Tiny tool can play big role against tuberculosis, UF researcher finds
A tiny filter could have a big impact around the world in the fight against tuberculosis. Using the traditional microscope-based diagnosis method as a starting point, a University of Florida lung disease specialist and colleagues in Brazil have devised a way to detect more cases of the bacterial infection.
“We’re hopeful that this more sensitive method, which is both simple and inexpensive, will improve diagnosis in patients,” said lead researcher Kevin Fennelly, M.D., M.P.H., an associate professor in the UF College of Medicine’s department of medicine and Southeastern Tuberculosis Center, and the UF Emerging Pathogens Institute.
The new technique, which involves vacuum filtering a sputum sample treated with household bleach and other simple chemicals through a small filter, could dramatically improve TB diagnoses globally, particularly in settings where the disease is common and resources are limited. It is especially useful when the presence of only a small number of bacteria in the test sample makes it hard to detect TB. The researchers are refining the technique in hopes of developing a cost-effective product that can be used globally.
Funded by the World Health Organization and the Núcleo de Doenças Infecciosas infectious disease institute in Brazil, the study appears online and in an upcoming print edition of the Journal of Clinical Microbiology.
TB is a treatable disease caused by a microbe called Mycobacterium tuberculosis. It most often affects the lungs, but can also target organs such as the brain, spine and kidneys. Symptoms of active disease include a chronic cough, sputum production and coughing up blood. TB spreads from person to person through the air.
Once the leading cause of death in the U.S., TB has been largely under control in Western nations. Still, more than 11,000 U.S. cases were reported in 2010, the latest year for which there is comprehensive data. That year, almost 9 million people around the world were diagnosed with TB and almost 1.5 million died from it. TB causes more deaths than any other bacterial infection and is the most common killer of people living with HIV.
“TB is still a tremendously important disease worldwide and control efforts are greatly hindered by lack ofsimple, inexpensive diagnostics that could be used at the point of care,” said Elizabeth Talbot, M.D., a Dartmouth College infectious diseases and TB diagnostics expert who was not involved in the UF research. “What Dr. Fennelly has done is capitalize on existing infrastructure of microscopy to try to improve performance of that prevalent diagnostic tool.”
The most widely used way to confirm TB infection is to use a microscope to identify and count disease-causing bacteria in sputum smeared onto a glass slide. This so-called direct-smear method also helps health professionals figure out how likely people are to pass on the disease, what treatment decisions should be made, and how well patients are responding to treatment. Although the method has been in continuous use for more than a century, it can be unreliable, catching cases only about half of the time, on average.
Part of the problem is that sometimes sputum samples don’t contain many bacteria, making it hard to detect TB. Concentrating bacteria onto a small area could help improve detection accuracy, and although previous efforts have led to improvements, they tend to require expensive equipment or technical know-how. In some cases, gains were offset by loss of sample or safety concerns. So the quest for a low-cost, simple, effective method led back to the trusty microscope.
In the early 1980s researchers vacuum-filtered sputum samples to trap TB bacteria onto quarter-sized filters that were then viewed under a microscope. But the filters hung over the sides of standard microscope slides, posing a health hazard and preventing proper inspection. So Fennelly and his team decided to try smaller-than-a-dime filters that fit neatly onto microscope slides and that concentrated the bacteria even more.
Among 314 patients in Brazil suspected as having TB, but not yet in treatment, the small-filter method detected 89 percent of cases, compared with 60 percent detection when samples were concentrated by the currently used method of rapid spinning, and 56 percent detection when sputum smears were looked at directly under the microscope. Furthermore, the small-filter method identified almost three-quarters of TB-positive cases that had been incorrectly reported as negative based on the traditional technique.
Fennelly and collaborators are now teaming with the humanitarian organization Médecins Sans Frontières, translated as “Doctors Without Borders,” to test the method in western Uganda, where many people have both TB and HIV. They’re comparing it again with the traditional direct-smear method and with a sophisticated DNA-based test that can also detect whether bacteria are drug resistant.
Both types of technique have their place — high-tech tools would be most feasible in referral centers, but on the front lines, the small-filter microscope method can perform an invaluable service, the researchers say.
“A point-of-care dipstick that can say yes or no is the Holy Grail, but we’re a long way from there,” Fennelly said. “‘Microscope’ has become a dirty word in the TB diagnostics world — but almost every clinical laboratory in the world has one.”