Your search keyword '"Szwargulski, Patryk"' showing total 4 results

1. Fat quantification in dual-layer detector spectral CT: How to handle iron overload, varying tube voltage and radiation dose Indices

Author

Molwitz, Isabel, primary, Campbell, Graeme Michael, additional, Knopp, Tobias, additional, Schubert, Niklas, additional, Erley, Jennifer, additional, Löser, Anastassia, additional, Adam, Gerhard, additional, Yamamura, Jin, additional, Fischer, Roland, additional, Ozga, Ann-Kathrin, additional, and Szwargulski, Patryk, additional

Published

2024

2. Fat quantification in dual-layer detector spectral CT: how to handle iron overload, varying tube voltage and radiation dose Indices

Author

Molwitz, Isabel, Campbell, Graeme Michael, Knopp, Tobias, Schubert, Niklas, Erley, Jennifer, Löser, Anastassia, Adam, Gerhard, Yamamura, Jin, Fischer, Roland F., Ozga, Ann-Kathrin, Szwargulski, Patryk, Molwitz, Isabel, Campbell, Graeme Michael, Knopp, Tobias, Schubert, Niklas, Erley, Jennifer, Löser, Anastassia, Adam, Gerhard, Yamamura, Jin, Fischer, Roland F., Ozga, Ann-Kathrin, and Szwargulski, Patryk

Abstract

Objectives Opposed to other spectral CT techniques, fat quantification in dual-layer detector CT (dlCT) has only recently been developed. The impact of concomitant iron overload and dlCT-specific protocol settings such as the dose right index (DRI), a measure of image noise and tube current, on dlCT fat quantification was unclear. Further, spectral information became newly available <120 kV. Therefore, this study's objective was to evaluate the impact of iron, changing tube voltage, and DRI on dlCT fat quantification. Material and methods Phantoms with 0 and 8mg/cm3 iron; 0 and 5mg/cm3 iodine; 0, 10, 20, 35, 50, and 100% fat and liver equivalent, respectively, were scanned with a dlCT (CT7500, Philips, the Netherlands) at 100kV/20DRI, 120kV/20DRI, 140kV/20DRI, and at 120kV/16DRI, 120kV/24DRI. Material decomposition was done for fat, liver, and iodine (A1); for fat, liver, and iron (A2); and for fat, liver, and combined reference values of iodine and iron (A3). All scans were analyzed with reference values from 120kV/20DRI. For statistics, the intraclass correlation coefficient (ICC) and Bland-Altman analyses were used. Results In phantoms with iron and iodine, results were best for A3 with a mean deviation to phantom fat of 1.3±2.6% (ICC 0.999 [95%-confidence interval 0.996-1]). The standard approach A1 yielded a deviation of -2.5±3.0% (0.998[0.994-0.999]), A2 of 6.1±4.8% (0.991[0.974-0.997]). With A3 and changing tube voltage, the maximal difference between quantified fat and the phantom ground truth occurred at 100kV with 4.6±2.1%. Differences between scans were largest between 100kV and 140kV (2.0%[-7.1-11.2]). The maximal difference of changing DRI occurred between 16 and 24 DRI with 0.4%[-2.2-3.0]. Conclusion For dlCT fat quantification in the presence of iron, material decomposition with combined reference values for iodine and iron delivers the most accurate results. Tube voltage-specific calibration of reference values is advisable while the impact of the DR

Published

2024

3. Real-time multi-contrast magnetic particle imaging for the detection of gastrointestinal bleeding

Author

Mohn, Fabian, Szwargulski, Patryk, Kaul, Michael, Graeser, Matthias, Mummert, Tobias, Krishnan, Kannan M., Knopp, Tobias, Adam, Gerhard, Salamon, Johannes, Riedel, Christoph, Mohn, Fabian, Szwargulski, Patryk, Kaul, Michael, Graeser, Matthias, Mummert, Tobias, Krishnan, Kannan M., Knopp, Tobias, Adam, Gerhard, Salamon, Johannes, and Riedel, Christoph

Abstract

Gastrointestinal bleeding, as a potentially life-threatening condition, is typically diagnosed by radiation-based imaging modalities like computed tomography or more invasively catheter-based angiography. Endoscopy enables examination of the upper gastrointestinal tract and the colon but not of the entire small bowel. Magnetic Particle Imaging (MPI) enables non-invasive, volumetric imaging without ionizing radiation. The aim of this study was to evaluate the feasibility of detecting gastrointestinal bleeding by single- and multi-contrast MPI using human-sized organs. A 3D-printed small bowel phantom and porcine small bowel specimens were prepared with a defect within the bowel wall as the source of a bleeding. For multi-contrast MPI, the bowel lumen was filled with an intestinal tracer representing an orally administered tracer. MPI was performed to evaluate the fluid exchange between the vascular compartment of the bowel wall and the lumen while a blood pool tracer was applied. Leakage of the blood pool tracer was observed to the bowel lumen. Multi-contrast MPI enabled co-registration of both tracers at the same location within the bowel lumen indicating gastrointestinal bleeding. Single- and multi-contrast MPI are feasible to visualize gastrointestinal bleeding. Therefore, MPI might emerge as a useful tool for radiation-free detection of bleeding within the entire gastrointestinal tract.

Published

2024

4. In vitro detection of gastrointestinal bleeding using single- and multi-contrast MPI

Author

Mohn, Fabian, Szwargulski, Patryk, Kaul, Michael Gerhard, Gräser, Matthias, Mummert, Tobias, Krishnan, Kannan M., Knopp, Tobias, Adam, Gerhard, Salamon, Johannes, Riedel, Christoph, Mohn, Fabian, Szwargulski, Patryk, Kaul, Michael Gerhard, Gräser, Matthias, Mummert, Tobias, Krishnan, Kannan M., Knopp, Tobias, Adam, Gerhard, Salamon, Johannes, and Riedel, Christoph

Abstract

Gastrointestinal (GI) bleeding is a potentially life-threatening condition that is typically diagnosed using radiation-based imaging modalities such as computed tomography (CT) or catheter-based angiography. Magnetic Particle Imaging (MPI) could provide non-invasive, real-time volumetric imaging without ionizing radiation in future human-sized scanners that covers the entire GI tract. We have developed a human-sized (3D printed) phantom that represents both the bowel lumen and the vascular compartment of the bowel wall. One version has a perforation between the two compartments and a control phantom does not. For single contrast MPI, we evaluate the fluid exchange between the two lumen by observing an administered blood pool tracer. For multi-contrast MPI, the intestinal lumen was filled with an intestinal tracer, which represents an orally administered tracer, to allow co-registration of both tracers at the same location. Both single-and multi-contrast MPI are feasible to visualize GI bleeding and MPI may prove to be a useful tool for radiation-free detection of bleeding throughout the GI tract.

Published

2024