Machine Learning-based Dual-energy CT Parametric Mapping

Overview

Journal Phys Med Biol

Publisher IOP Publishing

Specialties Biophysics
Nuclear Medicine
Radiology

Date 2018 May 23

PMID 29787382

Citations 14

Authors

Kuan-Hao Su

Jung-Wen Kuo

David W Jordan

Steven van Hedent

Paul Klahr

Zhouping Wei

Rose Al Helo

Fan Liang

Pengjiang Qian

Gisele C Pereira

Negin Rassouli

Robert C Gilkeson

Bryan J Traughber

Chee-Wai Cheng

Raymond F Muzic

Affiliations

Soon will be listed here.

Abstract

The aim is to develop and evaluate machine learning methods for generating quantitative parametric maps of effective atomic number (Z), relative electron density (ρ ), mean excitation energy (I ), and relative stopping power (RSP) from clinical dual-energy CT data. The maps could be used for material identification and radiation dose calculation. Machine learning methods of historical centroid (HC), random forest (RF), and artificial neural networks (ANN) were used to learn the relationship between dual-energy CT input data and ideal output parametric maps calculated for phantoms from the known compositions of 13 tissue substitutes. After training and model selection steps, the machine learning predictors were used to generate parametric maps from independent phantom and patient input data. Precision and accuracy were evaluated using the ideal maps. This process was repeated for a range of exposure doses, and performance was compared to that of the clinically-used dual-energy, physics-based method which served as the reference. The machine learning methods generated more accurate and precise parametric maps than those obtained using the reference method. Their performance advantage was particularly evident when using data from the lowest exposure, one-fifth of a typical clinical abdomen CT acquisition. The RF method achieved the greatest accuracy. In comparison, the ANN method was only 1% less accurate but had much better computational efficiency than RF, being able to produce parametric maps in 15 s. Machine learning methods outperformed the reference method in terms of accuracy and noise tolerance when generating parametric maps, encouraging further exploration of the techniques. Among the methods we evaluated, ANN is the most suitable for clinical use due to its combination of accuracy, excellent low-noise performance, and computational efficiency.

Citing Articles

A dual-energy computed tomography-based radiomics nomogram for predicting time since stroke onset: a multicenter study.

Jiang J, Sheng K, Li M, Zhao H, Guan B, Dai L Eur Radiol. 2024; 34(11):7373-7385.

PMID: 38834786 DOI: 10.1007/s00330-024-10802-8.

MRI-only based material mass density and relative stopping power estimation via deep learning for proton therapy: a preliminary study.

Gao Y, Chang C, Mandava S, Marants R, Scholey J, Goette M Sci Rep. 2024; 14(1):11166.

PMID: 38750148 PMC: 11096170. DOI: 10.1038/s41598-024-61869-8.

Conversion of single-energy CT to parametric maps of dual-energy CT using convolutional neural network.

Kim S, Lee J, Kim J, Kim B, Choi C, Jung S Br J Radiol. 2024; 97(1158):1180-1190.

PMID: 38597871 PMC: 11135792. DOI: 10.1093/bjr/tqae076.

Systematic Review on Learning-based Spectral CT.

Bousse A, Kandarpa V, Rit S, Perelli A, Li M, Wang G IEEE Trans Radiat Plasma Med Sci. 2024; 8(2):113-137.

PMID: 38476981 PMC: 10927029. DOI: 10.1109/trpms.2023.3314131.

Single energy CT-based mass density and relative stopping power estimation for proton therapy using deep learning method.

Gao Y, Chang C, Roper J, Axente M, Lei Y, Pan S Front Oncol. 2023; 13:1278180.

PMID: 38074686 PMC: 10702508. DOI: 10.3389/fonc.2023.1278180.