Scientists have developed a matchbox-sized device that can test for the presence of bacteria in a couple of minutes, instead of up to several weeks.
The device can be used to determine if a bacteria has been effectively treated by an antibiotic, a crucial medical tool especially for resistant strains. It could also prove useful for testing chemotherapy treatment, researchers believe.
It works by a nano-lever that vibrates in the presence of bacterial activity, while a laser reads the vibration and translates it into an electrical signal that can be easily read - the absence of a signal signifies the absence of bacteria.
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It currently takes a long time to measure a bacterial infection's response to antibiotic treatment. Clinicians must culture the bacteria and then observe its growth, sometimes for almost a month, as is the case with tuberculosis, in order to determine if the treatment has been effective.
EPFL researchers exploited the microscopic movements of a bacterium's metabolism. These vital signs are almost unperceivable. In order to test for them, the researchers place the bacteria on an extremely sensitive measuring device that vibrates a small lever - only slightly thicker than a strand of hair - in the presence of certain activity.
The lever then vibrates under the metabolic activity of the germs. These infinitely small oscillations, on the order of one millionth of a millimetre, determine the presence or absence of the bacteria.
To measure these vibrations, the researchers project a laser onto the lever. The light is then reflected back and the signal is converted into an electrical current to be interpreted by the clinician or researcher.
When the electrical current is a flat line, one knows that the bacteria are all dead; it is as easy to read as an electrocardiogram.
The researchers have miniaturised the tool - it is currently the size of a matchbox.
"By joining our tool with a piezoelectric device instead of a laser, we could further reduce its size to the size of a microchip," said Dietler.
The study was published in the journal of Nature Nanotechnology.