Fully Automated Thrombus Segmentation on CT Images of Patients with Acute Ischemic Stroke

Mahsa Mojtahedi; Manon Kappelhof; Elena Ponomareva; Manon Tolhuisen; Ivo Jansen; Agnetha A E Bruggeman; Bruna G Dutra; Lonneke Yo; Natalie LeCouffe; Jan W Hoving; Henk van Voorst; Josje Brouwer; Nerea Arrarte Terreros; Praneeta Konduri; Frederick J A Meijer; Auke Appelman; Kilian M Treurniet; Jonathan M Coutinho; Yvo Roos; Wim van Zwam; Diederik Dippel; Efstratios Gavves; Bart J Emmer; Charles Majoie; Henk Marquering

doi:10.3390/diagnostics12030698

Fully Automated Thrombus Segmentation on CT Images of Patients with Acute Ischemic Stroke

Mahsa Mojtahedi^*, Manon Kappelhof, Elena Ponomareva, Manon Tolhuisen, Ivo Jansen, Agnetha A E Bruggeman, Bruna G Dutra, Lonneke Yo, Natalie LeCouffe, Jan W Hoving, Henk van Voorst, Josje Brouwer, Nerea Arrarte Terreros, Praneeta Konduri, Frederick J A Meijer, Auke Appelman, Kilian M Treurniet, Jonathan M Coutinho, Yvo Roos, Wim van ZwamDiederik Dippel, Efstratios Gavves, Bart J Emmer, Charles Majoie, Henk Marquering

^*Corresponding author for this work

Research output: Contribution to journal › Article › Academic › peer-review

Abstract

Thrombus imaging characteristics are associated with treatment success and functional outcomes in stroke patients. However, assessing these characteristics based on manual annotations is labor intensive and subject to observer bias. Therefore, we aimed to create an automated pipeline for consistent and fast full thrombus segmentation. We used multi-center, multi-scanner datasets of anterior circulation stroke patients with baseline NCCT and CTA for training (n = 228) and testing (n = 100). We first found the occlusion location using StrokeViewer LVO and created a bounding box around it. Subsequently, we trained dual modality U-Net based convolutional neural networks (CNNs) to segment the thrombus inside this bounding box. We experimented with: (1) U-Net with two input channels for NCCT and CTA, and U-Nets with two encoders where (2) concatenate, (3) add, and (4) weighted-sum operators were used for feature fusion. Furthermore, we proposed a dynamic bounding box algorithm to adjust the bounding box. The dynamic bounding box algorithm reduces the missed cases but does not improve Dice. The two-encoder U-Net with a weighted-sum feature fusion shows the best performance (surface Dice 0.78, Dice 0.62, and 4% missed cases). Final segmentation results have high spatial accuracies and can therefore be used to determine thrombus characteristics and potentially benefit radiologists in clinical practice.

Original language	English
Article number	698
Number of pages	22
Journal	Diagnostics
Volume	12
Issue number	3
DOIs	https://doi.org/10.3390/diagnostics12030698
Publication status	Published - 12 Mar 2022

Keywords

ASSOCIATION
CT angiography
CT imaging
RECANALIZATION
U-Net
convolutional neural network (CNN)
ischemic stroke
segmentation
thrombus

Access to Document

10.3390/diagnostics12030698Licence: CC BY

Cite this

Mojtahedi, M., Kappelhof, M., Ponomareva, E., Tolhuisen, M., Jansen, I., Bruggeman, A. A. E., Dutra, B. G., Yo, L., LeCouffe, N., Hoving, J. W., van Voorst, H., Brouwer, J., Terreros, N. A., Konduri, P., Meijer, F. J. A., Appelman, A., Treurniet, K. M., Coutinho, J. M., Roos, Y., ... Marquering, H. (2022). Fully Automated Thrombus Segmentation on CT Images of Patients with Acute Ischemic Stroke. Diagnostics, 12(3), Article 698. https://doi.org/10.3390/diagnostics12030698

@article{cb3e4028c3b643e980b349f40c113413,

title = "Fully Automated Thrombus Segmentation on CT Images of Patients with Acute Ischemic Stroke",

abstract = "Thrombus imaging characteristics are associated with treatment success and functional outcomes in stroke patients. However, assessing these characteristics based on manual annotations is labor intensive and subject to observer bias. Therefore, we aimed to create an automated pipeline for consistent and fast full thrombus segmentation. We used multi-center, multi-scanner datasets of anterior circulation stroke patients with baseline NCCT and CTA for training (n = 228) and testing (n = 100). We first found the occlusion location using StrokeViewer LVO and created a bounding box around it. Subsequently, we trained dual modality U-Net based convolutional neural networks (CNNs) to segment the thrombus inside this bounding box. We experimented with: (1) U-Net with two input channels for NCCT and CTA, and U-Nets with two encoders where (2) concatenate, (3) add, and (4) weighted-sum operators were used for feature fusion. Furthermore, we proposed a dynamic bounding box algorithm to adjust the bounding box. The dynamic bounding box algorithm reduces the missed cases but does not improve Dice. The two-encoder U-Net with a weighted-sum feature fusion shows the best performance (surface Dice 0.78, Dice 0.62, and 4% missed cases). Final segmentation results have high spatial accuracies and can therefore be used to determine thrombus characteristics and potentially benefit radiologists in clinical practice.",

keywords = "ASSOCIATION, CT angiography, CT imaging, RECANALIZATION, U-Net, convolutional neural network (CNN), ischemic stroke, segmentation, thrombus",

author = "Mahsa Mojtahedi and Manon Kappelhof and Elena Ponomareva and Manon Tolhuisen and Ivo Jansen and Bruggeman, {Agnetha A E} and Dutra, {Bruna G} and Lonneke Yo and Natalie LeCouffe and Hoving, {Jan W} and {van Voorst}, Henk and Josje Brouwer and Terreros, {Nerea Arrarte} and Praneeta Konduri and Meijer, {Frederick J A} and Auke Appelman and Treurniet, {Kilian M} and Coutinho, {Jonathan M} and Yvo Roos and {van Zwam}, Wim and Diederik Dippel and Efstratios Gavves and Emmer, {Bart J} and Charles Majoie and Henk Marquering",

note = "Funding Information: Funding: This project is part of the Artificial Intelligence for Early Imaging Based Patient Selection in Acute Ischemic Stroke (AIRBORNE), which is funded by Top Sector Life Sciences & Health and Nicolab B.V. The commercial entities mentioned hereafter did not fund this project directly: MR CLEAN NO-IV was funded through the CONTRAST consortium, which acknowledges the support from the Netherlands Cardiovascular Research Initiative, an initiative of the Dutch Heart Foundation (CVON2015-01: CONTRAST), and from the Brain Foundation Netherlands (HA2015.01.06). Additionally, it is financed by the Ministry of Economic Affairs by means of the PPP allowance made available by the Top Sector Life Sciences & Health to stimulate public–private partnerships (LSHM17016). The MR CLEAN trial was supported by the Dutch Heart Foundation and by unrestricted grants from AngioCare BV, Medtronic/Covidien/EV3, MEDAC Gmbh/LAMEPRO, Penumbra Inc., Stryker, and Top Medical/Concentric. Funding Information: Conflicts of Interest: H.M. is co-founder and shareholder of Nicolab; C.M., Y.R., E.P. and I.J. are shareholders of Nicolab. I.J. and E.P. are employed by the company Nicolab. C.M. reports grants from CVON/Dutch Heart Foundation, TWIN Foundation, European Commission, Health Evaluation Netherlands, and Stryker (paid to the institution). Funding Information: This project is part of the Artificial Intelligence for Early Imaging Based Patient Selection in Acute Ischemic Stroke (AIRBORNE), which is funded by Top Sector Life Sciences & Health and Nicolab B.V. The commercial entities mentioned hereafter did not fund this project directly: MR CLEAN NO-IV was funded through the CONTRAST consortium, which acknowledges the support from the Netherlands Cardiovascular Research Initiative, an initiative of the Dutch Heart Foundation (CVON2015-01: CONTRAST), and from the Brain Foundation Netherlands (HA2015.01.06). Addition-ally, it is financed by the Ministry of Economic Affairs by means of the PPP allowance made available by the Top Sector Life Sciences & Health to stimulate public–private partnerships (LSHM17016). The MR CLEAN trial was supported by the Dutch Heart Foundation and by unrestricted grants from AngioCare BV, Medtronic/Covidien/EV3, MEDAC Gmbh/LAMEPRO, Penumbra Inc., Stryker, and Top Medical/Concentric. Publisher Copyright: {\textcopyright} 2022 by the authors. Licensee MDPI, Basel, Switzerland.",

year = "2022",

month = mar,

day = "12",

doi = "10.3390/diagnostics12030698",

language = "English",

volume = "12",

journal = "Diagnostics",

issn = "2075-4418",

publisher = "MDPI",

number = "3",

}

Mojtahedi, M, Kappelhof, M, Ponomareva, E, Tolhuisen, M, Jansen, I, Bruggeman, AAE, Dutra, BG, Yo, L, LeCouffe, N, Hoving, JW, van Voorst, H, Brouwer, J, Terreros, NA, Konduri, P, Meijer, FJA, Appelman, A, Treurniet, KM, Coutinho, JM, Roos, Y, van Zwam, W, Dippel, D, Gavves, E, Emmer, BJ, Majoie, C & Marquering, H 2022, 'Fully Automated Thrombus Segmentation on CT Images of Patients with Acute Ischemic Stroke', Diagnostics, vol. 12, no. 3, 698. https://doi.org/10.3390/diagnostics12030698

TY - JOUR

T1 - Fully Automated Thrombus Segmentation on CT Images of Patients with Acute Ischemic Stroke

AU - Mojtahedi, Mahsa

AU - Kappelhof, Manon

AU - Ponomareva, Elena

AU - Tolhuisen, Manon

AU - Jansen, Ivo

AU - Bruggeman, Agnetha A E

AU - Dutra, Bruna G

AU - Yo, Lonneke

AU - LeCouffe, Natalie

AU - Hoving, Jan W

AU - van Voorst, Henk

AU - Brouwer, Josje

AU - Terreros, Nerea Arrarte

AU - Konduri, Praneeta

AU - Meijer, Frederick J A

AU - Appelman, Auke

AU - Treurniet, Kilian M

AU - Coutinho, Jonathan M

AU - Roos, Yvo

AU - van Zwam, Wim

AU - Dippel, Diederik

AU - Gavves, Efstratios

AU - Emmer, Bart J

AU - Majoie, Charles

AU - Marquering, Henk

N1 - Funding Information: Funding: This project is part of the Artificial Intelligence for Early Imaging Based Patient Selection in Acute Ischemic Stroke (AIRBORNE), which is funded by Top Sector Life Sciences & Health and Nicolab B.V. The commercial entities mentioned hereafter did not fund this project directly: MR CLEAN NO-IV was funded through the CONTRAST consortium, which acknowledges the support from the Netherlands Cardiovascular Research Initiative, an initiative of the Dutch Heart Foundation (CVON2015-01: CONTRAST), and from the Brain Foundation Netherlands (HA2015.01.06). Additionally, it is financed by the Ministry of Economic Affairs by means of the PPP allowance made available by the Top Sector Life Sciences & Health to stimulate public–private partnerships (LSHM17016). The MR CLEAN trial was supported by the Dutch Heart Foundation and by unrestricted grants from AngioCare BV, Medtronic/Covidien/EV3, MEDAC Gmbh/LAMEPRO, Penumbra Inc., Stryker, and Top Medical/Concentric. Funding Information: Conflicts of Interest: H.M. is co-founder and shareholder of Nicolab; C.M., Y.R., E.P. and I.J. are shareholders of Nicolab. I.J. and E.P. are employed by the company Nicolab. C.M. reports grants from CVON/Dutch Heart Foundation, TWIN Foundation, European Commission, Health Evaluation Netherlands, and Stryker (paid to the institution). Funding Information: This project is part of the Artificial Intelligence for Early Imaging Based Patient Selection in Acute Ischemic Stroke (AIRBORNE), which is funded by Top Sector Life Sciences & Health and Nicolab B.V. The commercial entities mentioned hereafter did not fund this project directly: MR CLEAN NO-IV was funded through the CONTRAST consortium, which acknowledges the support from the Netherlands Cardiovascular Research Initiative, an initiative of the Dutch Heart Foundation (CVON2015-01: CONTRAST), and from the Brain Foundation Netherlands (HA2015.01.06). Addition-ally, it is financed by the Ministry of Economic Affairs by means of the PPP allowance made available by the Top Sector Life Sciences & Health to stimulate public–private partnerships (LSHM17016). The MR CLEAN trial was supported by the Dutch Heart Foundation and by unrestricted grants from AngioCare BV, Medtronic/Covidien/EV3, MEDAC Gmbh/LAMEPRO, Penumbra Inc., Stryker, and Top Medical/Concentric. Publisher Copyright: © 2022 by the authors. Licensee MDPI, Basel, Switzerland.

PY - 2022/3/12

Y1 - 2022/3/12

N2 - Thrombus imaging characteristics are associated with treatment success and functional outcomes in stroke patients. However, assessing these characteristics based on manual annotations is labor intensive and subject to observer bias. Therefore, we aimed to create an automated pipeline for consistent and fast full thrombus segmentation. We used multi-center, multi-scanner datasets of anterior circulation stroke patients with baseline NCCT and CTA for training (n = 228) and testing (n = 100). We first found the occlusion location using StrokeViewer LVO and created a bounding box around it. Subsequently, we trained dual modality U-Net based convolutional neural networks (CNNs) to segment the thrombus inside this bounding box. We experimented with: (1) U-Net with two input channels for NCCT and CTA, and U-Nets with two encoders where (2) concatenate, (3) add, and (4) weighted-sum operators were used for feature fusion. Furthermore, we proposed a dynamic bounding box algorithm to adjust the bounding box. The dynamic bounding box algorithm reduces the missed cases but does not improve Dice. The two-encoder U-Net with a weighted-sum feature fusion shows the best performance (surface Dice 0.78, Dice 0.62, and 4% missed cases). Final segmentation results have high spatial accuracies and can therefore be used to determine thrombus characteristics and potentially benefit radiologists in clinical practice.

AB - Thrombus imaging characteristics are associated with treatment success and functional outcomes in stroke patients. However, assessing these characteristics based on manual annotations is labor intensive and subject to observer bias. Therefore, we aimed to create an automated pipeline for consistent and fast full thrombus segmentation. We used multi-center, multi-scanner datasets of anterior circulation stroke patients with baseline NCCT and CTA for training (n = 228) and testing (n = 100). We first found the occlusion location using StrokeViewer LVO and created a bounding box around it. Subsequently, we trained dual modality U-Net based convolutional neural networks (CNNs) to segment the thrombus inside this bounding box. We experimented with: (1) U-Net with two input channels for NCCT and CTA, and U-Nets with two encoders where (2) concatenate, (3) add, and (4) weighted-sum operators were used for feature fusion. Furthermore, we proposed a dynamic bounding box algorithm to adjust the bounding box. The dynamic bounding box algorithm reduces the missed cases but does not improve Dice. The two-encoder U-Net with a weighted-sum feature fusion shows the best performance (surface Dice 0.78, Dice 0.62, and 4% missed cases). Final segmentation results have high spatial accuracies and can therefore be used to determine thrombus characteristics and potentially benefit radiologists in clinical practice.

KW - ASSOCIATION

KW - CT angiography

KW - CT imaging

KW - RECANALIZATION

KW - U-Net

KW - convolutional neural network (CNN)

KW - ischemic stroke

KW - segmentation

KW - thrombus

U2 - 10.3390/diagnostics12030698

DO - 10.3390/diagnostics12030698

M3 - Article

C2 - 35328251

SN - 2075-4418

VL - 12

JO - Diagnostics

JF - Diagnostics

IS - 3

M1 - 698

ER -