Histopathologic brain age estimation via multiple instance learning

Gabriel A. Marx; Justin Kauffman; Andrew T. McKenzie; Daniel G. Koenigsberg; Cory T. McMillan; Susan Morgello; Esma Karlovich; Ricardo Insausti; Timothy E. Richardson; Jamie M. Walker; Charles L. White; Bergan M. Babrowicz; Li Shen; Ann C. McKee; Thor D. Stein; Kurt Farrell; John F. Crary

doi:10.1007/s00401-023-02636-3

Histopathologic brain age estimation via multiple instance learning

Gabriel A. Marx, Justin Kauffman, Andrew T. McKenzie, Daniel G. Koenigsberg, Cory T. McMillan, Susan Morgello, Esma Karlovich, Ricardo Insausti, Timothy E. Richardson, Jamie M. Walker, Charles L. White, Bergan M. Babrowicz, Li Shen, Ann C. McKee, Thor D. Stein, Kurt Farrell, John F. Crary

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

1 Scopus citations

Abstract

Understanding age acceleration, the discordance between biological and chronological age, in the brain can reveal mechanistic insights into normal physiology as well as elucidate pathological determinants of age-related functional decline and identify early disease changes in the context of Alzheimer’s and other disorders. Histopathological whole slide images provide a wealth of pathologic data on the cellular level that can be leveraged to build deep learning models to assess age acceleration. Here, we used a collection of digitized human post-mortem hippocampal sections to develop a histological brain age estimation model. Our model predicted brain age within a mean absolute error of 5.45 ± 0.22 years, with attention weights corresponding to neuroanatomical regions vulnerable to age-related changes. We found that histopathologic brain age acceleration had significant associations with clinical and pathologic outcomes that were not found with epigenetic based measures. Our results indicate that histopathologic brain age is a powerful, independent metric for understanding factors that contribute to brain aging.

Original language	English (US)
Pages (from-to)	785-802
Number of pages	18
Journal	Acta Neuropathologica
Volume	146
Issue number	6
DOIs	https://doi.org/10.1007/s00401-023-02636-3
State	Published - Dec 2023
Externally published	Yes

Keywords

Aging
Biological clock
Digital pathology
Machine learning
Methylation

ASJC Scopus subject areas

Pathology and Forensic Medicine
Clinical Neurology
Cellular and Molecular Neuroscience

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10.1007/s00401-023-02636-3

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Marx, G. A., Kauffman, J., McKenzie, A. T., Koenigsberg, D. G., McMillan, C. T., Morgello, S., Karlovich, E., Insausti, R., Richardson, T. E., Walker, J. M., White, C. L., Babrowicz, B. M., Shen, L., McKee, A. C., Stein, T. D., Farrell, K., & Crary, J. F. (2023). Histopathologic brain age estimation via multiple instance learning. Acta Neuropathologica, 146(6), 785-802. https://doi.org/10.1007/s00401-023-02636-3

Marx, GA, Kauffman, J, McKenzie, AT, Koenigsberg, DG, McMillan, CT, Morgello, S, Karlovich, E, Insausti, R, Richardson, TE, Walker, JM, White, CL, Babrowicz, BM, Shen, L, McKee, AC, Stein, TD, Farrell, K & Crary, JF 2023, 'Histopathologic brain age estimation via multiple instance learning', Acta Neuropathologica, vol. 146, no. 6, pp. 785-802. https://doi.org/10.1007/s00401-023-02636-3

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abstract = "Understanding age acceleration, the discordance between biological and chronological age, in the brain can reveal mechanistic insights into normal physiology as well as elucidate pathological determinants of age-related functional decline and identify early disease changes in the context of Alzheimer{\textquoteright}s and other disorders. Histopathological whole slide images provide a wealth of pathologic data on the cellular level that can be leveraged to build deep learning models to assess age acceleration. Here, we used a collection of digitized human post-mortem hippocampal sections to develop a histological brain age estimation model. Our model predicted brain age within a mean absolute error of 5.45 ± 0.22 years, with attention weights corresponding to neuroanatomical regions vulnerable to age-related changes. We found that histopathologic brain age acceleration had significant associations with clinical and pathologic outcomes that were not found with epigenetic based measures. Our results indicate that histopathologic brain age is a powerful, independent metric for understanding factors that contribute to brain aging.",

keywords = "Aging, Biological clock, Digital pathology, Machine learning, Methylation",

author = "Marx, {Gabriel A.} and Justin Kauffman and McKenzie, {Andrew T.} and Koenigsberg, {Daniel G.} and McMillan, {Cory T.} and Susan Morgello and Esma Karlovich and Ricardo Insausti and Richardson, {Timothy E.} and Walker, {Jamie M.} and White, {Charles L.} and Babrowicz, {Bergan M.} and Li Shen and McKee, {Ann C.} and Stein, {Thor D.} and Kurt Farrell and Crary, {John F.}",

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doi = "10.1007/s00401-023-02636-3",

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AU - Kauffman, Justin

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AU - McMillan, Cory T.

AU - Morgello, Susan

AU - Karlovich, Esma

AU - Insausti, Ricardo

AU - Richardson, Timothy E.

AU - Walker, Jamie M.

AU - White, Charles L.

AU - Babrowicz, Bergan M.

AU - Shen, Li

AU - McKee, Ann C.

AU - Stein, Thor D.

AU - Farrell, Kurt

AU - Crary, John F.

PY - 2023/12

Y1 - 2023/12

N2 - Understanding age acceleration, the discordance between biological and chronological age, in the brain can reveal mechanistic insights into normal physiology as well as elucidate pathological determinants of age-related functional decline and identify early disease changes in the context of Alzheimer’s and other disorders. Histopathological whole slide images provide a wealth of pathologic data on the cellular level that can be leveraged to build deep learning models to assess age acceleration. Here, we used a collection of digitized human post-mortem hippocampal sections to develop a histological brain age estimation model. Our model predicted brain age within a mean absolute error of 5.45 ± 0.22 years, with attention weights corresponding to neuroanatomical regions vulnerable to age-related changes. We found that histopathologic brain age acceleration had significant associations with clinical and pathologic outcomes that were not found with epigenetic based measures. Our results indicate that histopathologic brain age is a powerful, independent metric for understanding factors that contribute to brain aging.

AB - Understanding age acceleration, the discordance between biological and chronological age, in the brain can reveal mechanistic insights into normal physiology as well as elucidate pathological determinants of age-related functional decline and identify early disease changes in the context of Alzheimer’s and other disorders. Histopathological whole slide images provide a wealth of pathologic data on the cellular level that can be leveraged to build deep learning models to assess age acceleration. Here, we used a collection of digitized human post-mortem hippocampal sections to develop a histological brain age estimation model. Our model predicted brain age within a mean absolute error of 5.45 ± 0.22 years, with attention weights corresponding to neuroanatomical regions vulnerable to age-related changes. We found that histopathologic brain age acceleration had significant associations with clinical and pathologic outcomes that were not found with epigenetic based measures. Our results indicate that histopathologic brain age is a powerful, independent metric for understanding factors that contribute to brain aging.

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Histopathologic brain age estimation via multiple instance learning

Abstract

Keywords

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