A hybrid segmentation method for partitioning the liver based on 4D DCE-MR images

Tian Zhang; Zhiyi Wu; Jurgen H. Runge; Cristina Lavini; Jaap Stoker; Thomas van Gulik; Kasia P. Cieslak; Lucas J. van Vliet; Frans M. Vos

doi:https://doi.org/10.1117/12.2293530

A hybrid segmentation method for partitioning the liver based on 4D DCE-MR images

Tian Zhang, Zhiyi Wu, Jurgen H. Runge, Cristina Lavini, Jaap Stoker, Thomas van Gulik, Kasia P. Cieslak, Lucas J. van Vliet, Frans M. Vos

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › Academic › peer-review

3 Citations (Scopus)

Abstract

The Couinaud classification of hepatic anatomy partitions the liver into eight functionally independent segments. Detection and segmentation of the hepatic vein (HV), portal vein (PV) and inferior vena cava (IVC) plays an important role in the subsequent delineation of the liver segments. To facilitate pharmacokinetic modeling of the liver based on the same data, a 4D DCE-MR scan protocol was selected. This yields images with high temporal resolution but low spatial resolution. Since the liver's vasculature consists of many tiny branches, segmentation of these images is challenging. The proposed framework starts with registration of the 4D DCE-MRI series followed by region growing from manually annotated seeds in the main branches of key blood vessels in the liver. It calculates the Pearson correlation between the time intensity curves (TICs) of a seed and all voxels. A maximum correlation map for each vessel is obtained by combining the correlation maps for all branches of the same vessel through a maximum selection per voxel. The maximum correlation map is incorporated in a level set scheme to individually delineate the main vessels. Subsequently, the eight liver segments are segmented based on three vertical intersecting planes fit through the three skeleton branches of HV and IVC's center of mass as well as a horizontal plane fit through the skeleton of PV. Our segmentation regarding delineation of the vessels is more accurate than the results of two state-of-the-art techniques on five subjects in terms of the average symmetric surface distance (ASSD) and modified Hausdorff distance (MHD). Furthermore, the proposed liver partitioning achieves large overlap with manual reference segmentations (expressed in Dice Coefficient) in all but a small minority of segments (mean values between 87% and 94% for segments 2-8). The lower mean overlap for segment 1 (72%) is due to the limited spatial resolution of our DCE-MR scan protocol.

Original language	English
Title of host publication	Medical Imaging 2018: Image Processing
Editors	Elsa D. Angelini, Bennett A. Landman
Publisher	SPIE
Volume	10574
ISBN (Electronic)	9781510616370
DOIs	https://doi.org/10.1117/12.2293530
Publication status	Published - 2018
Event	Medical Imaging 2018: Image Processing - Houston, United States Duration: 11 Feb 2018 → 13 Feb 2018

Publication series

Name	Progress in Biomedical Optics and Imaging - Proceedings of SPIE

Conference

Conference	Medical Imaging 2018: Image Processing
Country/Territory	United States
City	Houston
Period	11/02/2018 → 13/02/2018

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https://doi.org/10.1117/12.2293530

Cite this

Zhang, T., Wu, Z., Runge, J. H., Lavini, C., Stoker, J., van Gulik, T., Cieslak, K. P., van Vliet, L. J., & Vos, F. M. (2018). A hybrid segmentation method for partitioning the liver based on 4D DCE-MR images. In E. D. Angelini, & B. A. Landman (Eds.), Medical Imaging 2018: Image Processing (Vol. 10574). Article 1057434 (Progress in Biomedical Optics and Imaging - Proceedings of SPIE). SPIE. https://doi.org/10.1117/12.2293530

@inproceedings{77879a2aaca64a8b8bd138a0cc600467,

title = "A hybrid segmentation method for partitioning the liver based on 4D DCE-MR images",

abstract = "The Couinaud classification of hepatic anatomy partitions the liver into eight functionally independent segments. Detection and segmentation of the hepatic vein (HV), portal vein (PV) and inferior vena cava (IVC) plays an important role in the subsequent delineation of the liver segments. To facilitate pharmacokinetic modeling of the liver based on the same data, a 4D DCE-MR scan protocol was selected. This yields images with high temporal resolution but low spatial resolution. Since the liver's vasculature consists of many tiny branches, segmentation of these images is challenging. The proposed framework starts with registration of the 4D DCE-MRI series followed by region growing from manually annotated seeds in the main branches of key blood vessels in the liver. It calculates the Pearson correlation between the time intensity curves (TICs) of a seed and all voxels. A maximum correlation map for each vessel is obtained by combining the correlation maps for all branches of the same vessel through a maximum selection per voxel. The maximum correlation map is incorporated in a level set scheme to individually delineate the main vessels. Subsequently, the eight liver segments are segmented based on three vertical intersecting planes fit through the three skeleton branches of HV and IVC's center of mass as well as a horizontal plane fit through the skeleton of PV. Our segmentation regarding delineation of the vessels is more accurate than the results of two state-of-the-art techniques on five subjects in terms of the average symmetric surface distance (ASSD) and modified Hausdorff distance (MHD). Furthermore, the proposed liver partitioning achieves large overlap with manual reference segmentations (expressed in Dice Coefficient) in all but a small minority of segments (mean values between 87% and 94% for segments 2-8). The lower mean overlap for segment 1 (72%) is due to the limited spatial resolution of our DCE-MR scan protocol.",

author = "Tian Zhang and Zhiyi Wu and Runge, {Jurgen H.} and Cristina Lavini and Jaap Stoker and {van Gulik}, Thomas and Cieslak, {Kasia P.} and {van Vliet}, {Lucas J.} and Vos, {Frans M.}",

year = "2018",

doi = "https://doi.org/10.1117/12.2293530",

language = "English",

volume = "10574",

series = "Progress in Biomedical Optics and Imaging - Proceedings of SPIE",

publisher = "SPIE",

editor = "Angelini, {Elsa D.} and Landman, {Bennett A.}",

booktitle = "Medical Imaging 2018: Image Processing",

note = "Medical Imaging 2018: Image Processing ; Conference date: 11-02-2018 Through 13-02-2018",

}

Zhang, T, Wu, Z, Runge, JH, Lavini, C , Stoker, J , van Gulik, T, Cieslak, KP, van Vliet, LJ & Vos, FM 2018, A hybrid segmentation method for partitioning the liver based on 4D DCE-MR images. in ED Angelini & BA Landman (eds), Medical Imaging 2018: Image Processing. vol. 10574, 1057434, Progress in Biomedical Optics and Imaging - Proceedings of SPIE, SPIE, Medical Imaging 2018: Image Processing, Houston, United States, 11/02/2018. https://doi.org/10.1117/12.2293530

A hybrid segmentation method for partitioning the liver based on 4D DCE-MR images. / Zhang, Tian; Wu, Zhiyi; Runge, Jurgen H. et al.
Medical Imaging 2018: Image Processing. ed. / Elsa D. Angelini; Bennett A. Landman. Vol. 10574 SPIE, 2018. 1057434 (Progress in Biomedical Optics and Imaging - Proceedings of SPIE).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › Academic › peer-review

TY - GEN

T1 - A hybrid segmentation method for partitioning the liver based on 4D DCE-MR images

AU - Zhang, Tian

AU - Wu, Zhiyi

AU - Runge, Jurgen H.

AU - Lavini, Cristina

AU - Stoker, Jaap

AU - van Gulik, Thomas

AU - Cieslak, Kasia P.

AU - van Vliet, Lucas J.

AU - Vos, Frans M.

PY - 2018

Y1 - 2018

N2 - The Couinaud classification of hepatic anatomy partitions the liver into eight functionally independent segments. Detection and segmentation of the hepatic vein (HV), portal vein (PV) and inferior vena cava (IVC) plays an important role in the subsequent delineation of the liver segments. To facilitate pharmacokinetic modeling of the liver based on the same data, a 4D DCE-MR scan protocol was selected. This yields images with high temporal resolution but low spatial resolution. Since the liver's vasculature consists of many tiny branches, segmentation of these images is challenging. The proposed framework starts with registration of the 4D DCE-MRI series followed by region growing from manually annotated seeds in the main branches of key blood vessels in the liver. It calculates the Pearson correlation between the time intensity curves (TICs) of a seed and all voxels. A maximum correlation map for each vessel is obtained by combining the correlation maps for all branches of the same vessel through a maximum selection per voxel. The maximum correlation map is incorporated in a level set scheme to individually delineate the main vessels. Subsequently, the eight liver segments are segmented based on three vertical intersecting planes fit through the three skeleton branches of HV and IVC's center of mass as well as a horizontal plane fit through the skeleton of PV. Our segmentation regarding delineation of the vessels is more accurate than the results of two state-of-the-art techniques on five subjects in terms of the average symmetric surface distance (ASSD) and modified Hausdorff distance (MHD). Furthermore, the proposed liver partitioning achieves large overlap with manual reference segmentations (expressed in Dice Coefficient) in all but a small minority of segments (mean values between 87% and 94% for segments 2-8). The lower mean overlap for segment 1 (72%) is due to the limited spatial resolution of our DCE-MR scan protocol.

AB - The Couinaud classification of hepatic anatomy partitions the liver into eight functionally independent segments. Detection and segmentation of the hepatic vein (HV), portal vein (PV) and inferior vena cava (IVC) plays an important role in the subsequent delineation of the liver segments. To facilitate pharmacokinetic modeling of the liver based on the same data, a 4D DCE-MR scan protocol was selected. This yields images with high temporal resolution but low spatial resolution. Since the liver's vasculature consists of many tiny branches, segmentation of these images is challenging. The proposed framework starts with registration of the 4D DCE-MRI series followed by region growing from manually annotated seeds in the main branches of key blood vessels in the liver. It calculates the Pearson correlation between the time intensity curves (TICs) of a seed and all voxels. A maximum correlation map for each vessel is obtained by combining the correlation maps for all branches of the same vessel through a maximum selection per voxel. The maximum correlation map is incorporated in a level set scheme to individually delineate the main vessels. Subsequently, the eight liver segments are segmented based on three vertical intersecting planes fit through the three skeleton branches of HV and IVC's center of mass as well as a horizontal plane fit through the skeleton of PV. Our segmentation regarding delineation of the vessels is more accurate than the results of two state-of-the-art techniques on five subjects in terms of the average symmetric surface distance (ASSD) and modified Hausdorff distance (MHD). Furthermore, the proposed liver partitioning achieves large overlap with manual reference segmentations (expressed in Dice Coefficient) in all but a small minority of segments (mean values between 87% and 94% for segments 2-8). The lower mean overlap for segment 1 (72%) is due to the limited spatial resolution of our DCE-MR scan protocol.

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DO - https://doi.org/10.1117/12.2293530

M3 - Conference contribution

VL - 10574

T3 - Progress in Biomedical Optics and Imaging - Proceedings of SPIE

BT - Medical Imaging 2018: Image Processing

A2 - Angelini, Elsa D.

A2 - Landman, Bennett A.

PB - SPIE

T2 - Medical Imaging 2018: Image Processing

Y2 - 11 February 2018 through 13 February 2018

ER -

A hybrid segmentation method for partitioning the liver based on 4D DCE-MR images

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