Structural tract alterations predict downstream tau accumulation in amyloid-positive older individuals

Heidi I. L. Jacobs; Trey Hedden; Aaron P. Schultz; Jorge Sepulcre; Rodrigo D. Perea; Rebecca E. Amariglio; Kathryn V. Papp; Dorene M. Rentz; Reisa A. Sperling; Keith A. Johnson

doi:10.1038/s41593-018-0070-z

Structural tract alterations predict downstream tau accumulation in amyloid-positive older individuals

Heidi I. L. Jacobs^*, Trey Hedden, Aaron P. Schultz, Jorge Sepulcre, Rodrigo D. Perea, Rebecca E. Amariglio, Kathryn V. Papp, Dorene M. Rentz, Reisa A. Sperling, Keith A. Johnson

^*Corresponding author for this work

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

Abstract

Animal models of Alzheimer's disease have suggested that tau pathology propagation, facilitated by amyloid pathology, may occur along connected pathways. To investigate these ideas in humans, we combined amyloid scans with longitudinal data on white matter connectivity, hippocampal volume, tau positron emission tomography and memory performance in 256 cognitively healthy older individuals. Lower baseline hippocampal volume was associated with increased mean diffusivity of the connecting hippocampal cingulum bundle (HCB). HCB diffusivity predicted tau accumulation in the downstream-connected posterior cingulate cortex in amyloid-positive but not in amyloid-negative individuals. Furthermore, HCB diffusivity predicted memory decline in amyloid-positive individuals with high posterior cingulate cortex tau binding. Our results provide in vivo evidence that higher amyloid pathology strengthens the association between HCB diffusivity and tau accumulation in the downstream posterior cingulate cortex and facilitates memory decline. This confirms amyloid's crucial role in potentiating neural vulnerability and memory decline marking the onset of preclinical Alzheimer's disease.

Original language	English
Pages (from-to)	424–431
Number of pages	8
Journal	Nature Neuroscience
Volume	21
Issue number	3
DOIs	https://doi.org/10.1038/s41593-018-0070-z
Publication status	Published - 1 Mar 2018

Keywords

SURFACE-BASED ANALYSIS
PRECLINICAL ALZHEIMERS-DISEASE
CLINICALLY NORMAL INDIVIDUALS
WHITE-MATTER
IN-VIVO
FUNCTIONAL CONNECTIVITY
HUMAN BRAIN
RETROSPLENIAL CORTEX
NEURONAL DYSFUNCTION
PATHOLOGICAL PROCESS

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Cite this

@article{0d0a153679d948f9bf5e2a7a55cf3987,

title = "Structural tract alterations predict downstream tau accumulation in amyloid-positive older individuals",

abstract = "Animal models of Alzheimer's disease have suggested that tau pathology propagation, facilitated by amyloid pathology, may occur along connected pathways. To investigate these ideas in humans, we combined amyloid scans with longitudinal data on white matter connectivity, hippocampal volume, tau positron emission tomography and memory performance in 256 cognitively healthy older individuals. Lower baseline hippocampal volume was associated with increased mean diffusivity of the connecting hippocampal cingulum bundle (HCB). HCB diffusivity predicted tau accumulation in the downstream-connected posterior cingulate cortex in amyloid-positive but not in amyloid-negative individuals. Furthermore, HCB diffusivity predicted memory decline in amyloid-positive individuals with high posterior cingulate cortex tau binding. Our results provide in vivo evidence that higher amyloid pathology strengthens the association between HCB diffusivity and tau accumulation in the downstream posterior cingulate cortex and facilitates memory decline. This confirms amyloid's crucial role in potentiating neural vulnerability and memory decline marking the onset of preclinical Alzheimer's disease.",

keywords = "SURFACE-BASED ANALYSIS, PRECLINICAL ALZHEIMERS-DISEASE, CLINICALLY NORMAL INDIVIDUALS, WHITE-MATTER, IN-VIVO, FUNCTIONAL CONNECTIVITY, HUMAN BRAIN, RETROSPLENIAL CORTEX, NEURONAL DYSFUNCTION, PATHOLOGICAL PROCESS",

author = "Jacobs, {Heidi I. L.} and Trey Hedden and Schultz, {Aaron P.} and Jorge Sepulcre and Perea, {Rodrigo D.} and Amariglio, {Rebecca E.} and Papp, {Kathryn V.} and Rentz, {Dorene M.} and Sperling, {Reisa A.} and Johnson, {Keith A.}",

year = "2018",

month = mar,

day = "1",

doi = "10.1038/s41593-018-0070-z",

language = "English",

volume = "21",

pages = "424–431 ",

journal = "Nature Neuroscience",

issn = "1097-6256",

publisher = "Nature Publishing Group",

number = "3",

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T1 - Structural tract alterations predict downstream tau accumulation in amyloid-positive older individuals

AU - Jacobs, Heidi I. L.

AU - Hedden, Trey

AU - Schultz, Aaron P.

AU - Sepulcre, Jorge

AU - Perea, Rodrigo D.

AU - Amariglio, Rebecca E.

AU - Papp, Kathryn V.

AU - Rentz, Dorene M.

AU - Sperling, Reisa A.

AU - Johnson, Keith A.

PY - 2018/3/1

Y1 - 2018/3/1

N2 - Animal models of Alzheimer's disease have suggested that tau pathology propagation, facilitated by amyloid pathology, may occur along connected pathways. To investigate these ideas in humans, we combined amyloid scans with longitudinal data on white matter connectivity, hippocampal volume, tau positron emission tomography and memory performance in 256 cognitively healthy older individuals. Lower baseline hippocampal volume was associated with increased mean diffusivity of the connecting hippocampal cingulum bundle (HCB). HCB diffusivity predicted tau accumulation in the downstream-connected posterior cingulate cortex in amyloid-positive but not in amyloid-negative individuals. Furthermore, HCB diffusivity predicted memory decline in amyloid-positive individuals with high posterior cingulate cortex tau binding. Our results provide in vivo evidence that higher amyloid pathology strengthens the association between HCB diffusivity and tau accumulation in the downstream posterior cingulate cortex and facilitates memory decline. This confirms amyloid's crucial role in potentiating neural vulnerability and memory decline marking the onset of preclinical Alzheimer's disease.

AB - Animal models of Alzheimer's disease have suggested that tau pathology propagation, facilitated by amyloid pathology, may occur along connected pathways. To investigate these ideas in humans, we combined amyloid scans with longitudinal data on white matter connectivity, hippocampal volume, tau positron emission tomography and memory performance in 256 cognitively healthy older individuals. Lower baseline hippocampal volume was associated with increased mean diffusivity of the connecting hippocampal cingulum bundle (HCB). HCB diffusivity predicted tau accumulation in the downstream-connected posterior cingulate cortex in amyloid-positive but not in amyloid-negative individuals. Furthermore, HCB diffusivity predicted memory decline in amyloid-positive individuals with high posterior cingulate cortex tau binding. Our results provide in vivo evidence that higher amyloid pathology strengthens the association between HCB diffusivity and tau accumulation in the downstream posterior cingulate cortex and facilitates memory decline. This confirms amyloid's crucial role in potentiating neural vulnerability and memory decline marking the onset of preclinical Alzheimer's disease.

KW - SURFACE-BASED ANALYSIS

KW - PRECLINICAL ALZHEIMERS-DISEASE

KW - CLINICALLY NORMAL INDIVIDUALS

KW - WHITE-MATTER

KW - IN-VIVO

KW - FUNCTIONAL CONNECTIVITY

KW - HUMAN BRAIN

KW - RETROSPLENIAL CORTEX

KW - NEURONAL DYSFUNCTION

KW - PATHOLOGICAL PROCESS

U2 - 10.1038/s41593-018-0070-z

DO - 10.1038/s41593-018-0070-z

M3 - Article

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SN - 1097-6256

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JO - Nature Neuroscience

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