Deriving concentrations of oxygen and carbon in human tissues using single- and dual-energy CT for ion therapy applications.
about
A linear, separable two-parameter model for dual energy CT imaging of proton stopping power computation.Tissue decomposition from dual energy CT data for MC based dose calculation in particle therapyReview of 3D image data calibration for heterogeneity correction in proton therapy treatment planning.Vision 20/20: Positron emission tomography in radiation therapy planning, delivery, and monitoring.The potential of dual-energy CT to reduce proton beam range uncertainties.Monitoring proton therapy with PET.Site-specific range uncertainties caused by dose calculation algorithms for proton therapy.Experimental validation of two dual-energy CT methods for proton therapy using heterogeneous tissue samples.Europium-155 as a source for dual energy cone beam computed tomography in adaptive proton therapy: A simulation study.A model-based iterative reconstruction algorithm DIRA using patient-specific tissue classification via DECT for improved quantitative CT in dose planning.Technical Note: Relation between dual-energy subtraction of CT images for electron density calibration and virtual monochromatic imaging.Material Elemental Decomposition in Dual and Multi-energy CT via a Sparsity-Dictionary Approach for Proton Stopping Power Ratio Calculation.Comparison of proton therapy treatment planning for head tumors with a pencil beam algorithm on dual and single energy CT images.Initial implementation of the conversion from the energy-subtracted CT number to electron density in tissue inhomogeneity corrections: an anthropomorphic phantom study of radiotherapy treatment planning.Dosimetric comparison of stopping power calibration with dual-energy CT and single-energy CT in proton therapy treatment planning.
P2860
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P2860
Deriving concentrations of oxygen and carbon in human tissues using single- and dual-energy CT for ion therapy applications.
description
2013 nî lūn-bûn
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2013年の論文
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name
Deriving concentrations of oxy ...... for ion therapy applications.
@en
Deriving concentrations of oxy ...... for ion therapy applications.
@nl
type
label
Deriving concentrations of oxy ...... for ion therapy applications.
@en
Deriving concentrations of oxy ...... for ion therapy applications.
@nl
prefLabel
Deriving concentrations of oxy ...... for ion therapy applications.
@en
Deriving concentrations of oxy ...... for ion therapy applications.
@nl
P356
P1476
Deriving concentrations of oxy ...... T for ion therapy applications
@en
P2093
Guillaume Landry
Joachim E Wildberger
P304
P356
10.1088/0031-9155/58/15/5029
P577
2013-07-08T00:00:00Z