A Novel Three-Dimensional Vector Analysis of Axial Globe Position in Thyroid Eye Disease

Overview

Journal J Ophthalmol

Publisher Wiley

Specialty Ophthalmology

Date 2017 May 12

PMID 28491471

Citations 1

Authors

Jie Guo

Jiang Qian

Yifei Yuan

Rui Zhang

Wenhu Huang

Affiliations

Soon will be listed here.

Abstract

. To define a three-dimensional (3D) vector method to describe the axial globe position in thyroid eye disease (TED). . CT data from 59 patients with TED were collected and 3D images were reconstructed. A reference coordinate system was established, and the coordinates of the corneal apex and the eyeball center were calculated to obtain the globe vector [Formula: see text]. The measurement reliability was evaluated. The parameters of [Formula: see text] were analyzed and compared with the results of two-dimensional (2D) CT measurement, Hertel exophthalmometry, and strabismus tests. . The reliability of [Formula: see text] measurement was excellent. The difference between [Formula: see text] and 2D CT measurement was significant ( = 0.003), and [Formula: see text] was more consistent with Hertel exophthalmometry than with 2D CT measurement ( < 0.001). There was no significant difference between [Formula: see text] and Hirschberg test, and a strong correlation was found between [Formula: see text] and synoptophore test. When one eye had a larger deviation angle than its fellow, its corneal apex shifted in the corresponding direction, but the shift of the eyeball center was not significant. The parameters of [Formula: see text] were almost perfectly consistent with the geometrical equation. . The establishment of a 3D globe vector is feasible and reliable, and it could provide more information in the axial globe position.

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