Cerebrospinal fluid biomarkers of neurofibrillary tangles and synaptic dysfunction
are associated with longitudinal decline in white matter connectivity: A multi-resolution graph analysis
[NeuroImage: Clinical]
Abstract. In addition to the development of beta amyloid plaques and neurofibrillary tangles,
Alzheimer's disease (AD) involves the loss of connecting structures including degeneration of myelinated axons
and synaptic connections. However, the extent to which white matter tracts change longitudinally, particularly
in the asymptomatic, preclinical stage of AD, remains poorly characterized. In this study we used a novel
graph wavelet algorithm to determine the extent to which microstructural brain changes evolve in concert with
the development of AD neuropathology as observed using CSF biomarkers. A total of 118 participants with at
least two diffusion tensor imaging (DTI) scans and one lumbar puncture for CSF were selected from two observational
and longitudinally followed cohorts. CSF was assayed for pathology specific to AD (AB42 and phosphorylated-tau),
neurodegeneration (total-tau), axonal degeneration (neurofilament light chain protein; NFL), and synaptic degeneration
(neurogranin). Tractography was performed on DTI scans to obtain structural connectivity networks with 160 nodes where
the nodes correspond to specific brain regions of interest (ROIs) and their connections were defined by DTI metrics
(i.e., fractional anisotropy (FA) and mean diffusivity (MD)). For the analysis, we adopted a multi-resolution graph
wavelet technique called Wavelet Connectivity Signature (WaCS) which derives higher order representations from DTI
metrics at each brain connection. Our statistical analysis showed interactions between the CSF measures and the MRI time interval,
such that elevated CSF biomarkers and longer time were associated with greater longitudinal changes in white matter
microstructure (decreasing FA and increasing MD). Specifically, we detected a total of 17 fiber tracts whose WaCS
representations showed an association between longitudinal decline in white matter microstructure and both CSF p-tau
and neurogranin. While development of neurofibrillary tangles and synaptic degeneration are cortical phenomena, the
results show that they are also associated with degeneration of underlying white matter tracts, a process which may
eventually play a role in the development of cognitive decline and dementia.
Figure 1: Visualization of identified brain connections whose longitudinal MD changes are dependent on p-tau (i.e. ptau x change in Time).
Top: visualization of tractography generated tracts from the identified connectivity where the tracts in the same color belong to the same
connectivity, Bottom: lines representing the identified connections with thickness corresponding to the p-values, where thicker line corresponds
to lower p-value and ROI indices. Left: top view, Middle: left view, Right: right view.
Figure 2: Visualization of identified brain connections whose longitudinal MD changes are dependent on
neurogranin (i.e., neurogranin x change in Time). Top: visualization of tractography generated tracts from the identified
connectivity where the tracts in the same color belong to the same connectivity, Bottom: lines representing the
identified connections with thickness corresponding to the p-values. Thicker line corresponds to lower p-value.
Left: top view, Middle: left view, Right: right view.
Figure 3: Visualization of the identified brain connections whose longitudinal FA changes are dependent
on neurogranin (i.e., neurogranin x change in Time). Top: visualization of tractography generated tracts from the identified
connectivity where the tracts in the same color belong to the same connectivity, Bottom: lines representing the identified
connections with thickness corresponding to the p-values. Thicker line corresponds to lower p-value. Left: top view, Middle: left view, Right: right view.
References:
[1] Won Hwa Kim, Annie M. Racine, Nagesh Adluru, Seong Jae Hwang, Kaj Blennow, Henrik Zetterberg, Cyhthia M. Carlsson, Sanjay Asthana, Rebecca L. Koscik, Sterling C. Johnson, Barbara B. Bendlin, Vikas Singh,
"Cerebrospinal fluid biomarkers of neurofibrillary tangles and synaptic dysfunction are associated with longitudinal decline in white matter connectivity: A multi-resolution graph analysis",
NeuroImage: Clinical, 2018.
[NeuroImage: Clinical]
Acknowledgment:
This research was supported by the National Institutes of Health (R01AG040396, R01AG037639,
R01AG021155, R01AG027161, P50AG033514), by a Clinical and Translational Science Award (UL1RR025011)
to the University of Wisconsin, Madison, the Center for Predictive Computational Phenotyping;
and by the Swedish Research Council, the Swedish Brain Foundation, the Knut and Alice Wallenberg
Foundation, and Torsten Söderberg's Foundation to the University of Gothenburg. Portions of this
research were supported by a NSF CAREER Award to Singh and the Veterans Administration including
facilities and resources at the Geriatric Research Education and Clinical Center of the William S. Middleton Memorial Veterans Hospital, Madison, WI.