Predicting Age from White Matter Diffusivity with Residual Learning: Progress in Biomedical Optics and Imaging - Proceedings of SPIE

C. Gao; M.E. Kim; H.H. Lee; Q. Yang; N.M. Khairi; P. Kanakaraj; N.R. Newlin; D.B. Archer; A.L. Jefferson; W.D. Taylor; B.D. Boyd; L.L. Beason-Held; S.M. Resnick; Y. Huo; K.D. Van Schaik; K.G. Schilling; D. Moyer; I. Išgum; B.A. Landman; M. Albert; C. Pettigrew; B. Rodzon; A. Soldan; R. Gottesman; L. Farrington; M. Grega; G. Rudow; R. Brichko; S. Rudow; J. Giles; N. Sacktor; M. Miller; S. Mori; A. Kolasny; H. Lu; K. Oishi; T. Ratnanather; P. vanZijl; L. Younes; A. Moghekar; J. Darrow; A. Lewis; R. O’Brien; R. Scherer; A. Ervin; D. Shade; J. Jones; H. Coulibaly; K. Moser; C. Potter; M.-C. Wang; Y. Zhu; J. Wang; J. Troncoso; D. Nauen; O. Pletnikova; K. Fisher; P. Worley; J. Walston; M.-F. Xiao; Y. Sun; Y. Xu; Colliot O.; Mitra J.

doi:10.1117/12.3006525

Predicting Age from White Matter Diffusivity with Residual Learning: Progress in Biomedical Optics and Imaging - Proceedings of SPIE

C. Gao
, M.E. Kim
, H.H. Lee
, Q. Yang
, N.M. Khairi
, P. Kanakaraj
, N.R. Newlin
, D.B. Archer
, A.L. Jefferson
, W.D. Taylor
, B.D. Boyd
, L.L. Beason-Held
, S.M. Resnick
, Y. Huo
, K.D. Van Schaik
, K.G. Schilling
, D. Moyer
, I. Išgum
, B.A. Landman
, M. Albert

C. Pettigrew, B. Rodzon, A. Soldan, R. Gottesman, L. Farrington, M. Grega, G. Rudow, R. Brichko, S. Rudow, J. Giles, N. Sacktor, M. Miller, S. Mori, A. Kolasny, H. Lu, K. Oishi, T. Ratnanather, P. vanZijl, L. Younes, A. Moghekar, J. Darrow, A. Lewis, R. O’Brien, R. Scherer, A. Ervin, D. Shade, J. Jones, H. Coulibaly, K. Moser, C. Potter, M.-C. Wang, Y. Zhu, J. Wang, J. Troncoso, D. Nauen, O. Pletnikova, K. Fisher, P. Worley, J. Walston, M.-F. Xiao, Y. Sun, Y. Xu, Colliot O. (Editor), Mitra J. (Editor)

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Abstract

Imaging findings inconsistent with those expected at specific chronological age ranges may serve as early indicators of neurological disorders and increased mortality risk. Estimation of chronological age, and deviations from expected results, from structural magnetic resonance imaging (MRI) data has become an important proxy task for developing biomarkers that are sensitive to such deviations. Complementary to structural analysis, diffusion tensor imaging (DTI) has proven effective in identifying age-related microstructural changes within the brain white matter, thereby presenting itself as a promising additional modality for brain age prediction. Although early studies have sought to harness DTI’s advantages for age estimation, there is no evidence that the success of this prediction is owed to the unique microstructural and diffusivity features that DTI provides, rather than the macrostructural features that are also available in DTI data. Therefore, we seek to develop white-matter-specific age estimation to capture deviations from normal white matter aging. Specifically, we deliberately disregard the macrostructural information when predicting age from DTI scalar images, using two distinct methods. The first method relies on extracting only microstructural features from regions of interest (ROIs). The second applies 3D residual neural networks (ResNets) to learn features directly from the images, which are non-linearly registered and warped to a template to minimize macrostructural variations. When tested on unseen data, the first method yields mean absolute error (MAE) of 6.11 ± 0.19 years for cognitively normal participants and MAE of 6.62 ± 0.30 years for cognitively impaired participants, while the second method achieves MAE of 4.69 ± 0.23 years for cognitively normal participants and MAE of 4.96 ± 0.28 years for cognitively impaired participants. We find that the ResNet model captures subtler, non-macrostructural features for brain age prediction. © 2024 SPIE.

Original language	English
DOIs	https://doi.org/10.1117/12.3006525
Publication status	Published - 2024

Keywords

brain age
convolutional neural networks
deep learning
DTI
Convolutional neural networks
Deep learning
Forecasting
Magnetic resonance imaging
Tensors
Age estimation
Age predictions
Brain age
Chronological age
Cognitively impaired
Convolutional neural network
Early indicators
Mean absolute error
White matter
Diffusion tensor imaging

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Gao, C., Kim, M. E., Lee, H. H., Yang, Q., Khairi, N. M., Kanakaraj, P., Newlin, N. R., Archer, D. B., Jefferson, A. L., Taylor, W. D., Boyd, B. D., Beason-Held, L. L., Resnick, S. M., Huo, Y., Van Schaik, K. D., Schilling, K. G., Moyer, D., Išgum, I., Landman, B. A., ... J., M. (Ed.) (2024). Predicting Age from White Matter Diffusivity with Residual Learning: Progress in Biomedical Optics and Imaging - Proceedings of SPIE. https://doi.org/10.1117/12.3006525

@conference{1499fb999a3543ccb45d1475e7d25133,

title = "Predicting Age from White Matter Diffusivity with Residual Learning: Progress in Biomedical Optics and Imaging - Proceedings of SPIE",

abstract = "Imaging findings inconsistent with those expected at specific chronological age ranges may serve as early indicators of neurological disorders and increased mortality risk. Estimation of chronological age, and deviations from expected results, from structural magnetic resonance imaging (MRI) data has become an important proxy task for developing biomarkers that are sensitive to such deviations. Complementary to structural analysis, diffusion tensor imaging (DTI) has proven effective in identifying age-related microstructural changes within the brain white matter, thereby presenting itself as a promising additional modality for brain age prediction. Although early studies have sought to harness DTI{\textquoteright}s advantages for age estimation, there is no evidence that the success of this prediction is owed to the unique microstructural and diffusivity features that DTI provides, rather than the macrostructural features that are also available in DTI data. Therefore, we seek to develop white-matter-specific age estimation to capture deviations from normal white matter aging. Specifically, we deliberately disregard the macrostructural information when predicting age from DTI scalar images, using two distinct methods. The first method relies on extracting only microstructural features from regions of interest (ROIs). The second applies 3D residual neural networks (ResNets) to learn features directly from the images, which are non-linearly registered and warped to a template to minimize macrostructural variations. When tested on unseen data, the first method yields mean absolute error (MAE) of 6.11 ± 0.19 years for cognitively normal participants and MAE of 6.62 ± 0.30 years for cognitively impaired participants, while the second method achieves MAE of 4.69 ± 0.23 years for cognitively normal participants and MAE of 4.96 ± 0.28 years for cognitively impaired participants. We find that the ResNet model captures subtler, non-macrostructural features for brain age prediction. {\textcopyright} 2024 SPIE.",

keywords = "brain age, convolutional neural networks, deep learning, DTI, Convolutional neural networks, Deep learning, Forecasting, Magnetic resonance imaging, Tensors, Age estimation, Age predictions, Brain age, Chronological age, Cognitively impaired, Convolutional neural network, Early indicators, Mean absolute error, White matter, Diffusion tensor imaging",

author = "C. Gao and M.E. Kim and H.H. Lee and Q. Yang and N.M. Khairi and P. Kanakaraj and N.R. Newlin and D.B. Archer and A.L. Jefferson and W.D. Taylor and B.D. Boyd and L.L. Beason-Held and S.M. Resnick and Y. Huo and \{Van Schaik\}, K.D. and K.G. Schilling and D. Moyer and I. I{\v s}gum and B.A. Landman and M. Albert and C. Pettigrew and B. Rodzon and A. Soldan and R. Gottesman and L. Farrington and M. Grega and G. Rudow and R. Brichko and S. Rudow and J. Giles and N. Sacktor and M. Miller and S. Mori and A. Kolasny and H. Lu and K. Oishi and T. Ratnanather and P. vanZijl and L. Younes and A. Moghekar and J. Darrow and A. Lewis and R. O{\textquoteright}Brien and R. Scherer and A. Ervin and D. Shade and J. Jones and H. Coulibaly and K. Moser and C. Potter and M.-C. Wang and Y. Zhu and J. Wang and J. Troncoso and D. Nauen and O. Pletnikova and K. Fisher and P. Worley and J. Walston and M.-F. Xiao and Y. Sun and Y. Xu and Colliot O. and Mitra J.",

note = "Export Date: 25 February 2025; Cited By: 0; Correspondence Address: C. Gao; Dept. of Electrical and Computer Engineering, Vanderbilt University, Nashville, United States; email: [email protected]; Conference name: Medical Imaging 2024: Image Processing; Conference date: 19 February 2024 through 22 February 2024; Conference code: 199405",

year = "2024",

doi = "10.1117/12.3006525",

language = "English",

}

Gao, C, Kim, ME, Lee, HH, Yang, Q, Khairi, NM, Kanakaraj, P, Newlin, NR, Archer, DB, Jefferson, AL, Taylor, WD, Boyd, BD, Beason-Held, LL, Resnick, SM, Huo, Y, Van Schaik, KD, Schilling, KG, Moyer, D, Išgum, I, Landman, BA, Albert, M, Pettigrew, C, Rodzon, B, Soldan, A, Gottesman, R, Farrington, L, Grega, M, Rudow, G, Brichko, R, Rudow, S, Giles, J, Sacktor, N, Miller, M, Mori, S, Kolasny, A, Lu, H, Oishi, K, Ratnanather, T, vanZijl, P, Younes, L, Moghekar, A, Darrow, J, Lewis, A, O’Brien, R, Scherer, R, Ervin, A, Shade, D, Jones, J, Coulibaly, H, Moser, K, Potter, C, Wang, M-C, Zhu, Y, Wang, J, Troncoso, J, Nauen, D, Pletnikova, O, Fisher, K, Worley, P, Walston, J, Xiao, M-F, Sun, Y, Xu, Y, O., C (ed.) & J., M (ed.) 2024, 'Predicting Age from White Matter Diffusivity with Residual Learning: Progress in Biomedical Optics and Imaging - Proceedings of SPIE'. https://doi.org/10.1117/12.3006525

TY - CONF

T1 - Predicting Age from White Matter Diffusivity with Residual Learning

T2 - Progress in Biomedical Optics and Imaging - Proceedings of SPIE

AU - Gao, C.

AU - Kim, M.E.

AU - Lee, H.H.

AU - Yang, Q.

AU - Khairi, N.M.

AU - Kanakaraj, P.

AU - Newlin, N.R.

AU - Archer, D.B.

AU - Jefferson, A.L.

AU - Taylor, W.D.

AU - Boyd, B.D.

AU - Beason-Held, L.L.

AU - Resnick, S.M.

AU - Huo, Y.

AU - Van Schaik, K.D.

AU - Schilling, K.G.

AU - Moyer, D.

AU - Išgum, I.

AU - Landman, B.A.

AU - Albert, M.

AU - Pettigrew, C.

AU - Rodzon, B.

AU - Soldan, A.

AU - Gottesman, R.

AU - Farrington, L.

AU - Grega, M.

AU - Rudow, G.

AU - Brichko, R.

AU - Rudow, S.

AU - Giles, J.

AU - Sacktor, N.

AU - Miller, M.

AU - Mori, S.

AU - Kolasny, A.

AU - Lu, H.

AU - Oishi, K.

AU - Ratnanather, T.

AU - vanZijl, P.

AU - Younes, L.

AU - Moghekar, A.

AU - Darrow, J.

AU - Lewis, A.

AU - O’Brien, R.

AU - Scherer, R.

AU - Ervin, A.

AU - Shade, D.

AU - Jones, J.

AU - Coulibaly, H.

AU - Moser, K.

AU - Potter, C.

AU - Wang, M.-C.

AU - Zhu, Y.

AU - Wang, J.

AU - Troncoso, J.

AU - Nauen, D.

AU - Pletnikova, O.

AU - Fisher, K.

AU - Worley, P.

AU - Walston, J.

AU - Xiao, M.-F.

AU - Sun, Y.

AU - Xu, Y.

A2 - O., Colliot

A2 - J., Mitra

N1 - Export Date: 25 February 2025; Cited By: 0; Correspondence Address: C. Gao; Dept. of Electrical and Computer Engineering, Vanderbilt University, Nashville, United States; email: [email protected]; Conference name: Medical Imaging 2024: Image Processing; Conference date: 19 February 2024 through 22 February 2024; Conference code: 199405

PY - 2024

Y1 - 2024

N2 - Imaging findings inconsistent with those expected at specific chronological age ranges may serve as early indicators of neurological disorders and increased mortality risk. Estimation of chronological age, and deviations from expected results, from structural magnetic resonance imaging (MRI) data has become an important proxy task for developing biomarkers that are sensitive to such deviations. Complementary to structural analysis, diffusion tensor imaging (DTI) has proven effective in identifying age-related microstructural changes within the brain white matter, thereby presenting itself as a promising additional modality for brain age prediction. Although early studies have sought to harness DTI’s advantages for age estimation, there is no evidence that the success of this prediction is owed to the unique microstructural and diffusivity features that DTI provides, rather than the macrostructural features that are also available in DTI data. Therefore, we seek to develop white-matter-specific age estimation to capture deviations from normal white matter aging. Specifically, we deliberately disregard the macrostructural information when predicting age from DTI scalar images, using two distinct methods. The first method relies on extracting only microstructural features from regions of interest (ROIs). The second applies 3D residual neural networks (ResNets) to learn features directly from the images, which are non-linearly registered and warped to a template to minimize macrostructural variations. When tested on unseen data, the first method yields mean absolute error (MAE) of 6.11 ± 0.19 years for cognitively normal participants and MAE of 6.62 ± 0.30 years for cognitively impaired participants, while the second method achieves MAE of 4.69 ± 0.23 years for cognitively normal participants and MAE of 4.96 ± 0.28 years for cognitively impaired participants. We find that the ResNet model captures subtler, non-macrostructural features for brain age prediction. © 2024 SPIE.

AB - Imaging findings inconsistent with those expected at specific chronological age ranges may serve as early indicators of neurological disorders and increased mortality risk. Estimation of chronological age, and deviations from expected results, from structural magnetic resonance imaging (MRI) data has become an important proxy task for developing biomarkers that are sensitive to such deviations. Complementary to structural analysis, diffusion tensor imaging (DTI) has proven effective in identifying age-related microstructural changes within the brain white matter, thereby presenting itself as a promising additional modality for brain age prediction. Although early studies have sought to harness DTI’s advantages for age estimation, there is no evidence that the success of this prediction is owed to the unique microstructural and diffusivity features that DTI provides, rather than the macrostructural features that are also available in DTI data. Therefore, we seek to develop white-matter-specific age estimation to capture deviations from normal white matter aging. Specifically, we deliberately disregard the macrostructural information when predicting age from DTI scalar images, using two distinct methods. The first method relies on extracting only microstructural features from regions of interest (ROIs). The second applies 3D residual neural networks (ResNets) to learn features directly from the images, which are non-linearly registered and warped to a template to minimize macrostructural variations. When tested on unseen data, the first method yields mean absolute error (MAE) of 6.11 ± 0.19 years for cognitively normal participants and MAE of 6.62 ± 0.30 years for cognitively impaired participants, while the second method achieves MAE of 4.69 ± 0.23 years for cognitively normal participants and MAE of 4.96 ± 0.28 years for cognitively impaired participants. We find that the ResNet model captures subtler, non-macrostructural features for brain age prediction. © 2024 SPIE.

KW - brain age

KW - convolutional neural networks

KW - deep learning

KW - DTI

KW - Convolutional neural networks

KW - Deep learning

KW - Forecasting

KW - Magnetic resonance imaging

KW - Tensors

KW - Age estimation

KW - Age predictions

KW - Brain age

KW - Chronological age

KW - Cognitively impaired

KW - Convolutional neural network

KW - Early indicators

KW - Mean absolute error

KW - White matter

KW - Diffusion tensor imaging

U2 - 10.1117/12.3006525

DO - 10.1117/12.3006525

M3 - Paper

C2 - 39310214

ER -

Predicting Age from White Matter Diffusivity with Residual Learning: Progress in Biomedical Optics and Imaging - Proceedings of SPIE

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Keywords

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