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Advances in micro-computed tomography

TECHNICAL UNIVERSITY OF MUNICH

Corporate Communications Center

phone: +49 89 289 10808 - email: presse@tum.de - web: www.tum.de

This text on the web: https://www.tum.de/en/about-tum/news/press-releases/details/37244

Pictures: https://mediatum.ub.tum.de/1650159

NEWS RELEASE

Advances in micro-computed tomography

Improved imaging for medicine and material sciences

Researchers in biomedical physics and biology have significantly improved micro-computed tomography, more specifically imaging with phase contrast and high brilliance x-ray radiation. They have developed a new microstructured optical grating and combined it with new analytical algorithms. The new approach makes it possible to depict and analyze the microstructures of samples in greater detail, and to investigate a particularly broad spectrum of samples.

Micro-computed tomography (micro-CT) is an imaging method which generates detailed three-dimensional images of the internal structure of samples with small dimensions. Researchers in biology, medicine or material sciences can use this method to obtain information on the structure and characteristics of tissue and material samples which are important in diagnoses and other analyses.

Micro-CT is based on x-ray images which are reconstructed to form a three-dimensional image. Depending on the sample, different x-ray imaging methods are used in order to achieve the most accurate depiction possible. Here the key parameters are resolution, contrast and the sensitivity of the method used.

X-ray imaging with phase contrast

X-ray imaging with phase contrast is particularly well-suited for investigating soft tissue. The method employs the refraction of the x-rays caused by the sample's structures in order to obtain contrast for these structures and thus to depict soft tissue in greater detail than it is possible with conventional x-ray methods.

In many phase-contrast methods, optical components modulate the x-rays on their way to the detector, resulting in what is referred to as a diffraction pattern at the detector. "When comparing this pattern with and without the sample in the x-ray beam, the refraction of the x-rays on the sample provides information about its characteristics," says Julia Herzen, Professor of Biomedical Imaging Physics at the Technical University of Munich (TUM).

Until now inefficient structures such as sandpaper and absorption masks have been used for this type of modulation, but in the meantime a variety of optical gratings are available. "The function of the new optical gratings resembles that of small lenses. The gratings focus the x-rays to form tiny points. This renders the differences in intensity with and without the sample much clearer and makes it possible to visualize even minute differences in the tissue in greater detail," says Prof. Herzen.

High contrast, high resolution and high sensitivity

Physicist Julia Herzen and her team have now introduced a new method for micro-CT with phase contrast using high-brilliance x-ray radiation. The technology is based on a newly developed optical grating referred to as a Talbot Array Illuminator. This new optical element is comparatively easy to produce, is resilient to x-ray radiation and can be used with different energies. This establishes the technically necessary prerequisites for high contrast. The new method enables more efficient use of the radiation dose than with ordinary modulators such as sandpaper and significantly reduces scan times.

"By combining our newly developed Talbot Array Illuminator with new analysis software optimized for the purpose, we've been able to significantly improve imaging and analysis with micro-CT. The new technology is more sensitive than comparable methods in this field. At very high resolutions, it allows to depict soft tissue with higher contrast than previously. High sensitivity is particularly important for example in order to detect fine differences within soft tissue," says Prof. Herzen.

Analysis of a broad spectrum of samples

The new technology can be used to investigate a particularly broad spectrum of samples. Researchers can even simultaneously depict materials of greatly differing compositions, for example water and oil embedded in stone, which was not possible in the past using conventional methods. This provides crucial advantages over conventional methods not only in medicine and biology, but also opens up new application possibilities in material sciences, for example in geology.

Quantitative analysis is possible

"In contrast to previous approaches, our new method also makes quantitative analysis possible. We can make and compare absolute measurements of the electron density of samples, without the need for any assumptions about the samples," explains Prof. Herzen. Further studies will investigate the potential of this new option in a variety of applications.

Publication:

Alex Gustschin, Mirko Riedel, Kirsten Taphorn, Christian Petrich, Wolfgang Gottwald, Wolfgang Noichl, Madleen Busse, Sheila E. Francis, Felix Beckmann, Jörg U. Hammel, Julian Moosmann, Pierre Thibault, and Julia Herzen: High-resolution and sensitivity bi-directional x-ray phase contrast imaging using 2D Talbot array illuminators. Optica 8, 1588-1595 (2021). DOI: https://doi.org/10.1364/OPTICA.441004

More information:

Prof. Dr. Julia Herzen is Principal Investigator at the Munich Institute of Biomedical Engineering (MIBE). MIBE is an Integrative Research Institute (IRI) within the Technical University of Munich (TUM). At MIBE, researchers specializing in medicine, the natural sciences, and engineering join forces to develop new methods for diagnosing or treating diseases. They also work on improving technologies that compensate for physical disabilities. The activities cover the entire development process – from the study of basic scientific principles through to their application in new medical devices, medicines and software. https://www.bioengineering.tum.de/

The study was carried out in collaboration with the Helmholtz-Zentrum Hereon and the Deutsches Elektronen-Synchrotron (DESY), which are both research centres of the Helmholtz Association. Large parts of this research were carried out at PETRA III at DESY. The University of Trieste (Italy) and the University of Sheffield (UK) also participated in the research.

This work was funded by the European Research Council (ERC) under the European Union Horizon 2020 research and innovation program, the British Heart Foundation, and the Deutsche Forschungsgemeinschaft (DFG).

High resolution images:

https://mediatum.ub.tum.de/1650159

Contact:

Prof. Dr. Julia Herzen

Technical University of Munich

Professor of Biomedical Imaging Physics

Phone: +49 (89) 289 10806

julia.herzen@tum.de

https://www.professoren.tum.de/en/herzen-julia

https://www.groups.ph.tum.de/en/bip/home/

The Technical University of Munich (TUM) is one of Europe’s leading research universities, with more than 600 professors, 48,000 students, and 11,000 academic and non-academic staff. Its focus areas are the engineering sciences, natural sciences, life sciences and medicine, combined with economic and social sciences. TUM acts as an entrepreneurial university that promotes talents and creates value for society. In that it profits from having strong partners in science and industry. It is represented worldwide with the TUM Asia campus in Singapore as well as offices in Beijing, Brussels, Mumbai, San Francisco, and São Paulo. Nobel Prize winners and inventors such as Rudolf Diesel, Carl von Linde, and Rudolf Mößbauer have done research at TUM. In 2006, 2012, and 2019 it won recognition as a German "Excellence University." In international rankings, TUM regularly places among the best universities in Germany.

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