RT Journal Article
SR Electronic
T1 Quantifying Differences and Similarities in Whole-brain White Matter Architecture Using Local Connectome Fingerprints
JF bioRxiv
FD Cold Spring Harbor Laboratory
SP 043778
DO 10.1101/043778
A1 Fang-Cheng Yeh
A1 Jean M. Vettel
A1 Aarti Singh
A1 Barnabas Poczos
A1 Scott Grafton
A1 Kirk I. Erickson
A1 Wen-Yih I. Tseng
A1 Timothy D. Verstynen
YR 2016
UL http://biorxiv.org/content/early/2016/08/31/043778.abstract
AB Quantifying differences or similarities in connectomes has been a challenge due to the immense complexity of global brain networks. Here we introduce a noninvasive method that uses diffusion MRI to characterize whole-brain white matter architecture as a single local connectome fingerprint that allows for a direct comparison between structural connectomes. In four independently acquired data sets with repeated scans (total N=213), we show that the local connectome fingerprint is highly specific to an individual, allowing for an accurate self-versus-others classification that achieved 100% accuracy across 17,398 identification tests. The estimated classification error was approximately one thousand times smaller than fingerprints derived from diffusivity-based measures or region-to-region connectivity patterns. The local connectome fingerprint also revealed neuroplasticity within an individual reflected as a decreasing trend in self-similarity across time, whereas this change was not observed in the diffusivity measures. Moreover, the local connectome fingerprint can be used as a phenotypic marker, revealing 12.51% similarity between monozygotic twins, 5.14% between dizygotic twins, and 4.51% between none-twin siblings. This novel approach opens a new door for probing the influence of pathological, genetic, social, or environmental factors on the unique configuration of the human connectome.Author Summary The local organization of white matter architecture is highly unique to individuals, making it a tangible metric of connectomic differences. The variability in local white matter architecture is found to be partially determined by genetic factors, but largely plastic across time. This approach opens a new door for probing the influence of pathological, genetic, social, or environmental factors on the unique configuration of the human connectome.