Abstract
Spectroscopic x-ray imaging based on pixellated semiconductor detectors can be sensitive to charge sharing and K-fluorescence, depending on the sensor material used, its thickness and the pixel pitch employed. As a consequence, spectroscopic resolution is partially lost. In this paper, we study a new detector ASIC, the Medipix3RX, that offers a novel feature called charge summing, which is established by making adjacent pixels communicate with each other. Consequently, single photon interactions resulting in multiple hits are almost completely avoided. We investigate this charge summing mode with respect to those of its imaging properties that are of interest in medical physics and benchmark them against the case without charge summing. In particular, we review its influence on spectroscopic resolution and find that the low energy bias normally present when recording energy spectra is dramatically reduced. Furthermore, we show that charge summing provides a modulation transfer function which is almost independent of the energy threshold setting, which is in contrast to approaches common so far. We demonstrate that this property is directly linked to the detective quantum efficiency, which is found to increase by a factor of three or more when the energy threshold approaches the photon energy and when using charge summing. As a consequence, the contrast-to-noise ratio is found to double at elevated threshold levels and the dynamic range increases for a given counter depth. All these effects are shown to lead to an improved ability to perform material discrimination in spectroscopic CT, using iodine and gadolinium contrast agents. Hence, when compared to conventional photon counting detectors, these benefits carry the potential of substantially reducing the imaging dose a patient is exposed to during diagnostic CT examinations.
Highlights
Today, most x-ray imaging modalities rely on detectors that make use of the indirect detection of photons
We have investigated a method called charge summing with the aim to improve both regular as well as material contrast in spectroscopic computed tomography (CT)
While all the benefits of charge summing that we reported are due to the improved spectroscopic performance, some have implications that go beyond energy response
Summary
Most x-ray imaging modalities rely on detectors that make use of the indirect detection of photons. Based on scintillators, which first convert the absorbed x-ray flux into visible light, a digital signal is obtained that is proportional to the total amount of energy deposited during exposure. These indirect conversion devices are a proven and robust technology and are widely used in fields such as materials research as well as preclinical and medical imaging. By means of a high voltage applied to the sensor, the resulting photocurrent can be measured in some form of readout electronics attached to one of the sensor sides, which can, for instance, be made of amorphous selenium (Pang et al 2001). Integrating this current over time again gives the total amount of energy deposited in a pixel, but does not require the intermediate step of a scintillator
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