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An AI tool developed at the University of Gothenburg offers new opportunities for analysing images taken with microscopes. A study shows that the tool, which has already received international recognition, can fundamentally change microscopy and pave the way for new discoveries and areas of use within both research and industry.
The focus of the study is deep learning, a type of artificial intelligence (AI) and machine learning that we all interact with daily, often without thinking about it. For example when a new song on Spotify pops up that is similar to songs we have previously listened to or when our mobile phone camera automatically finds the best settings and corrects colours in a photo.
“Deep learning has taken the world by storm and has had a huge impact on many industries, sectors and scientific fields. We have now developed a tool that makes it possible to utilise the incredible potential of deep learning, with focus on images taken with microscopes,” says Benjamin Midtvedt, a doctoral student in physics and the main author of the study.
Deep learning can be described as a mathematical model used to solve problems that are difficult to tackle using traditional algorithmic methods. In microscopy, the great challenge is to retrieve as much information as possible from the data-packed images, and this is where deep learning has proven to be very effective.
The tool that Midtvedt and his research colleagues have developed involves neural networks learning to retrieve exactly the information that a researcher wants from an image by looking through a huge number of images, known as training data. The tool simplifies the process of producing training data compared with having to do so manually, so that tens of thousands of images can be generated in an hour instead of a hundred in a month.
“This makes it possible to quickly extract more details from microscope images without needing to create a complicated analysis with traditional methods. In addition, the results are reproducible, and customised, specific information can be retrieved for a specific purpose.”
For example, the tool allows the user to decide the size and material characteristics for very small particles and to easily count and classify cells. The researchers have already demonstrated that the tool can be used by industries that need to purify their emissions since they can see in real time whether all unwanted particles have been filtered out.
The researchers are hopeful that in the future the tool can be used to follow infections in a cell and map cellular defence mechanisms, which would open up huge possibilities for new medicines and treatments.
“We have already seen major international interest in the tool. Regardless of the microscopic challenges, researchers can now more easily conduct analyses, make new discoveries, implement ideas and break new ground within their fields.”
About the research
The tool is described in the article “Quantitative Digital Microscopy with Deep Learning”, published in Applied Physics Reviews
Another study about the tool has been published in American Chemical Society: “Fast and Accurate Nanoparticle Characterization Using Deep-Learning-Enhanced Off-Axis Holography”
The tool is called Deep Track 2.0 and is freely available.
Contact:
Benjamin Midtvedt, doctoral student in physics at the University of Gothenburg, telephone: +46 (0)730-752304, e-mail: benjamin.midtvedt@physics.gu.se
The tool is described in the article “Quantitative Digital Microscopy with Deep Learning”, published in Applied Physics Reviews
https://aip.scitation.org/doi/10.1063/5.0034891
https://pubs.acs.org/doi/10.1021/acsnano.0c06902
https://expertsvar.se/wp-content/uploads/2021/02/DeepLearning_Aykut-Argun_02-102...
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Mathematics, Physics / astronomy
transregional, national
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