Heidelberg-mCT-Analyzer: a novel method for standardized microcomputed-tomography-guided evaluation of scaffold properties in bone and tissue research

Heidelberg-mCT-Analyzer: a novel method for standardized microcomputed-tomography-guided evaluation of scaffold properties in bone and tissue research

Bone tissue engineering and bone scaffold development represent two challenging fields in orthopaedic research. Micro-computed tomography (mCT) allows non-invasive measurement of these scaffolds’ properties in vivo. However, the lack of standardized mCT analysis protocols and, therefore, the protoco...

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Main Authors: Fabian Westhauser, Christian Weis, Melanie Hoellig, Tyler Swing, Gerhard Schmidmaier, Marc-André Weber, Wolfram Stiller, Hans-Ulrich Kauczor, Arash Moghaddam
Format: Article
Language:English
Published: The Royal Society 2015-01-01
Series:Royal Society Open Science
Subjects:
bone scaffold
bone tissue engineering
micro-computed tomography
scaffold characterization
bmp-7 (bone morphogenetic protein-7)
human mesenchymal stem cells
Online Access:https://royalsocietypublishing.org/doi/pdf/10.1098/rsos.150496
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spelling doaj-7c80935c2da14134a53d32a8d362b5872020-11-25T03:08:41ZengThe Royal SocietyRoyal Society Open Science2054-57032015-01-0121110.1098/rsos.150496150496Heidelberg-mCT-Analyzer: a novel method for standardized microcomputed-tomography-guided evaluation of scaffold properties in bone and tissue researchFabian WesthauserChristian WeisMelanie HoelligTyler SwingGerhard SchmidmaierMarc-André WeberWolfram StillerHans-Ulrich KauczorArash MoghaddamBone tissue engineering and bone scaffold development represent two challenging fields in orthopaedic research. Micro-computed tomography (mCT) allows non-invasive measurement of these scaffolds’ properties in vivo. However, the lack of standardized mCT analysis protocols and, therefore, the protocols’ user-dependency make interpretation of the reported results difficult. To overcome these issues in scaffold research, we introduce the Heidelberg-mCT-Analyzer. For evaluation of our technique, we built 10 bone-inducing scaffolds, which underwent mCT acquisition before ectopic implantation (T0) in mice, and at explantation eight weeks thereafter (T1). The scaffolds’ three-dimensional reconstructions were automatically segmented using fuzzy clustering with fully automatic level-setting. The scaffold itself and its pores were then evaluated for T0 and T1. Analysing the scaffolds’ characteristic parameter set with our quantification method showed bone formation over time. We were able to demonstrate that our algorithm obtained the same results for basic scaffold parameters (e.g. scaffold volume, pore number and pore volume) as other established analysis methods. Furthermore, our algorithm was able to analyse more complex parameters, such as pore size range, tissue mineral density and scaffold surface. Our imaging and post-processing strategy enables standardized and user-independent analysis of scaffold properties, and therefore is able to improve the quantitative evaluations of scaffold-associated bone tissue-engineering projects.https://royalsocietypublishing.org/doi/pdf/10.1098/rsos.150496bone scaffoldbone tissue engineeringmicro-computed tomographyscaffold characterizationbmp-7 (bone morphogenetic protein-7)human mesenchymal stem cells
collection DOAJ
language English
format Article
sources DOAJ
author Fabian Westhauser
Christian Weis
Melanie Hoellig
Tyler Swing
Gerhard Schmidmaier
Marc-André Weber
Wolfram Stiller
Hans-Ulrich Kauczor
Arash Moghaddam
spellingShingle Fabian Westhauser
Christian Weis
Melanie Hoellig
Tyler Swing
Gerhard Schmidmaier
Marc-André Weber
Wolfram Stiller
Hans-Ulrich Kauczor
Arash Moghaddam
Heidelberg-mCT-Analyzer: a novel method for standardized microcomputed-tomography-guided evaluation of scaffold properties in bone and tissue research
Royal Society Open Science
bone scaffold
bone tissue engineering
micro-computed tomography
scaffold characterization
bmp-7 (bone morphogenetic protein-7)
human mesenchymal stem cells
author_facet Fabian Westhauser
Christian Weis
Melanie Hoellig
Tyler Swing
Gerhard Schmidmaier
Marc-André Weber
Wolfram Stiller
Hans-Ulrich Kauczor
Arash Moghaddam
author_sort Fabian Westhauser
title Heidelberg-mCT-Analyzer: a novel method for standardized microcomputed-tomography-guided evaluation of scaffold properties in bone and tissue research
title_short Heidelberg-mCT-Analyzer: a novel method for standardized microcomputed-tomography-guided evaluation of scaffold properties in bone and tissue research
title_full Heidelberg-mCT-Analyzer: a novel method for standardized microcomputed-tomography-guided evaluation of scaffold properties in bone and tissue research
title_fullStr Heidelberg-mCT-Analyzer: a novel method for standardized microcomputed-tomography-guided evaluation of scaffold properties in bone and tissue research
title_full_unstemmed Heidelberg-mCT-Analyzer: a novel method for standardized microcomputed-tomography-guided evaluation of scaffold properties in bone and tissue research
title_sort heidelberg-mct-analyzer: a novel method for standardized microcomputed-tomography-guided evaluation of scaffold properties in bone and tissue research
publisher The Royal Society
series Royal Society Open Science
issn 2054-5703
publishDate 2015-01-01
description Bone tissue engineering and bone scaffold development represent two challenging fields in orthopaedic research. Micro-computed tomography (mCT) allows non-invasive measurement of these scaffolds’ properties in vivo. However, the lack of standardized mCT analysis protocols and, therefore, the protocols’ user-dependency make interpretation of the reported results difficult. To overcome these issues in scaffold research, we introduce the Heidelberg-mCT-Analyzer. For evaluation of our technique, we built 10 bone-inducing scaffolds, which underwent mCT acquisition before ectopic implantation (T0) in mice, and at explantation eight weeks thereafter (T1). The scaffolds’ three-dimensional reconstructions were automatically segmented using fuzzy clustering with fully automatic level-setting. The scaffold itself and its pores were then evaluated for T0 and T1. Analysing the scaffolds’ characteristic parameter set with our quantification method showed bone formation over time. We were able to demonstrate that our algorithm obtained the same results for basic scaffold parameters (e.g. scaffold volume, pore number and pore volume) as other established analysis methods. Furthermore, our algorithm was able to analyse more complex parameters, such as pore size range, tissue mineral density and scaffold surface. Our imaging and post-processing strategy enables standardized and user-independent analysis of scaffold properties, and therefore is able to improve the quantitative evaluations of scaffold-associated bone tissue-engineering projects.
topic bone scaffold
bone tissue engineering
micro-computed tomography
scaffold characterization
bmp-7 (bone morphogenetic protein-7)
human mesenchymal stem cells
url https://royalsocietypublishing.org/doi/pdf/10.1098/rsos.150496
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