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Detecting Bacterial Contamination Using Magneto-fluorescent Nanosensors

Detecting Bacterial Contamination Using Magneto-fluorescent Nanosensors

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In order to prepare solutions for reading in the magnetic relaxometry, 300 microliters of PBS is first pipetted into an eppendorf tube. Then, a sample of bacterial stock is added, followed by the addition of nanosensors. The solution is then transferred to a glass tube, and a piece of parafilm is placed on top in order to prevent evaporation.

The glass tube is then placed inside a larger NMR tube and inserted into the magnetic relaxometer. A baseline solution containing no bacteria and only nanosensor in PBS is used to get a baseline T2 reading as shown. Then, solutions containing various concentrations of bacteria are inserted into the magnetic relaxometer for analysis, and the changes in T2 values are caused by the binding between the nanosensors and the bacteria.

As shown, the presence of as few as one bacterial CFU can be detected within minutes using this modality. However, as the bacterial concentration increases, the MR readings are less quantifiable, which is why the use of fluorescence emission data is also tantamount to an accurate bacterial quantification. Before fluorescence data can be collected, the sample must first be centrifuged.

The solution is transferred from the glass tube to an eppendorf tube, and then centrifuged. This separates the bacteria and the nanosensors bound to it from free-floating nanosensors in solution. The supernatant is discarded and the bacterial pellet is resuspended in PBS. Finally, the sample may be analyzed via fluorescence emission. The strength of the emission will be relative to the amount of nanosensors remaining in solution, and therefore, also to the amount of bacteria present.

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