Five Material Tissue Decomposition by Dual Energy Computed Tomography

Overview

Journal Sci Rep

Specialty Science

Date 2022 Oct 12

PMID 36224229

Authors

Maximilian E Lochschmidt

Melina Gassenhuber

Isabelle Riederer

Johannes Hammel

Lorenz Birnbacher

Madleen Busse

Tobias Boeckh-Behrens

Benno Ikenberg

Silke Wunderlich

Friederike Liesche-Starnecker

Jurgen Schlegel

Marcus R Makowski

Claus Zimmer

Franz Pfeiffer

Daniela Pfeiffer

Affiliations

Soon will be listed here.

Abstract

The separation of mixtures of substances into their individual components plays an important role in many areas of science. In medical imaging, one method is the established analysis using dual-energy computed tomography. However, when analyzing mixtures consisting of more than three individual basis materials, a physical limit is reached that no longer allows this standard analysis. In addition, the X-ray attenuation coefficients of chemically complicated basis materials may not be known and also cannot be determined by other or previous analyses. To address these issues, we developed a novel theoretical approach and algorithm and tested it on samples prepared in the laboratory as well as on ex-vivo medical samples. This method allowed both five-material decomposition and determination or optimization of the X-ray attenuation coefficients of the sample base materials via optimizations of objective functions. After implementation, this new multimodal method was successfully tested on self-mixed samples consisting of the aqueous base solutions iomeprol, eosin Y disodiumsalt, sodium chloride, and pure water. As a first proof of concept of this technique for detailed material decomposition in medicine we analyzed exact percentage composition of ex vivo clots from patients with acute ischemic stroke, using histological analysis as a reference standard.

Citing Articles

Multimaterial decomposition in dual-energy CT for characterization of clots from acute ischemic stroke patients.

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