (D. B. DiGiulio et al., unpublished data). For the above reasons, among others, we believe that therapeutic decisions informed by the thoughtful interpretation of fungal morphology will continue to be required of clinicians into the foreseeable future. When morphology characterized by thin septate hyphae branching at acute angles is evident (thereby rendering zygomycetes unlikely), we believe that data support the consideration of voriconazole as a first-line agent. As discussed in our paper, toxicity is a consideration when prescribing voriconazole. We believe, however, that voriconazole’s toxicity profile must be judged vis-a`-vis the toxicities of alternative antifungal therapies. Finally, we share Mancini and coauthors’ concerns about the widespread use of newer antifungal agents. In our report, however, we advocate, not the indiscriminate use of voriconazole, but rather a targeted therapeutic approach that is informed by all the evidence available to the clinician, including morphology. When such evidence supports a specific agent as a therapeutic option for the treatment of relatively rare, serious infections, we do not believe that concerns regarding community resistance justify withholding this option from individual patients, particularly those who are critically ill or immunocompromised. REFERENCES 1. Cuenca-Estrella, M., B. Ruiz-Diez, J. V. Martinez-Suarez, A. Monzon, and J. L. Rodriguez-Tudela. 1999. Comparative in-vitro activity of voriconazole (UK-109,496) and six other antifungal agents against clinical isolates of Scedosporium prolificans and Scedosporium apiospermum. J. Antimicrob. Chemother. 43:149–151. 2. Dimech, W., D. S. Bowden, B. Brestovac, K. Byron, G. James, D. Jardine, T. Sloots, and E. M. Dax. 2004. Validation of assembled nucleic acid-based tests in diagnostic microbiology laboratories. Pathology 36:45–50. 3. Espinel-Ingroff, A. 2001. In vitro fungicidal activities of voriconazole, itraconazole, and amphotericin B against opportunistic moniliaceous and dematiaceous fungi. J. Clin. Microbiol. 39:954–958. 4. Forbes, B. A. 2003. Introducing a molecular test into the clinical microbiology

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laboratory: development, evaluation, and validation. Arch. Pathol. Lab. Med. 127:1106–1111. Loeffler, J., H. Hebart, R. Bialek, L. Hagmeyer, D. Schmidt, F. P. Serey, M. Hartmann, J. Eucker, and H. Einsele. 1999. Contaminations occurring in fungal PCR assays. J. Clin. Microbiol. 37:1200–1202. National Committee for Clinical Laboratory Standards. 1995. Molecular diagnostic methods for infectious diseases: approved guidelines. NCCLS document MM3-A, vol. 15, no. 22. NCCLS, Wayne, Pa. National Pathology Accreditation Advisory Council. 2000. Laboratory accreditation standards and guidelines for nucleic acid detection techniques. Commonwealth Department of Health and Aged Care, Canberra, Australia. Pryce, T. M., S. Palladino, I. D. Kay, and G. W. Coombs. 2003. Rapid identification of fungi by sequencing the ITS1 and ITS2 regions using an automated capillary electrophoresis system. Med. Mycol. 41:369–381. Schaenman, J. M., D. B. DiGiulio, L. F. Mirels, N. B. McClenny, G. J. Berry, A. W. Fothergill, M. G. Rinaldi, and J. G. Montoya. 2005. Scedosporium apiospermum soft tissue infection successfully treated with voriconazole: potential pitfalls in the transition from intravenous to oral therapy. J. Clin. Microbiol. 43:973–977.

Daniel B. DiGiulio Joanna M. Schaenman* Jose G. Montoya Division of Infectious Diseases and Geographic Medicine Stanford University School of Medicine Stanford, CA 94305 Nancy B. McClenny Clinical Microbiology Laboratory Stanford University School of Medicine Stanford, CA 94305 Gerald J. Berry Department of Pathology Stanford University School of Medicine Stanford, CA 94305 Laurence F. Mirels Division of Infectious Diseases Santa Clara Valley Medical Center San Jose, CA 95128 Michael G. Rinaldi Annette W. Fothergill Department of Pathology University of Texas Health Science Center at San Antonio San Antonio, TX 78229 *Phone: (650) 725-8338 Fax: (650) 498-7011 E-mail: [email protected]