Molecular diagnosis of disseminated adiaspiromycosis due to Emmonsia crescens.

Emmonsia crescens is a saprophytic fungus that is distributed worldwide, causing diseases mostly in rodents. It has also been described, though rarely, as an etiologic agent of pulmonary pathology in humans, potentially leading to death. A case of pulmonary adiaspiromycosis is reported in a 30-year-old immunocompetent man. The patient presented with a history of several weeks of weakness, cough, fever, and weight loss of 10 kg. Clinical and radiographic findings showed pulmonary lesions consistent with tuberculosis or histoplasmosis, but no pathogen was found with classical microbiological procedures. The diagnosis of adiaspiromycosis due to Emmonsia crescens was initially made using molecular biology techniques. Histological observations subsequently confirmed the presence of adiaspores in granulomas. To our knowledge, this is the first case of adiaspiromycosis diagnosed by PCR and sequencing. The patient was treated with itraconazole and was seen at 1 month with symptomatic improvement. Here we will discuss this rare fungal infection and its difficult treatment and diagnosis. As represented in this case, molecular biology is a powerful method to optimize diagnostic tests and therefore improve the care of the infected patient.

Development of a PCR assay followed by nonradioactive hybridization using oligonucleotides covalently bound to CovaLink NH microwells for detection of four Plasmodium species in blood samples from humans.

We developed and evaluated a PCR-based assay to detect four Plasmodium species in 79 blood samples from 56 travelers returning from areas where malaria is endemic. DNA amplification targeting a small region of the 18S rRNA gene was performed with Plasmodium genus-specific primers. The biotinylated PCR products were then identified by PCR-colorimetric Covalink NH microwell plate hybridization (CMPH) using species-specific phosphorylated probes covalently bound to a pretreated polystyrene surface. The results from PCR-CMPH showed high specificity, and for 47 of the 56 patients (84%), microscopy and PCR-CMPH results were in agreement. Discordant results were reevaluated with microscopy examination, other molecular methods, and DNA sequencing. Except for one patient, discrepancies were resolved in favor of PCR-CMPH: three mixed infections were detected, four species identification errors were corrected, and two negative results were shown to be positive. Our results indicate that PCR-CMPH is a simple, rapid, and specific method for malaria diagnosis. It employs stable reagents and inexpensive equipment, making it suitable for routine epidemiological use.