Antibiotics are used far too frequently all over the world. Bacteria are getting resistant as a result. Curing bacterial infections is becoming increasingly challenging because antibiotics are one of our most powerful tools in the fight against them.
The good news is that finding better ways for identifying infections is a crucial step towards requiring fewer antibiotics. "We have developed a simple tool that can identify all of the genetic material in bacteria. This allows us to find out more quickly what kind of bacteria a sick person or animal is affected by, or what kind of bacteria are found in food or the environment. We can then also decide whether it is necessary to use antibiotics against the bacterium, and if so what kind, so we don't have to use as much medication," says Professor Erika Eiser at Norwegian University of Science and Technology's (NTNU)Department of Physics. An international research group is behind the latest findings. The results have been presented in the prestigious Proceedings of the National Academy of Sciences (PNAS) journal. Playing a key role in the work was Dr Peicheng Xu from the Institute of Physics Chinese Academy of Sciences in Beijing, for whom Eiser was previously an academic supervisor. One reason why the new method is faster is that users do not have to go through a step called 'gene amplification'. This involves making several copies of the genetic material so it is easier to analyse, but this step can now be skipped. "We can analyse all of the bacterium's DNA without gene amplification by using a method previously used in simulations," says Professor Eiser. Eiser was part of a research group led by Tine Curk from Johns Hopkins University that developed the theory behind the method, which also works in reality. "We get excellent results when we apply the theoretical method to real samples," said Professor Eiser. This paragraph might be a bit difficult to understand, but basically, DNA is made up of rows of so-called nucleotides. The new method enables researchers to find short sequences of the bacteria's DNA. They do this by seeing how these sequences bind to different variants of DNA that are grafted onto colloids, which are particles dissolved in a liquid. If you are interested in finding out more, you can read about the process in more detail here. What it means, however, is that researchers can quickly identify the bacteria, because they bind themselves to these colloids in various ways and cause them to clump together. The bottom line is: you don't have to analyse so much material. You can skip the step of having to copy them, and this saves time and money. "Using this method, we saw how as few as five E. coli bacteria caused the colloids to create clusters," said Professor Eiser. All of this is currently in its early stages. Eiser has published a proof-of-principle experiment. This means that there is still a lot of work to be done before it becomes a widely used method. "The findings can provide us with a reliable method for identifying pathogens in disciplines such as food safety, disease control and environmental monitoring," said Professor Eiser. (ANI)
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