Evaluation of Diffusion Lesion Volume Measurements in Acute Ischemic Stroke Using Encoder-Decoder Convolutional Network
Background and Purpose- Automatic segmentation of cerebral infarction on diffusion-weighted imaging (DWI) is typically performed based on a fixed apparent diffusion coefficient (ADC) threshold. Fixed ADC threshold methods may not be accurate because ADC values vary over time after stroke onset. Deep...
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| Veröffentlicht in: | Stroke (1970) Jg. 50; H. 6; S. 1444 |
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01.06.2019
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| Abstract | Background and Purpose- Automatic segmentation of cerebral infarction on diffusion-weighted imaging (DWI) is typically performed based on a fixed apparent diffusion coefficient (ADC) threshold. Fixed ADC threshold methods may not be accurate because ADC values vary over time after stroke onset. Deep learning has the potential to improve the accuracy, provided that a large set of correctly annotated lesion data is used for training. The purpose of this study was to evaluate deep learning-based methods and compare them with commercial software in terms of lesion volume measurements. Methods- U-net, an encoder-decoder convolutional neural network, was adopted to train segmentation models. Two U-net models were developed: a U-net (DWI+ADC) model, trained on DWI and ADC data, and a U-net (DWI) model, trained on DWI data only. A total of 296 subjects were used for training and 134 for external validation. An expert neurologist manually delineated the stroke lesions on DWI images, which were used as the ground-truth reference. Lesion volume measurements from the U-net methods were compared against the expert's manual segmentation and Rapid Processing of Perfusion and Diffusion (RAPID; iSchemaView Inc) analysis. Results- In external validation, U-net (DWI+ADC) showed the highest intraclass correlation coefficient with manual segmentation (intraclass correlation coefficient, 1.0; 95% CI, 0.99-1.00) and sufficiently high correlation with the RAPID results (intraclass correlation coefficient, 0.99; 95% CI, 0.98-0.99). U-net (DWI+ADC) and manual segmentation resulted in the smallest 95% Bland-Altman limits of agreement (-5.31 to 4.93 mL) with a mean difference of -0.19 mL. Conclusions- The presented deep learning-based method is fully automatic and shows a high correlation of diffusion lesion volume measurements with manual segmentation and commercial software. The method has the potential to be used in patient selection for endovascular reperfusion therapy in the late time window of acute stroke. |
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| AbstractList | Background and Purpose- Automatic segmentation of cerebral infarction on diffusion-weighted imaging (DWI) is typically performed based on a fixed apparent diffusion coefficient (ADC) threshold. Fixed ADC threshold methods may not be accurate because ADC values vary over time after stroke onset. Deep learning has the potential to improve the accuracy, provided that a large set of correctly annotated lesion data is used for training. The purpose of this study was to evaluate deep learning-based methods and compare them with commercial software in terms of lesion volume measurements. Methods- U-net, an encoder-decoder convolutional neural network, was adopted to train segmentation models. Two U-net models were developed: a U-net (DWI+ADC) model, trained on DWI and ADC data, and a U-net (DWI) model, trained on DWI data only. A total of 296 subjects were used for training and 134 for external validation. An expert neurologist manually delineated the stroke lesions on DWI images, which were used as the ground-truth reference. Lesion volume measurements from the U-net methods were compared against the expert's manual segmentation and Rapid Processing of Perfusion and Diffusion (RAPID; iSchemaView Inc) analysis. Results- In external validation, U-net (DWI+ADC) showed the highest intraclass correlation coefficient with manual segmentation (intraclass correlation coefficient, 1.0; 95% CI, 0.99-1.00) and sufficiently high correlation with the RAPID results (intraclass correlation coefficient, 0.99; 95% CI, 0.98-0.99). U-net (DWI+ADC) and manual segmentation resulted in the smallest 95% Bland-Altman limits of agreement (-5.31 to 4.93 mL) with a mean difference of -0.19 mL. Conclusions- The presented deep learning-based method is fully automatic and shows a high correlation of diffusion lesion volume measurements with manual segmentation and commercial software. The method has the potential to be used in patient selection for endovascular reperfusion therapy in the late time window of acute stroke. Background and Purpose- Automatic segmentation of cerebral infarction on diffusion-weighted imaging (DWI) is typically performed based on a fixed apparent diffusion coefficient (ADC) threshold. Fixed ADC threshold methods may not be accurate because ADC values vary over time after stroke onset. Deep learning has the potential to improve the accuracy, provided that a large set of correctly annotated lesion data is used for training. The purpose of this study was to evaluate deep learning-based methods and compare them with commercial software in terms of lesion volume measurements. Methods- U-net, an encoder-decoder convolutional neural network, was adopted to train segmentation models. Two U-net models were developed: a U-net (DWI+ADC) model, trained on DWI and ADC data, and a U-net (DWI) model, trained on DWI data only. A total of 296 subjects were used for training and 134 for external validation. An expert neurologist manually delineated the stroke lesions on DWI images, which were used as the ground-truth reference. Lesion volume measurements from the U-net methods were compared against the expert's manual segmentation and Rapid Processing of Perfusion and Diffusion (RAPID; iSchemaView Inc) analysis. Results- In external validation, U-net (DWI+ADC) showed the highest intraclass correlation coefficient with manual segmentation (intraclass correlation coefficient, 1.0; 95% CI, 0.99-1.00) and sufficiently high correlation with the RAPID results (intraclass correlation coefficient, 0.99; 95% CI, 0.98-0.99). U-net (DWI+ADC) and manual segmentation resulted in the smallest 95% Bland-Altman limits of agreement (-5.31 to 4.93 mL) with a mean difference of -0.19 mL. Conclusions- The presented deep learning-based method is fully automatic and shows a high correlation of diffusion lesion volume measurements with manual segmentation and commercial software. The method has the potential to be used in patient selection for endovascular reperfusion therapy in the late time window of acute stroke.Background and Purpose- Automatic segmentation of cerebral infarction on diffusion-weighted imaging (DWI) is typically performed based on a fixed apparent diffusion coefficient (ADC) threshold. Fixed ADC threshold methods may not be accurate because ADC values vary over time after stroke onset. Deep learning has the potential to improve the accuracy, provided that a large set of correctly annotated lesion data is used for training. The purpose of this study was to evaluate deep learning-based methods and compare them with commercial software in terms of lesion volume measurements. Methods- U-net, an encoder-decoder convolutional neural network, was adopted to train segmentation models. Two U-net models were developed: a U-net (DWI+ADC) model, trained on DWI and ADC data, and a U-net (DWI) model, trained on DWI data only. A total of 296 subjects were used for training and 134 for external validation. An expert neurologist manually delineated the stroke lesions on DWI images, which were used as the ground-truth reference. Lesion volume measurements from the U-net methods were compared against the expert's manual segmentation and Rapid Processing of Perfusion and Diffusion (RAPID; iSchemaView Inc) analysis. Results- In external validation, U-net (DWI+ADC) showed the highest intraclass correlation coefficient with manual segmentation (intraclass correlation coefficient, 1.0; 95% CI, 0.99-1.00) and sufficiently high correlation with the RAPID results (intraclass correlation coefficient, 0.99; 95% CI, 0.98-0.99). U-net (DWI+ADC) and manual segmentation resulted in the smallest 95% Bland-Altman limits of agreement (-5.31 to 4.93 mL) with a mean difference of -0.19 mL. Conclusions- The presented deep learning-based method is fully automatic and shows a high correlation of diffusion lesion volume measurements with manual segmentation and commercial software. The method has the potential to be used in patient selection for endovascular reperfusion therapy in the late time window of acute stroke. |
| Author | Seong, Joon-Kyung Nam, Hyo Suk Jeong, Han-Gil Bang, Oh Young Chung, Jong-Won Lee, Ji-Eun Kim, Beom Joon Kim, Gyeong-Moon Yu, Inwu Song, Ha-Na Seo, Woo-Keun Kim, Yoon-Chul Baek, In-Young |
| Author_xml | – sequence: 1 givenname: Yoon-Chul surname: Kim fullname: Kim, Yoon-Chul organization: From the Clinical Research Institute (Y.-C.K.), Samsung Medical Center, Sungkyunkwan University School of Medicine, Republic of Korea – sequence: 2 givenname: Ji-Eun surname: Lee fullname: Lee, Ji-Eun organization: Department of Neurology (J.-E.L., I.Y., H.-N.S., I.-Y.B., J.-W.C., O.Y.B., G.-M.K., W.-K.S.), Samsung Medical Center, Sungkyunkwan University School of Medicine, Republic of Korea – sequence: 3 givenname: Inwu surname: Yu fullname: Yu, Inwu organization: Department of Neurology (J.-E.L., I.Y., H.-N.S., I.-Y.B., J.-W.C., O.Y.B., G.-M.K., W.-K.S.), Samsung Medical Center, Sungkyunkwan University School of Medicine, Republic of Korea – sequence: 4 givenname: Ha-Na surname: Song fullname: Song, Ha-Na organization: Department of Neurology (J.-E.L., I.Y., H.-N.S., I.-Y.B., J.-W.C., O.Y.B., G.-M.K., W.-K.S.), Samsung Medical Center, Sungkyunkwan University School of Medicine, Republic of Korea – sequence: 5 givenname: In-Young surname: Baek fullname: Baek, In-Young organization: Department of Neurology (J.-E.L., I.Y., H.-N.S., I.-Y.B., J.-W.C., O.Y.B., G.-M.K., W.-K.S.), Samsung Medical Center, Sungkyunkwan University School of Medicine, Republic of Korea – sequence: 6 givenname: Joon-Kyung surname: Seong fullname: Seong, Joon-Kyung organization: Department of Biomedical Engineering, Korea University, Seoul (J.-K.S.) – sequence: 7 givenname: Han-Gil surname: Jeong fullname: Jeong, Han-Gil organization: Department of Neurology and Cerebrovascular Center, Seoul National University Bundang Hospital, Seong Nam, Republic of Korea (H.-G.J., B.J.K.) – sequence: 8 givenname: Beom Joon surname: Kim fullname: Kim, Beom Joon organization: Department of Neurology and Cerebrovascular Center, Seoul National University Bundang Hospital, Seong Nam, Republic of Korea (H.-G.J., B.J.K.) – sequence: 9 givenname: Hyo Suk surname: Nam fullname: Nam, Hyo Suk organization: Department of Neurology, Yonsei University, Seoul, Republic of Korea (H.S.N.) – sequence: 10 givenname: Jong-Won surname: Chung fullname: Chung, Jong-Won organization: Department of Neurology (J.-E.L., I.Y., H.-N.S., I.-Y.B., J.-W.C., O.Y.B., G.-M.K., W.-K.S.), Samsung Medical Center, Sungkyunkwan University School of Medicine, Republic of Korea – sequence: 11 givenname: Oh Young surname: Bang fullname: Bang, Oh Young organization: Department of Neurology (J.-E.L., I.Y., H.-N.S., I.-Y.B., J.-W.C., O.Y.B., G.-M.K., W.-K.S.), Samsung Medical Center, Sungkyunkwan University School of Medicine, Republic of Korea – sequence: 12 givenname: Gyeong-Moon surname: Kim fullname: Kim, Gyeong-Moon organization: Department of Neurology (J.-E.L., I.Y., H.-N.S., I.-Y.B., J.-W.C., O.Y.B., G.-M.K., W.-K.S.), Samsung Medical Center, Sungkyunkwan University School of Medicine, Republic of Korea – sequence: 13 givenname: Woo-Keun surname: Seo fullname: Seo, Woo-Keun organization: Department of Digital Health, SAIHST, Sungkyunkwan University, Seoul, Republic of Korea (W.-K.S.) |
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| SubjectTerms | Aged Cerebral Infarction - diagnostic imaging Diffusion Magnetic Resonance Imaging Female Humans Male Middle Aged Neural Networks, Computer Registries Software Stroke - diagnostic imaging |
| Title | Evaluation of Diffusion Lesion Volume Measurements in Acute Ischemic Stroke Using Encoder-Decoder Convolutional Network |
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