"Laser view" into the avocado: new method reveals cell interior
Research team develops method for recognizing cell properties
Checking whether an avocado is hard or soft by looking at it? This would require recognizing how the plant cells behave behind the skin. The same applies to all other cells on our planet: Despite more than 100 years of intensive research, many of their properties remain hidden inside the cell. Researchers at the University of Göttingen describe in their recent publication in Nature Materials a new approach that can determine the particularly difficult-to-detect mechanical properties of the cell interior by taking a closer look.
Precise observation of the fluctuating movement of tiny particles in cells makes it possible to determine whether the inside of the cell is hard, soft or liquid.
AI-generated by Till Moritz Münker
A view into the cell using an optical laser trap: it localizes microscopic particles in order to draw conclusions about their random trembling movement. A new approach developed by the Göttingen researchers makes it possible to deduce from these movements how hard, soft or liquid the inside of the cell is.
Till M. Münker
Cells are the basic units of all life and their precise understanding is a key factor in the progress made in medicine and biology. Nevertheless, research on them is still challenging because many methods destroy the cell during analysis. Researchers at the University of Göttingen now pursued a new idea: they used the random fluctuating movement that all microscopic particles perform. To do this, they first simulated the expected fluctuations and then checked the predictions using optical laser traps that can precisely control microparticles. Using this approach, the research team was able to analyze the movement of microscopic particles – with precision in the nanometer range and a time resolution of around 50 microseconds. In addition, the analysis also takes into account the history, i.e. past movements. It turned out that many objects always want to return to a certain place after having moved away randomly. The researchers used this tendency to return to a previous position to define a new quantify, the so-called mean back relaxation (MBR).
This new variable now serves as a kind of fingerprint: it contains information about the causes of the observed movements. This makes it possible for the first time to distinguish active processes from purely temperature-dependent processes (Brownian motion). "With MBR, we can obtain more information from the object movements than is possible with the usual approaches," explains Professor Matthias Krüger from the Institute of Theoretical Physics at the University of Göttingen.
In order to make statements about living cells, the researchers applied the method to the inside of living cells. "As our knowledge of the inside of cells is still limited, it was initially unclear whether the MBR could also be used here. When I saw the resulting curves, I could hardly believe my eyes, because the inside of cells could be described very precisely using the approaches we had originally worked out for much simpler situations ," marvels Professor Timo Betz from the Third Institute of Physics, head of the experiments.
"The results show that the combination of a close look and new, intelligent analysis methods can provide insights into whether the inside of cells is soft, hard or liquid," says first author of the study, Till Münker from the Third Institute of Physics. The work was co-funded by the European Union as part of an ERC Consolidator Grant.
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Topic World Cell Analysis
Cell analyse advanced method allows us to explore and understand cells in their many facets. From single cell analysis to flow cytometry and imaging technology, cell analysis provides us with valuable insights into the structure, function and interaction of cells. Whether in medicine, biological research or pharmacology, cell analysis is revolutionizing our understanding of disease, development and treatment options.
Topic World Cell Analysis
Cell analyse advanced method allows us to explore and understand cells in their many facets. From single cell analysis to flow cytometry and imaging technology, cell analysis provides us with valuable insights into the structure, function and interaction of cells. Whether in medicine, biological research or pharmacology, cell analysis is revolutionizing our understanding of disease, development and treatment options.
