Deep learning-based automatic segmentation of cerebral infarcts on diffusion MRI

Wi Sun Ryu; Dawid Schellingerhout; Jonghyeok Park; Jinyong Chung; Sang Wuk Jeong; Dong Seok Gwak; Beom Joon Kim; Joon Tae Kim; Keun Sik Hong; Kyung Bok Lee; Tai Hwan Park; Sang Soon Park; Jong Moo Park; Kyusik Kang; Yong Jin Cho; Hong Kyun Park; Byung Chul Lee; Kyung Ho Yu; Mi Sun Oh; Soo Joo Lee; Jae Guk Kim; Jae Kwan Cha; Dae Hyun Kim; Jun Lee; Man Seok Park; Dongmin Kim; Oh Young Bang; Eung Yeop Kim; Chul Ho Sohn; Hosung Kim; Hee Joon Bae; Dong Eog Kim

doi:10.1038/s41598-025-91032-w

Deep learning-based automatic segmentation of cerebral infarcts on diffusion MRI

Wi Sun Ryu, Dawid Schellingerhout, Jonghyeok Park, Jinyong Chung, Sang Wuk Jeong, Dong Seok Gwak, Beom Joon Kim, Joon Tae Kim, Keun Sik Hong, Kyung Bok Lee, Tai Hwan Park, Sang Soon Park, Jong Moo Park, Kyusik Kang, Yong Jin Cho, Hong Kyun Park, Byung Chul Lee, Kyung Ho Yu, Mi Sun Oh, Soo Joo LeeJae Guk Kim, Jae Kwan Cha, Dae Hyun Kim, Jun Lee, Man Seok Park, Dongmin Kim, Oh Young Bang, Eung Yeop Kim, Chul Ho Sohn, Hosung Kim, Hee Joon Bae, Dong Eog Kim

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Abstract

We explored effects of (1) training with various sample sizes of multi-site vs. single-site training data, (2) cross-site domain adaptation, and (3) data sources and features on the performance of algorithms segmenting cerebral infarcts on Magnetic Resonance Imaging (MRI). We used 10,820 annotated diffusion-weighted images (DWIs) from 10 university hospitals. Algorithms based on 3D U-net were trained using progressively larger subsamples (ranging from 217 to 8661), while internal testing employed a distinct set of 2159 DWIs. External validation was conducted using three unrelated datasets (n = 2777, 50, and 250). For domain adaptation, we utilized 50 to 1000 subsamples from the 2777-image external target dataset. As the size of the multi-site training data increased from 217 to 1732, the Dice similarity coefficient (DSC) and average Hausdorff distance (AHD) improved from 0.58 to 0.65 and from 16.1 to 3.75 mm, respectively. Further increases in sample size to 4330 and 8661 led to marginal gains in DSC (to 0.68 and 0.70, respectively) and in AHD (to 2.92 and 1.73). Similar outcomes were observed in external testing. Notably, performance was relatively poor for segmenting brainstem or hyperacute (< 3 h) infarcts. Domain adaptation, even with a small subsample (n = 50) of external data, conditioned the algorithm trained with 217 images to perform comparably to an algorithm trained with 8661 images. In conclusion, the use of multi-site data (approximately 2000 DWIs) and domain adaptation significantly enhances the performance and generalizability of deep learning algorithms for infarct segmentation.

Original language	English
Article number	13214
Journal	Scientific Reports
Volume	15
Issue number	1
DOIs	https://doi.org/10.1038/s41598-025-91032-w
State	Published - Dec 2025

Bibliographical note

Publisher Copyright:
© The Author(s) 2025.

Keywords

Deep learning
Diffusion-weighted image
Domain adaptation
Ischemic stroke
Magnetic resonance imaging

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Ryu, W. S., Schellingerhout, D., Park, J., Chung, J., Jeong, S. W., Gwak, D. S., Kim, B. J., Kim, J. T., Hong, K. S., Lee, K. B., Park, T. H., Park, S. S., Park, J. M., Kang, K., Cho, Y. J., Park, H. K., Lee, B. C., Yu, K. H., Oh, M. S., ... Kim, D. E. (2025). Deep learning-based automatic segmentation of cerebral infarcts on diffusion MRI. Scientific Reports, 15(1), Article 13214. https://doi.org/10.1038/s41598-025-91032-w

@article{7043b9ac76a14c8f857a8226fae8b469,

title = "Deep learning-based automatic segmentation of cerebral infarcts on diffusion MRI",

abstract = "We explored effects of (1) training with various sample sizes of multi-site vs. single-site training data, (2) cross-site domain adaptation, and (3) data sources and features on the performance of algorithms segmenting cerebral infarcts on Magnetic Resonance Imaging (MRI). We used 10,820 annotated diffusion-weighted images (DWIs) from 10 university hospitals. Algorithms based on 3D U-net were trained using progressively larger subsamples (ranging from 217 to 8661), while internal testing employed a distinct set of 2159 DWIs. External validation was conducted using three unrelated datasets (n = 2777, 50, and 250). For domain adaptation, we utilized 50 to 1000 subsamples from the 2777-image external target dataset. As the size of the multi-site training data increased from 217 to 1732, the Dice similarity coefficient (DSC) and average Hausdorff distance (AHD) improved from 0.58 to 0.65 and from 16.1 to 3.75 mm, respectively. Further increases in sample size to 4330 and 8661 led to marginal gains in DSC (to 0.68 and 0.70, respectively) and in AHD (to 2.92 and 1.73). Similar outcomes were observed in external testing. Notably, performance was relatively poor for segmenting brainstem or hyperacute (< 3 h) infarcts. Domain adaptation, even with a small subsample (n = 50) of external data, conditioned the algorithm trained with 217 images to perform comparably to an algorithm trained with 8661 images. In conclusion, the use of multi-site data (approximately 2000 DWIs) and domain adaptation significantly enhances the performance and generalizability of deep learning algorithms for infarct segmentation.",

keywords = "Deep learning, Diffusion-weighted image, Domain adaptation, Ischemic stroke, Magnetic resonance imaging",

author = "Ryu, \{Wi Sun\} and Dawid Schellingerhout and Jonghyeok Park and Jinyong Chung and Jeong, \{Sang Wuk\} and Gwak, \{Dong Seok\} and Kim, \{Beom Joon\} and Kim, \{Joon Tae\} and Hong, \{Keun Sik\} and Lee, \{Kyung Bok\} and Park, \{Tai Hwan\} and Park, \{Sang Soon\} and Park, \{Jong Moo\} and Kyusik Kang and Cho, \{Yong Jin\} and Park, \{Hong Kyun\} and Lee, \{Byung Chul\} and Yu, \{Kyung Ho\} and Oh, \{Mi Sun\} and Lee, \{Soo Joo\} and Kim, \{Jae Guk\} and Cha, \{Jae Kwan\} and Kim, \{Dae Hyun\} and Jun Lee and Park, \{Man Seok\} and Dongmin Kim and Bang, \{Oh Young\} and Kim, \{Eung Yeop\} and Sohn, \{Chul Ho\} and Hosung Kim and Bae, \{Hee Joon\} and Kim, \{Dong Eog\}",

note = "Publisher Copyright: {\textcopyright} The Author(s) 2025.",

year = "2025",

month = dec,

doi = "10.1038/s41598-025-91032-w",

language = "English",

volume = "15",

journal = "Scientific Reports",

issn = "2045-2322",

publisher = "Nature Research",

number = "1",

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Ryu, WS, Schellingerhout, D, Park, J, Chung, J, Jeong, SW, Gwak, DS, Kim, BJ, Kim, JT, Hong, KS, Lee, KB, Park, TH, Park, SS, Park, JM, Kang, K, Cho, YJ, Park, HK, Lee, BC, Yu, KH, Oh, MS, Lee, SJ, Kim, JG, Cha, JK, Kim, DH, Lee, J, Park, MS, Kim, D, Bang, OY, Kim, EY, Sohn, CH, Kim, H, Bae, HJ & Kim, DE 2025, 'Deep learning-based automatic segmentation of cerebral infarcts on diffusion MRI', Scientific Reports, vol. 15, no. 1, 13214. https://doi.org/10.1038/s41598-025-91032-w

TY - JOUR

T1 - Deep learning-based automatic segmentation of cerebral infarcts on diffusion MRI

AU - Ryu, Wi Sun

AU - Schellingerhout, Dawid

AU - Park, Jonghyeok

AU - Chung, Jinyong

AU - Jeong, Sang Wuk

AU - Gwak, Dong Seok

AU - Kim, Beom Joon

AU - Kim, Joon Tae

AU - Hong, Keun Sik

AU - Lee, Kyung Bok

AU - Park, Tai Hwan

AU - Park, Sang Soon

AU - Park, Jong Moo

AU - Kang, Kyusik

AU - Cho, Yong Jin

AU - Park, Hong Kyun

AU - Lee, Byung Chul

AU - Yu, Kyung Ho

AU - Oh, Mi Sun

AU - Lee, Soo Joo

AU - Kim, Jae Guk

AU - Cha, Jae Kwan

AU - Kim, Dae Hyun

AU - Lee, Jun

AU - Park, Man Seok

AU - Kim, Dongmin

AU - Bang, Oh Young

AU - Kim, Eung Yeop

AU - Sohn, Chul Ho

AU - Kim, Hosung

AU - Bae, Hee Joon

AU - Kim, Dong Eog

PY - 2025/12

Y1 - 2025/12

N2 - We explored effects of (1) training with various sample sizes of multi-site vs. single-site training data, (2) cross-site domain adaptation, and (3) data sources and features on the performance of algorithms segmenting cerebral infarcts on Magnetic Resonance Imaging (MRI). We used 10,820 annotated diffusion-weighted images (DWIs) from 10 university hospitals. Algorithms based on 3D U-net were trained using progressively larger subsamples (ranging from 217 to 8661), while internal testing employed a distinct set of 2159 DWIs. External validation was conducted using three unrelated datasets (n = 2777, 50, and 250). For domain adaptation, we utilized 50 to 1000 subsamples from the 2777-image external target dataset. As the size of the multi-site training data increased from 217 to 1732, the Dice similarity coefficient (DSC) and average Hausdorff distance (AHD) improved from 0.58 to 0.65 and from 16.1 to 3.75 mm, respectively. Further increases in sample size to 4330 and 8661 led to marginal gains in DSC (to 0.68 and 0.70, respectively) and in AHD (to 2.92 and 1.73). Similar outcomes were observed in external testing. Notably, performance was relatively poor for segmenting brainstem or hyperacute (< 3 h) infarcts. Domain adaptation, even with a small subsample (n = 50) of external data, conditioned the algorithm trained with 217 images to perform comparably to an algorithm trained with 8661 images. In conclusion, the use of multi-site data (approximately 2000 DWIs) and domain adaptation significantly enhances the performance and generalizability of deep learning algorithms for infarct segmentation.

AB - We explored effects of (1) training with various sample sizes of multi-site vs. single-site training data, (2) cross-site domain adaptation, and (3) data sources and features on the performance of algorithms segmenting cerebral infarcts on Magnetic Resonance Imaging (MRI). We used 10,820 annotated diffusion-weighted images (DWIs) from 10 university hospitals. Algorithms based on 3D U-net were trained using progressively larger subsamples (ranging from 217 to 8661), while internal testing employed a distinct set of 2159 DWIs. External validation was conducted using three unrelated datasets (n = 2777, 50, and 250). For domain adaptation, we utilized 50 to 1000 subsamples from the 2777-image external target dataset. As the size of the multi-site training data increased from 217 to 1732, the Dice similarity coefficient (DSC) and average Hausdorff distance (AHD) improved from 0.58 to 0.65 and from 16.1 to 3.75 mm, respectively. Further increases in sample size to 4330 and 8661 led to marginal gains in DSC (to 0.68 and 0.70, respectively) and in AHD (to 2.92 and 1.73). Similar outcomes were observed in external testing. Notably, performance was relatively poor for segmenting brainstem or hyperacute (< 3 h) infarcts. Domain adaptation, even with a small subsample (n = 50) of external data, conditioned the algorithm trained with 217 images to perform comparably to an algorithm trained with 8661 images. In conclusion, the use of multi-site data (approximately 2000 DWIs) and domain adaptation significantly enhances the performance and generalizability of deep learning algorithms for infarct segmentation.

KW - Deep learning

KW - Diffusion-weighted image

KW - Domain adaptation

KW - Ischemic stroke

KW - Magnetic resonance imaging

UR - https://www.scopus.com/pages/publications/105003124989

U2 - 10.1038/s41598-025-91032-w

DO - 10.1038/s41598-025-91032-w

M3 - Article

C2 - 40240396

AN - SCOPUS:105003124989

SN - 2045-2322

VL - 15

JO - Scientific Reports

JF - Scientific Reports

IS - 1

M1 - 13214

ER -

Deep learning-based automatic segmentation of cerebral infarcts on diffusion MRI

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Keywords

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