Finding the Needle in a Microbial Haystack: Penn Researchers Test New Pathogen Detection Technology

Patients who are undergoing treatment for diseases such as cancer often face the added challenge of a compromised immune system, which can be a toll both of their condition and the drugs used to treat it, leaving them vulnerable to various opportunistic infections. Many of these infections are not only life-threatening, but caused by rare organisms that are extremely difficult to isolate and identify. However, the sooner an infection is pinned down, the faster and more effectively it can be treated. After developing a novel investigational technology called PathoChip that can rapidly identify elusive microorganisms, a team of Penn Medicine researchers recently succeeded for the first time in identifying a pathogen in a patient sample, demonstrating the proof of principle that this technology can be used to identify pathogens in human disease.

In a recently published study in Cancer Biology & Therapy, the group of Penn colleagues, led by Erle Robertson, PhD, professor and vice-chair  for research in Otorhinolaryngology at the Perelman School of Medicine, and James Alwine, PhD, a professor of Cancer Biology and Michael Feldman, MD, a professor of Pathology and Laboratory Medicine, used a version of the PathoChip microarray, which contains 60,000 probes for all known viruses, as well as a broad range of bacteria, protozoa, fungi, and helminthes, a parasitic worm, to identify the pathogenic agent in the sample of a patient. They analyzed preserved tissue samples from a middle-aged male with relapsed acute myelogenous leukemia (AML) who developed an unknown fungal infection following chemotherapy.

“We've run many tests to see if we could identify pathogens in the lab, just to see if the PathoChip has efficacy in identifying a variety of organisms, and we were able to identify all infectious agents tested, ”Robertson said. “But this was the first time we actually looked directly at a patient sample to identify a pathogenic agent.”

The PathoChip allows for a single sample to be tested simultaneously for thousands of possibilities, dramatically reducing the time required for diagnosis. They first screened the sample and analyzed it with a type of bioinformatics probe to narrow the focus to a specific microbial family. Seventeen organisms displaying the highest signal were compared with the signals from a control sample. Molecular signals obtained from additional bioinformatics tests provided further information, which led to the identification of the specific infectious agent-- in this case one of the two species of Rhizomucor, a rare fungus known to cause zygomycosis in humans.

A potentially fatal illness most often seen in immunocompromised patients, zygomycosis is not only difficult to treat but challenging to diagnose. Fungal species can be painfully slow or even impossible to culture in the laboratory, delaying or preventing their identification and therefore patient treatment. As Robertson explains, the PathoChip provides an efficient alternative. “With this technology, out of 60,000 possibilities and probes that we used, in a little over 24 hours we were able to identify this particular fungi," he says. 

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