AI Article Synopsis
- Traditional tomographic imaging involves a static, sequential process where an expert analyzes data after it has been collected, limiting their influence on acquisition parameters and potentially leading to constrained conclusions.
- The proposed dynamic imaging process allows for real-time adjustments and expert input throughout the acquisition and reconstruction stages, enhancing the quality and relevance of the data collected.
- By showcasing applications from the FleX-ray Laboratory, the paper illustrates how a flexible approach to imaging facilitates a more exploratory research process, yielding unexpected insights and enhancing the overall research experience.
Article Abstract
In tomographic imaging, the traditional process consists of an expert and an operator collecting data, the expert working on the reconstructed slices and drawing conclusions. The quality of reconstructions depends heavily on the quality of the collected data, except that, in the traditional process of imaging, the expert has very little influence over the acquisition parameters, experimental plan or the collected data. It is often the case that the expert has to draw limited conclusions from the reconstructions, or adapt a research question to data available. This method of imaging is static and sequential, and limits the potential of tomography as a research tool. In this paper, we propose a more dynamic process of imaging where experiments are tailored around a sample or the research question; intermediate reconstructions and analysis are available almost instantaneously, and expert has input at any stage of the process (including during acquisition) to improve acquisition or image reconstruction. Through various applications of 2D, 3D and dynamic 3D imaging at the FleX-ray Laboratory, we present the unexpected journey of exploration a research question undergoes, and the surprising benefits it yields.
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| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC8321014 | PMC |
| http://dx.doi.org/10.3390/jimaging6040018 | DOI Listing |
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Article Synopsis
- Traditional tomographic imaging involves a static, sequential process where an expert analyzes data after it has been collected, limiting their influence on acquisition parameters and potentially leading to constrained conclusions.
- The proposed dynamic imaging process allows for real-time adjustments and expert input throughout the acquisition and reconstruction stages, enhancing the quality and relevance of the data collected.
- By showcasing applications from the FleX-ray Laboratory, the paper illustrates how a flexible approach to imaging facilitates a more exploratory research process, yielding unexpected insights and enhancing the overall research experience.
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