Neuroimage Signature from Salient Keypoints is Highly Specific to Individuals and Shared by Close Relatives

Overview

Journal Neuroimage

Specialty Radiology

Date 2019 Sep 24

PMID 31546048

Citations 2

Authors

Laurent Chauvin

Kuldeep Kumar

Christian Wachinger

Marc Vangel

Jacques De Guise

Christian Desrosiers

William Wells

Matthew Toews

Affiliations

Soon will be listed here.

Abstract

Neuroimaging studies typically adopt a common feature space for all data, which may obscure aspects of neuroanatomy only observable in subsets of a population, e.g. cortical folding patterns unique to individuals or shared by close relatives. Here, we propose to model individual variability using a distinctive keypoint signature: a set of unique, localized patterns, detected automatically in each image by a generic saliency operator. The similarity of an image pair is then quantified by the proportion of keypoints they share using a novel Jaccard-like measure of set overlap. Experiments demonstrate the keypoint method to be highly efficient and accurate, using a set of 7536 T1-weighted MRIs pooled from four public neuroimaging repositories, including twins, non-twin siblings, and 3334 unique subjects. All same-subject image pairs are identified by a similarity threshold despite confounds including aging and neurodegenerative disease progression. Outliers reveal previously unknown data labeling inconsistencies, demonstrating the usefulness of the keypoint signature as a computational tool for curating large neuroimage datasets.

Citing Articles

Temporal Interactions between Maintenance of Cerebral Cortex Thickness and Physical Activity from an Individual Person Micro-Longitudinal Perspective and Implications for Precision Medicine.

Wall J, Xie H, Wang X J Pers Med. 2024; 14(2).

PMID: 38392561 PMC: 10890462. DOI: 10.3390/jpm14020127.

Efficient Pairwise Neuroimage Analysis Using the Soft Jaccard Index and 3D Keypoint Sets.

Chauvin L, Kumar K, Desrosiers C, Wells W, Toews M IEEE Trans Med Imaging. 2021; 41(4):836-845.

PMID: 34699353 PMC: 9022638. DOI: 10.1109/TMI.2021.3123252.

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