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Probabilistic Learning Coherent Point Drift for 3D Ultrasound Fetal Head Registration

Quantification of brain growth is crucial for the assessment of fetal well being, for which ultrasound (US) images are the chosen clinical modality. However, they present artefacts, such as acoustic occlusion, especially after the 18(th) gestational week, when cranial calcification appears. Fetal US...

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Autores principales: Perez–Gonzalez, Jorge, Arámbula Cosío, Fernando, Huegel, Joel C., Medina-Bañuelos, Verónica
Formato: Online Artículo Texto
Lenguaje:English
Publicado: Hindawi 2020
Materias:
Acceso en línea:https://www.ncbi.nlm.nih.gov/pmc/articles/PMC7013355/
https://www.ncbi.nlm.nih.gov/pubmed/32089729
http://dx.doi.org/10.1155/2020/4271519
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author Perez–Gonzalez, Jorge
Arámbula Cosío, Fernando
Huegel, Joel C.
Medina-Bañuelos, Verónica
author_facet Perez–Gonzalez, Jorge
Arámbula Cosío, Fernando
Huegel, Joel C.
Medina-Bañuelos, Verónica
author_sort Perez–Gonzalez, Jorge
collection PubMed
description Quantification of brain growth is crucial for the assessment of fetal well being, for which ultrasound (US) images are the chosen clinical modality. However, they present artefacts, such as acoustic occlusion, especially after the 18(th) gestational week, when cranial calcification appears. Fetal US volume registration is useful in one or all of the following cases: to monitor the evolution of fetometry indicators, to segment different structures using a fetal brain atlas, and to align and combine multiple fetal brain acquisitions. This paper presents a new approach for automatic registration of real 3D US fetal brain volumes, volumes that contain a considerable degree of occlusion artefacts, noise, and missing data. To achieve this, a novel variant of the coherent point drift method is proposed. This work employs supervised learning to segment and conform a point cloud automatically and to estimate their subsequent weight factors. These factors are obtained by a random forest-based classification and are used to appropriately assign nonuniform membership probability values of a Gaussian mixture model. These characteristics allow for the automatic registration of 3D US fetal brain volumes with occlusions and multiplicative noise, without needing an initial point cloud. Compared to other intensity and geometry-based algorithms, the proposed method achieves an error reduction of 7.4% to 60.7%, with a target registration error of only 6.38 ± 3.24 mm. This makes the herein proposed approach highly suitable for 3D automatic registration of fetal head US volumes, an approach which can be useful to monitor fetal growth, segment several brain structures, or even compound multiple acquisitions taken from different projections.
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spelling pubmed-70133552020-02-23 Probabilistic Learning Coherent Point Drift for 3D Ultrasound Fetal Head Registration Perez–Gonzalez, Jorge Arámbula Cosío, Fernando Huegel, Joel C. Medina-Bañuelos, Verónica Comput Math Methods Med Research Article Quantification of brain growth is crucial for the assessment of fetal well being, for which ultrasound (US) images are the chosen clinical modality. However, they present artefacts, such as acoustic occlusion, especially after the 18(th) gestational week, when cranial calcification appears. Fetal US volume registration is useful in one or all of the following cases: to monitor the evolution of fetometry indicators, to segment different structures using a fetal brain atlas, and to align and combine multiple fetal brain acquisitions. This paper presents a new approach for automatic registration of real 3D US fetal brain volumes, volumes that contain a considerable degree of occlusion artefacts, noise, and missing data. To achieve this, a novel variant of the coherent point drift method is proposed. This work employs supervised learning to segment and conform a point cloud automatically and to estimate their subsequent weight factors. These factors are obtained by a random forest-based classification and are used to appropriately assign nonuniform membership probability values of a Gaussian mixture model. These characteristics allow for the automatic registration of 3D US fetal brain volumes with occlusions and multiplicative noise, without needing an initial point cloud. Compared to other intensity and geometry-based algorithms, the proposed method achieves an error reduction of 7.4% to 60.7%, with a target registration error of only 6.38 ± 3.24 mm. This makes the herein proposed approach highly suitable for 3D automatic registration of fetal head US volumes, an approach which can be useful to monitor fetal growth, segment several brain structures, or even compound multiple acquisitions taken from different projections. Hindawi 2020-01-31 /pmc/articles/PMC7013355/ /pubmed/32089729 http://dx.doi.org/10.1155/2020/4271519 Text en Copyright © 2020 Jorge Perez–Gonzalez et al. http://creativecommons.org/licenses/by/4.0/ This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.
spellingShingle Research Article
Perez–Gonzalez, Jorge
Arámbula Cosío, Fernando
Huegel, Joel C.
Medina-Bañuelos, Verónica
Probabilistic Learning Coherent Point Drift for 3D Ultrasound Fetal Head Registration
title Probabilistic Learning Coherent Point Drift for 3D Ultrasound Fetal Head Registration
title_full Probabilistic Learning Coherent Point Drift for 3D Ultrasound Fetal Head Registration
title_fullStr Probabilistic Learning Coherent Point Drift for 3D Ultrasound Fetal Head Registration
title_full_unstemmed Probabilistic Learning Coherent Point Drift for 3D Ultrasound Fetal Head Registration
title_short Probabilistic Learning Coherent Point Drift for 3D Ultrasound Fetal Head Registration
title_sort probabilistic learning coherent point drift for 3d ultrasound fetal head registration
topic Research Article
url https://www.ncbi.nlm.nih.gov/pmc/articles/PMC7013355/
https://www.ncbi.nlm.nih.gov/pubmed/32089729
http://dx.doi.org/10.1155/2020/4271519
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