The effect of tissue inhomogeneities on the accuracy of proton path reconstruction for proton computed tomography

Kent Wong; Bela Erdelyi; Reinhard Schulte; Vladimir Bashkirov; George Coutrakon; Hartmut Sadrozinski; Scott Penfold; Anatoly Rosenfeld

doi:10.1063/1.3120078

The effect of tissue inhomogeneities on the accuracy of proton path reconstruction for proton computed tomography

Kent Wong, Bela Erdelyi, Reinhard Schulte, Vladimir Bashkirov, George Coutrakon, Hartmut Sadrozinski, Scott Penfold, Anatoly Rosenfeld

Research output: Contribution to journal › Conference article › peer-review

Abstract

Maintaining a high degree of spatial resolution in proton computed tomography (pCT) is a challenge due to the statistical nature of the proton path through the object. Recent work has focused on the formulation of the most likely path (MLP) of protons through a homogeneous water object and the accuracy of this approach has been tested experimentally with a homogeneous PMMA phantom. Inhomogeneities inside the phantom, consisting of, for example, air and bone will lead to unavoidable inaccuracies of this approach. The purpose of this ongoing work is to characterize systematic errors that are introduced by regions of bone and air density and how this affects the accuracy of proton CT in surrounding voxels both in terms of spatial and density reconstruction accuracy. Phantoms containing tissue- equivalent inhomogeneities have been designed and proton transport through them has been simulated with the GEANT 4.9.0 Monte Carlo tool kit. Various iterative reconstruction techniques, including the classical fully sequential algebraic reconstruction technique (ART) and block-iterative techniques, are currently being tested, and we will select the most accurate method for this study.

Original language	English
Pages (from-to)	476-480
Number of pages	5
Journal	AIP Conference Proceedings
Volume	1099
DOIs	https://doi.org/10.1063/1.3120078
State	Published - 2009
Event	20th International Conference on the Application of Accelerators in Research and Industry, CAARI 2008 - Fort Worth, TX, United States Duration: Aug 10 2008 → Aug 15 2008

ASJC Scopus Subject Areas

General Physics and Astronomy

Keywords

GEANT4 simulation
Proton computed tomography
Proton path simulation

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abstract = "Maintaining a high degree of spatial resolution in proton computed tomography (pCT) is a challenge due to the statistical nature of the proton path through the object. Recent work has focused on the formulation of the most likely path (MLP) of protons through a homogeneous water object and the accuracy of this approach has been tested experimentally with a homogeneous PMMA phantom. Inhomogeneities inside the phantom, consisting of, for example, air and bone will lead to unavoidable inaccuracies of this approach. The purpose of this ongoing work is to characterize systematic errors that are introduced by regions of bone and air density and how this affects the accuracy of proton CT in surrounding voxels both in terms of spatial and density reconstruction accuracy. Phantoms containing tissue- equivalent inhomogeneities have been designed and proton transport through them has been simulated with the GEANT 4.9.0 Monte Carlo tool kit. Various iterative reconstruction techniques, including the classical fully sequential algebraic reconstruction technique (ART) and block-iterative techniques, are currently being tested, and we will select the most accurate method for this study.",

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note = "The Effect of Tissue Inhomogeneities on the Accuracy of Proton Path Reconstruction for Proton Computed Tomography; 20th International Conference on the Application of Accelerators in Research and Industry, CAARI 2008 ; Conference date: 10-08-2008 Through 15-08-2008",

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AU - Erdelyi, Bela

AU - Schulte, Reinhard

AU - Bashkirov, Vladimir

AU - Coutrakon, George

AU - Sadrozinski, Hartmut

AU - Penfold, Scott

AU - Rosenfeld, Anatoly

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N2 - Maintaining a high degree of spatial resolution in proton computed tomography (pCT) is a challenge due to the statistical nature of the proton path through the object. Recent work has focused on the formulation of the most likely path (MLP) of protons through a homogeneous water object and the accuracy of this approach has been tested experimentally with a homogeneous PMMA phantom. Inhomogeneities inside the phantom, consisting of, for example, air and bone will lead to unavoidable inaccuracies of this approach. The purpose of this ongoing work is to characterize systematic errors that are introduced by regions of bone and air density and how this affects the accuracy of proton CT in surrounding voxels both in terms of spatial and density reconstruction accuracy. Phantoms containing tissue- equivalent inhomogeneities have been designed and proton transport through them has been simulated with the GEANT 4.9.0 Monte Carlo tool kit. Various iterative reconstruction techniques, including the classical fully sequential algebraic reconstruction technique (ART) and block-iterative techniques, are currently being tested, and we will select the most accurate method for this study.

AB - Maintaining a high degree of spatial resolution in proton computed tomography (pCT) is a challenge due to the statistical nature of the proton path through the object. Recent work has focused on the formulation of the most likely path (MLP) of protons through a homogeneous water object and the accuracy of this approach has been tested experimentally with a homogeneous PMMA phantom. Inhomogeneities inside the phantom, consisting of, for example, air and bone will lead to unavoidable inaccuracies of this approach. The purpose of this ongoing work is to characterize systematic errors that are introduced by regions of bone and air density and how this affects the accuracy of proton CT in surrounding voxels both in terms of spatial and density reconstruction accuracy. Phantoms containing tissue- equivalent inhomogeneities have been designed and proton transport through them has been simulated with the GEANT 4.9.0 Monte Carlo tool kit. Various iterative reconstruction techniques, including the classical fully sequential algebraic reconstruction technique (ART) and block-iterative techniques, are currently being tested, and we will select the most accurate method for this study.

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KW - Proton computed tomography

KW - Proton path simulation

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The effect of tissue inhomogeneities on the accuracy of proton path reconstruction for proton computed tomography

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ASJC Scopus Subject Areas

Keywords

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