A volumetric model‐based 2D to 3D registration method for measuring kinematics of natural knees with single‐plane fluoroscopy
Author(s) -
Tsai TsungYuan,
Lu TungWu,
Chen ChungMing,
Kuo MeiYing,
Hsu HorngChaung
Publication year - 2010
Publication title -
medical physics
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 1.473
H-Index - 180
eISSN - 2473-4209
pISSN - 0094-2405
DOI - 10.1118/1.3301596
Subject(s) - fluoroscopy , kinematics , cadaveric spasm , translation (biology) , computer science , computer vision , image registration , artificial intelligence , biomedical engineering , medicine , physics , radiology , image (mathematics) , surgery , biochemistry , chemistry , classical mechanics , messenger rna , gene
Purpose: Accurate measurement of the three‐dimensional (3D) rigid body and surface kinematics of the natural human knee is essential for many clinical applications. Existing techniques are limited either in their accuracy or lack more realistic experimental evaluation of the measurement errors. The purposes of the study were to develop a volumetric model‐based 2D to 3D registration method, called the weighted edge‐matching score (WEMS) method, for measuring natural knee kinematics with single‐plane fluoroscopy to determine experimentally the measurement errors and to compare its performance with that of pattern intensity (PI) and gradient difference (GD) methods. Methods: The WEMS method gives higher priority to matching of longer edges of the digitally reconstructed radiograph and fluoroscopic images. The measurement errors of the methods were evaluated based on a human cadaveric knee at 11 flexion positions. Results: The accuracy of the WEMS method was determined experimentally to be less than 0.77 mm for the in‐plane translations, 3.06 mm for out‐of‐plane translation, and 1.13° for all rotations, which is better than that of the PI and GD methods. Conclusions: A new volumetric model‐based 2D to 3D registration method has been developed for measuring 3D in vivo kinematics of natural knee joints with single‐plane fluoroscopy. With the equipment used in the current study, the accuracy of the WEMS method is considered acceptable for the measurement of the 3D kinematics of the natural knee in clinical applications.