Abstract

Electronic portal imagers (EPIDs) with high detective quantum efficiencies (DQEs) are sought to facilitate the use of the megavoltage (MV) radiotherapy treatment beam for image guidance. Potential advantages include high quality (treatment) beam's eye view imaging, and improved cone-beam computed tomography (CBCT) generating images with more accurate electron density maps with immunity to metal artifacts. One approach to increasing detector sensitivity is to couple a thick pixelated scintillator array to an active matrix flat panel imager (AMFPI) incorporating amorphous silicon thin film electronics. Cadmium tungstate (CWO) has many desirable scintillation properties including good light output, a high index of refraction, high optical transparency, and reasonable cost. However, due to the 0 1 0 cleave plane inherent in its crystalline structure, the difficulty of cutting and polishing CWO has, in part, limited its study relative to other scintillators such as cesium iodide and bismuth germanate (BGO). The goal of this work was to build and test a focused large-area pixelated "strip" CWO detector. A 361 × 52 mm scintillator assembly that contained a total of 28 072 pixels was constructed. The assembly comprised seven subarrays, each 15 mm thick. Six of the subarrays were fabricated from CWO with a pixel pitch of 0.784 mm, while one array was constructed from BGO for comparison. Focusing was achieved by coupling the arrays to the Varian AS1000 AMFPI through a piecewise linear arc-shaped fiber optic plate. Simulation and experimental studies of modulation transfer function (MTF) and DQE were undertaken using a 6 MV beam, and comparisons were made between the performance of the pixelated strip assembly and the most common EPID configuration comprising a 1 mm-thick copper build-up plate attached to a 133 mg/cm(2) gadolinium oxysulfide scintillator screen (Cu-GOS). Projection radiographs and CBCT images of phantoms were acquired. The work also introduces the use of a lightweight edge phantom to generate MTF measurements at MV energies and shows its functional equivalence to the more cumbersome slit-based method. Measured and simulated DQE(0)'s of the pixelated CWO detector were 22% and 26%, respectively. The average measured and simulated ratios of CWO DQE(f) to Cu-GOS DQE(f) across the frequency range of 0.0-0.62 mm(-1) were 23 and 29, respectively. 2D and 3D imaging studies confirmed the large dose efficiency improvement and that focus was maintained across the field of view. In the CWO CBCT images, the measured spatial resolution was 7 lp/cm. The contrast-to-noise ratio was dramatically improved reflecting a 22 × sensitivity increase relative to Cu-GOS. The CWO scintillator material showed significantly higher stability and light yield than the BGO material. An efficient piecewise-focused pixelated strip scintillator for MV imaging is described that offers more than a 20-fold dose efficiency improvement over Cu-GOS.

Highlights

  • The low detective quantum efficiencies (DQEs) of electronic portal imagers (EPIDs) have limited their use for image-guided radiotherapy (IGRT) when good soft tissue contrast resolution is required

  • Note that the simulated and measured DQE( f )’s match very well in the horizontal direction while the measured vertical DQE( f ) is depressed somewhat, which may point to weaknesses in the array fabrication process

  • Optical cross talk may be the culprit since, after the second set of cutting and regluing operations, there remains a 7 μm glue layer that could allow for some cross talk in the direction of the first cut

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Summary

Introduction

The low detective quantum efficiencies (DQEs) of electronic portal imagers (EPIDs) have limited their use for image-guided radiotherapy (IGRT) when good soft tissue contrast resolution is required. Previous studies have shown that a DQE(0) of 20% is desired to achieve acceptable image quality at acceptably low doses.. 5085 Star-Lack et al.: Piecewise-focused high DQE MV imager a level of performance could be attained, some unique advantages may be conferred. These include high quality beam’s eye view imaging for intrafraction motion management, and metal artifact-free cone-beam computed tomography (CBCT) reconstructions of more accurate electron density for improved patient setup and treatment replanning.. These include high quality beam’s eye view imaging for intrafraction motion management, and metal artifact-free cone-beam computed tomography (CBCT) reconstructions of more accurate electron density for improved patient setup and treatment replanning. CBCT acquisition speeds and/or image quality could be increased by combining kV with high quality megavoltage (MV) data.

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