J.K. Van Abbema scite author profile

Radiotherapy and particle therapy treatment planning require accurate knowledge of the electron density and elemental composition of the tissues in the beam path to predict the local dose deposition. We describe a method for the analysis of dual energy computed tomography (DECT) images that provides the electron densities and effective atomic numbers of tissues. The CT measurement process is modelled by system weighting functions, which apply an energy dependent weighting to the parameterization of the total cross section for photon interactions with matter. This detailed parameterization is based on the theoretical analysis of Jackson and Hawkes and deviates, at most, 0.3% from the tabulated NIST values for the elements H to Zn. To account for beam hardening in the object as present in the CT image we implemented an iterative process employing a local weighting function, derived from the method proposed by Heismann and Balda. With this method effective atomic numbers between 1 and 30 can be determined. The method has been experimentally validated on a commercially available tissue characterization phantom with 16 inserts made of tissue substitutes and aluminium that has been scanned on a dual source CT system with tube potentials of 100 kV and 140 kV using a clinical scan protocol. Relative electron densities of all tissue substitutes have been determined with accuracy better than 1%. The presented DECT analysis method thus provides high accuracy electron densities and effective atomic numbers for radiotherapy and especially particle therapy treatment planning.

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Spectra of clinical CT scanners using a portable Compton spectrometer

Duisterwinkel

Abbema

Goethem

et al. 2015

Medical Physics

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Purpose:Spectral information of the output of x‐ray tubes in (dual source) computer tomography (CT) scanners can be used to improve the conversion of CT numbers to proton stopping power and can be used to advantage in CT scanner quality assurance. The purpose of this study is to design, validate, and apply a compact portable Compton spectrometer that was constructed to accurately measure x‐ray spectra of CT scanners.Methods:In the design of the Compton spectrometer, the shielding materials were carefully chosen and positioned to reduce background by x‐ray fluorescence from the materials used. The spectrum of Compton scattered x‐rays alters from the original source spectrum due to various physical processes. Reconstruction of the original x‐ray spectrum from the Compton scattered spectrum is based on Monte Carlo simulations of the processes involved. This reconstruction is validated by comparing directly and indirectly measured spectra of a mobile x‐ray tube. The Compton spectrometer is assessed in a clinical setting by measuring x‐ray spectra at various tube voltages of three different medical CT scanner x‐ray tubes.Results:The directly and indirectly measured spectra are in good agreement (their ratio being 0.99) thereby validating the reconstruction method. The measured spectra of the medical CT scanners are consistent with theoretical spectra and spectra obtained from the x‐ray tube manufacturer.Conclusions:A Compton spectrometer has been successfully designed, constructed, validated, and applied in the measurement of x‐ray spectra of CT scanners. These measurements show that our compact Compton spectrometer can be rapidly set‐up using the alignment lasers of the CT scanner, thereby enabling its use in commissioning, troubleshooting, and, e.g., annual performance check‐ups of CT scanners.

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Feasibility and accuracy of tissue characterization with dual source computed tomography

et al. 2012

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High accuracy proton relative stopping power measurement

Abbema

Goethem

Mulder

et al. 2018

Nuclear Instruments and Methods in Physics Research Section B:

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PO-0871: Relative electron density determination for radiotherapy and proton therapy treatment planning

Abbema¹,

Goethem²,

Greuter³

et al. 2015

Radiotherapy and Oncology

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J.K. Van Abbema

Relative electron density determination using a physics based parameterization of photon interactions in medical DECT

Spectra of clinical CT scanners using a portable Compton spectrometer

Feasibility and accuracy of tissue characterization with dual source computed tomography

High accuracy proton relative stopping power measurement

PO-0871: Relative electron density determination for radiotherapy and proton therapy treatment planning

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