Reducing Metal Artifacts in Cone-beam CT Images by Preprocessing Projection Data

Overview

Journal Int J Radiat Oncol Biol Phys

Specialties Oncology
Radiology

Date 2006 Dec 13

PMID 17161556

Citations 63

Authors

Yongbin Zhang

Lifei Zhang

X Ronald Zhu

Andrew K Lee

Mark Chambers

Lei Dong

Affiliations

Soon will be listed here.

Abstract

Purpose: Computed tomography (CT) streak artifacts caused by metallic implants remain a challenge for the automatic processing of image data. The impact of metal artifacts in the soft-tissue region is magnified in cone-beam CT (CBCT), because the soft-tissue contrast is usually lower in CBCT images. The goal of this study was to develop an effective offline processing technique to minimize the effect.

Methods And Materials: The geometry calibration cue of the CBCT system was used to track the position of the metal object in projection views. The three-dimensional (3D) representation of the object can be established from only two user-selected viewing angles. The position of the shadowed region in other views can be tracked by projecting the 3D coordinates of the object. Automatic image segmentation was used followed by a Laplacian diffusion method to replace the pixels inside the metal object with the boundary pixels. The modified projection data were then used to reconstruct a new CBCT image. The procedure was tested in phantoms, prostate cancer patients with implanted gold markers and metal prosthesis, and a head-and-neck patient with dental amalgam in the teeth.

Results: Both phantom and patient studies demonstrated that the procedure was able to minimize the metal artifacts. Soft-tissue visibility was improved near or away from the metal object. The processing time was 1-2 s per projection.

Conclusion: We have implemented an effective metal artifact-suppressing algorithm to improve the quality of CBCT images.

Citing Articles

Comprehensive Image Quality Evaluation and Motion Phantom Studies of an Ultra-Fast (6-Second) Cone-Beam Computed Tomography Imaging System on a Ring Gantry Linear Accelerator.

Zhao H, Nelson G, Sarkar V, Oare C, Szegedi M, James S Adv Radiat Oncol. 2024; 10(2):101681.

PMID: 39717196 PMC: 11665466. DOI: 10.1016/j.adro.2024.101681.

Metal implant segmentation in CT images based on diffusion model.

Xie K, Gao L, Zhang Y, Zhang H, Sun J, Lin T BMC Med Imaging. 2024; 24(1):204.

PMID: 39107679 PMC: 11301972. DOI: 10.1186/s12880-024-01379-1.

Volumetric analysis of artifacts from fiducial markers under cone beam computed tomography.

Kuo H, Lin K, Hsu C, Fu P, Hung C, Song S J Dent Sci. 2024; 19(2):1004-1011.

PMID: 38618050 PMC: 11010787. DOI: 10.1016/j.jds.2023.07.001.

Evaluation of computed tomography metal artifact and CyberKnife fiducial recognition for novel size fiducial markers.

Nemoto H, Saito M, Suzuki T, Suzuki H, Sano N, Mochizuki Z J Appl Clin Med Phys. 2023; 24(12):e14142.

PMID: 37672211 PMC: 10691645. DOI: 10.1002/acm2.14142.

Effect of Mandible Phantom Inclination in the Axial Plane on Image Quality in the Presence of Implant Using Cone-Beam Computer Tomography.

Khurana S, Parasher P, Creanga A, Geha H Cureus. 2023; 15(3):e36630.

PMID: 37155440 PMC: 10122839. DOI: 10.7759/cureus.36630.