DS6, Deformation-Aware Semi-Supervised Learning: Application to Small Vessel Segmentation with Noisy Training Data

Research output: Contribution to journalJournal articleResearchpeer-review

Standard

DS6, Deformation-Aware Semi-Supervised Learning : Application to Small Vessel Segmentation with Noisy Training Data. / Chatterjee, Soumick; Prabhu, Kartik; Pattadkal, Mahantesh; Bortsova, Gerda; Sarasaen, Chompunuch; Dubost, Florian; Mattern, Hendrik; de Bruijne, Marleen; Speck, Oliver; Nürnberger, Andreas.

In: Journal of Imaging, Vol. 8, No. 10, 259, 22.09.2022, p. 1-22.

Research output: Contribution to journalJournal articleResearchpeer-review

Harvard

Chatterjee, S, Prabhu, K, Pattadkal, M, Bortsova, G, Sarasaen, C, Dubost, F, Mattern, H, de Bruijne, M, Speck, O & Nürnberger, A 2022, 'DS6, Deformation-Aware Semi-Supervised Learning: Application to Small Vessel Segmentation with Noisy Training Data', Journal of Imaging, vol. 8, no. 10, 259, pp. 1-22. https://doi.org/10.3390/jimaging8100259

APA

Chatterjee, S., Prabhu, K., Pattadkal, M., Bortsova, G., Sarasaen, C., Dubost, F., Mattern, H., de Bruijne, M., Speck, O., & Nürnberger, A. (2022). DS6, Deformation-Aware Semi-Supervised Learning: Application to Small Vessel Segmentation with Noisy Training Data. Journal of Imaging, 8(10), 1-22. [259]. https://doi.org/10.3390/jimaging8100259

Vancouver

Chatterjee S, Prabhu K, Pattadkal M, Bortsova G, Sarasaen C, Dubost F et al. DS6, Deformation-Aware Semi-Supervised Learning: Application to Small Vessel Segmentation with Noisy Training Data. Journal of Imaging. 2022 Sep 22;8(10):1-22. 259. https://doi.org/10.3390/jimaging8100259

Author

Chatterjee, Soumick ; Prabhu, Kartik ; Pattadkal, Mahantesh ; Bortsova, Gerda ; Sarasaen, Chompunuch ; Dubost, Florian ; Mattern, Hendrik ; de Bruijne, Marleen ; Speck, Oliver ; Nürnberger, Andreas. / DS6, Deformation-Aware Semi-Supervised Learning : Application to Small Vessel Segmentation with Noisy Training Data. In: Journal of Imaging. 2022 ; Vol. 8, No. 10. pp. 1-22.

Bibtex

@article{f96e867eea074d069439cc24e0170b5c,
title = "DS6, Deformation-Aware Semi-Supervised Learning: Application to Small Vessel Segmentation with Noisy Training Data",
abstract = "Blood vessels of the brain provide the human brain with the required nutrients and oxygen. As a vulnerable part of the cerebral blood supply, pathology of small vessels can cause serious problems such as Cerebral Small Vessel Diseases (CSVD). It has also been shown that CSVD is related to neurodegeneration, such as Alzheimer's disease. With the advancement of 7 Tesla MRI systems, higher spatial image resolution can be achieved, enabling the depiction of very small vessels in the brain. Non-Deep Learning-based approaches for vessel segmentation, e.g., Frangi's vessel enhancement with subsequent thresholding, are capable of segmenting medium to large vessels but often fail to segment small vessels. The sensitivity of these methods to small vessels can be increased by extensive parameter tuning or by manual corrections, albeit making them time-consuming, laborious, and not feasible for larger datasets. This paper proposes a deep learning architecture to automatically segment small vessels in 7 Tesla 3D Time-of-Flight (ToF) Magnetic Resonance Angiography (MRA) data. The algorithm was trained and evaluated on a small imperfect semi-automatically segmented dataset of only 11 subjects; using six for training, two for validation, and three for testing. The deep learning model based on U-Net Multi-Scale Supervision was trained using the training subset and was made equivariant to elastic deformations in a self-supervised manner using deformation-aware learning to improve the generalisation performance. The proposed technique was evaluated quantitatively and qualitatively against the test set and achieved a Dice score of 80.44 ± 0.83. Furthermore, the result of the proposed method was compared against a selected manually segmented region (62.07 resultant Dice) and has shown a considerable improvement (18.98%) with deformation-aware learning.",
author = "Soumick Chatterjee and Kartik Prabhu and Mahantesh Pattadkal and Gerda Bortsova and Chompunuch Sarasaen and Florian Dubost and Hendrik Mattern and {de Bruijne}, Marleen and Oliver Speck and Andreas N{\"u}rnberger",
year = "2022",
month = sep,
day = "22",
doi = "10.3390/jimaging8100259",
language = "English",
volume = "8",
pages = "1--22",
journal = "Journal of Imaging",
issn = "2313-433X",
publisher = "MDPI",
number = "10",

}

RIS

TY - JOUR

T1 - DS6, Deformation-Aware Semi-Supervised Learning

T2 - Application to Small Vessel Segmentation with Noisy Training Data

AU - Chatterjee, Soumick

AU - Prabhu, Kartik

AU - Pattadkal, Mahantesh

AU - Bortsova, Gerda

AU - Sarasaen, Chompunuch

AU - Dubost, Florian

AU - Mattern, Hendrik

AU - de Bruijne, Marleen

AU - Speck, Oliver

AU - Nürnberger, Andreas

PY - 2022/9/22

Y1 - 2022/9/22

N2 - Blood vessels of the brain provide the human brain with the required nutrients and oxygen. As a vulnerable part of the cerebral blood supply, pathology of small vessels can cause serious problems such as Cerebral Small Vessel Diseases (CSVD). It has also been shown that CSVD is related to neurodegeneration, such as Alzheimer's disease. With the advancement of 7 Tesla MRI systems, higher spatial image resolution can be achieved, enabling the depiction of very small vessels in the brain. Non-Deep Learning-based approaches for vessel segmentation, e.g., Frangi's vessel enhancement with subsequent thresholding, are capable of segmenting medium to large vessels but often fail to segment small vessels. The sensitivity of these methods to small vessels can be increased by extensive parameter tuning or by manual corrections, albeit making them time-consuming, laborious, and not feasible for larger datasets. This paper proposes a deep learning architecture to automatically segment small vessels in 7 Tesla 3D Time-of-Flight (ToF) Magnetic Resonance Angiography (MRA) data. The algorithm was trained and evaluated on a small imperfect semi-automatically segmented dataset of only 11 subjects; using six for training, two for validation, and three for testing. The deep learning model based on U-Net Multi-Scale Supervision was trained using the training subset and was made equivariant to elastic deformations in a self-supervised manner using deformation-aware learning to improve the generalisation performance. The proposed technique was evaluated quantitatively and qualitatively against the test set and achieved a Dice score of 80.44 ± 0.83. Furthermore, the result of the proposed method was compared against a selected manually segmented region (62.07 resultant Dice) and has shown a considerable improvement (18.98%) with deformation-aware learning.

AB - Blood vessels of the brain provide the human brain with the required nutrients and oxygen. As a vulnerable part of the cerebral blood supply, pathology of small vessels can cause serious problems such as Cerebral Small Vessel Diseases (CSVD). It has also been shown that CSVD is related to neurodegeneration, such as Alzheimer's disease. With the advancement of 7 Tesla MRI systems, higher spatial image resolution can be achieved, enabling the depiction of very small vessels in the brain. Non-Deep Learning-based approaches for vessel segmentation, e.g., Frangi's vessel enhancement with subsequent thresholding, are capable of segmenting medium to large vessels but often fail to segment small vessels. The sensitivity of these methods to small vessels can be increased by extensive parameter tuning or by manual corrections, albeit making them time-consuming, laborious, and not feasible for larger datasets. This paper proposes a deep learning architecture to automatically segment small vessels in 7 Tesla 3D Time-of-Flight (ToF) Magnetic Resonance Angiography (MRA) data. The algorithm was trained and evaluated on a small imperfect semi-automatically segmented dataset of only 11 subjects; using six for training, two for validation, and three for testing. The deep learning model based on U-Net Multi-Scale Supervision was trained using the training subset and was made equivariant to elastic deformations in a self-supervised manner using deformation-aware learning to improve the generalisation performance. The proposed technique was evaluated quantitatively and qualitatively against the test set and achieved a Dice score of 80.44 ± 0.83. Furthermore, the result of the proposed method was compared against a selected manually segmented region (62.07 resultant Dice) and has shown a considerable improvement (18.98%) with deformation-aware learning.

U2 - 10.3390/jimaging8100259

DO - 10.3390/jimaging8100259

M3 - Journal article

C2 - 36286353

VL - 8

SP - 1

EP - 22

JO - Journal of Imaging

JF - Journal of Imaging

SN - 2313-433X

IS - 10

M1 - 259

ER -

ID: 323841098