Virtual monochromatic spectral imaging versus linearly blended dual-energy and single-energy imaging during CT-guided biopsy needle positioning: Optimization of keV settings and impact on image quality

OBJECTIVES: To compare image quality and metal artifact reduction between virtual monochromatic spectral imaging (VMSI), linearly blended dual-energy (DE) and single-energy (SE) images, each with and without dedicated iterative metal artifact reduction (iMAR) for CT-guided biopsy. MATERIALS AND METH...

Descripción completa

Detalles Bibliográficos
Autores principales: Do, T. D., Heim, J., Melzig, C., Vollherbst, D. F., Kauczor, H. U., Skornitzke, S., Sommer, C. M.
Formato: Online Artículo Texto
Lenguaje:English
Publicado: Public Library of Science 2020
Materias:
Research Article
Acceso en línea:https://www.ncbi.nlm.nih.gov/pmc/articles/PMC7010258/
https://www.ncbi.nlm.nih.gov/pubmed/32040496
http://dx.doi.org/10.1371/journal.pone.0228578
_version_ 1783495848242446336
author Do, T. D.
Heim, J.
Melzig, C.
Vollherbst, D. F.
Kauczor, H. U.
Skornitzke, S.
Sommer, C. M.
author_facet Do, T. D.
Heim, J.
Melzig, C.
Vollherbst, D. F.
Kauczor, H. U.
Skornitzke, S.
Sommer, C. M.
author_sort Do, T. D.
collection PubMed
description OBJECTIVES: To compare image quality and metal artifact reduction between virtual monochromatic spectral imaging (VMSI), linearly blended dual-energy (DE) and single-energy (SE) images, each with and without dedicated iterative metal artifact reduction (iMAR) for CT-guided biopsy. MATERIALS AND METHODS: A biopsy trocar was positioned in the liver of six pigs. DE (Sn140/100kV(p)) and SE (120kV(p)/200mAs) acquisitions were performed with equivalent dose. From dual-energy datasets DE Q30-3 images and VMSI between 40–180 keV in steps of 20 keV were generated. From SE datasets I30-3 images were reconstructed. All images were reconstructed with and without iMAR. Objective image quality was analyzed applying density measurements at standardized positions (e.g. trocar tip and liver parenchyma adjacent to the trocar tip) and semi-automated threshold based segmentation. Subjective image quality was performed using semi-quantitative scores. Analyses were performed by two observers. RESULTS: At the trocar tip quantitative image analysis revealed significant difference in CT numbers between reconstructions with iMAR compared to reconstructions without iMAR for VMSI at lower keV levels (80 and 100 keV; p = 0.03) and DE (p = 0.03). For liver parenchyma CT numbers were significantly higher in VMSI at high keV compared to low keV (p≤0.01). VMSI at high keV also showed higher CT numbers compared to DE and SE images, though not the level of statistical significance. The best signal-to-noise ratio for VMSI was at 80 keV and comparable to DE and SE. Noise was lowest at 80 keV and lower than in DE and SE. Subjective image quality was best with VMSI at 80 keV regardless of the application of iMAR. iMAR significantly improved image quality at levels of 140 keV and 160 keV. Interreader-agreement was good for quantitative and qualitative analysis. CONCLUSION: iMAR improved image quality in all settings. VMSI with iMAR provided metal artifact reduction and better image quality at 80 keV and thus could improve the accurate positioning in CT-guided needle biopsy. In comparison, DE imaging did not improve image quality compared to SE.
format Online
Article
Text
id pubmed-7010258
institution National Center for Biotechnology Information
language English
publishDate 2020
publisher Public Library of Science
record_format MEDLINE/PubMed
spelling pubmed-70102582020-02-21 Virtual monochromatic spectral imaging versus linearly blended dual-energy and single-energy imaging during CT-guided biopsy needle positioning: Optimization of keV settings and impact on image quality Do, T. D. Heim, J. Melzig, C. Vollherbst, D. F. Kauczor, H. U. Skornitzke, S. Sommer, C. M. PLoS One Research Article OBJECTIVES: To compare image quality and metal artifact reduction between virtual monochromatic spectral imaging (VMSI), linearly blended dual-energy (DE) and single-energy (SE) images, each with and without dedicated iterative metal artifact reduction (iMAR) for CT-guided biopsy. MATERIALS AND METHODS: A biopsy trocar was positioned in the liver of six pigs. DE (Sn140/100kV(p)) and SE (120kV(p)/200mAs) acquisitions were performed with equivalent dose. From dual-energy datasets DE Q30-3 images and VMSI between 40–180 keV in steps of 20 keV were generated. From SE datasets I30-3 images were reconstructed. All images were reconstructed with and without iMAR. Objective image quality was analyzed applying density measurements at standardized positions (e.g. trocar tip and liver parenchyma adjacent to the trocar tip) and semi-automated threshold based segmentation. Subjective image quality was performed using semi-quantitative scores. Analyses were performed by two observers. RESULTS: At the trocar tip quantitative image analysis revealed significant difference in CT numbers between reconstructions with iMAR compared to reconstructions without iMAR for VMSI at lower keV levels (80 and 100 keV; p = 0.03) and DE (p = 0.03). For liver parenchyma CT numbers were significantly higher in VMSI at high keV compared to low keV (p≤0.01). VMSI at high keV also showed higher CT numbers compared to DE and SE images, though not the level of statistical significance. The best signal-to-noise ratio for VMSI was at 80 keV and comparable to DE and SE. Noise was lowest at 80 keV and lower than in DE and SE. Subjective image quality was best with VMSI at 80 keV regardless of the application of iMAR. iMAR significantly improved image quality at levels of 140 keV and 160 keV. Interreader-agreement was good for quantitative and qualitative analysis. CONCLUSION: iMAR improved image quality in all settings. VMSI with iMAR provided metal artifact reduction and better image quality at 80 keV and thus could improve the accurate positioning in CT-guided needle biopsy. In comparison, DE imaging did not improve image quality compared to SE. Public Library of Science 2020-02-10 /pmc/articles/PMC7010258/ /pubmed/32040496 http://dx.doi.org/10.1371/journal.pone.0228578 Text en © 2020 Do et al http://creativecommons.org/licenses/by/4.0/ This is an open access article distributed under the terms of the Creative Commons Attribution License (http://creativecommons.org/licenses/by/4.0/) , which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
spellingShingle Research Article
Do, T. D.
Heim, J.
Melzig, C.
Vollherbst, D. F.
Kauczor, H. U.
Skornitzke, S.
Sommer, C. M.
Virtual monochromatic spectral imaging versus linearly blended dual-energy and single-energy imaging during CT-guided biopsy needle positioning: Optimization of keV settings and impact on image quality
title Virtual monochromatic spectral imaging versus linearly blended dual-energy and single-energy imaging during CT-guided biopsy needle positioning: Optimization of keV settings and impact on image quality
title_full Virtual monochromatic spectral imaging versus linearly blended dual-energy and single-energy imaging during CT-guided biopsy needle positioning: Optimization of keV settings and impact on image quality
title_fullStr Virtual monochromatic spectral imaging versus linearly blended dual-energy and single-energy imaging during CT-guided biopsy needle positioning: Optimization of keV settings and impact on image quality
title_full_unstemmed Virtual monochromatic spectral imaging versus linearly blended dual-energy and single-energy imaging during CT-guided biopsy needle positioning: Optimization of keV settings and impact on image quality
title_short Virtual monochromatic spectral imaging versus linearly blended dual-energy and single-energy imaging during CT-guided biopsy needle positioning: Optimization of keV settings and impact on image quality
title_sort virtual monochromatic spectral imaging versus linearly blended dual-energy and single-energy imaging during ct-guided biopsy needle positioning: optimization of kev settings and impact on image quality
topic Research Article
url https://www.ncbi.nlm.nih.gov/pmc/articles/PMC7010258/
https://www.ncbi.nlm.nih.gov/pubmed/32040496
http://dx.doi.org/10.1371/journal.pone.0228578
work_keys_str_mv AT dotd virtualmonochromaticspectralimagingversuslinearlyblendeddualenergyandsingleenergyimagingduringctguidedbiopsyneedlepositioningoptimizationofkevsettingsandimpactonimagequality
AT heimj virtualmonochromaticspectralimagingversuslinearlyblendeddualenergyandsingleenergyimagingduringctguidedbiopsyneedlepositioningoptimizationofkevsettingsandimpactonimagequality
AT melzigc virtualmonochromaticspectralimagingversuslinearlyblendeddualenergyandsingleenergyimagingduringctguidedbiopsyneedlepositioningoptimizationofkevsettingsandimpactonimagequality
AT vollherbstdf virtualmonochromaticspectralimagingversuslinearlyblendeddualenergyandsingleenergyimagingduringctguidedbiopsyneedlepositioningoptimizationofkevsettingsandimpactonimagequality
AT kauczorhu virtualmonochromaticspectralimagingversuslinearlyblendeddualenergyandsingleenergyimagingduringctguidedbiopsyneedlepositioningoptimizationofkevsettingsandimpactonimagequality
AT skornitzkes virtualmonochromaticspectralimagingversuslinearlyblendeddualenergyandsingleenergyimagingduringctguidedbiopsyneedlepositioningoptimizationofkevsettingsandimpactonimagequality
AT sommercm virtualmonochromaticspectralimagingversuslinearlyblendeddualenergyandsingleenergyimagingduringctguidedbiopsyneedlepositioningoptimizationofkevsettingsandimpactonimagequality

Ejemplares similares