Cadmium Zinc Telluride (CZT) photon counting detector Characterisation for soft tissue imaging

TL;DR

This study characterizes the performance of Cadmium Zinc Telluride (CZT) photon counting detectors for soft tissue imaging, demonstrating their high sensitivity, linearity, and optimal operational parameters for improved CT imaging applications.

Contribution

The paper provides a detailed characterization of CZT photon counting detectors, including optimal frame rate, energy thresholds, and their response to various tissue types and thicknesses.

Findings

Optimal FPS of 12 determined for spectral response.

Count per second (CPS) linearly related to X-ray tube current.

Detector sensitivity and linearity suitable for medical imaging.

Abstract

The use of photon counting detection technology has resulted in significant X-ray imaging research interest in recent years. Computed Tomography (CT) scanners can benefit from photon-counting detectors, which are new technology with the potential to overcome key limitations of conventional CT detectors. Researchers are still studying the effectiveness and sensitivity of semiconductor detector materials in photon counting detectors for detecting soft tissue contrasts. This study aimed to characterize the performance of the Cadmium Zinc Telluride photon counting detector in identifying various tissues. An optimal frame rate per second (FPS) of CZT detector was evaluated by setting the X-ray tube voltage and current at 25 keV, 35 keV and 0.5 mA, 1.0 mA respectively by keeping the optimum FPS fixed, the detector energy thresholds were set in small steps from 15 keV to 35 keV and the Currents were set for X-ray tubes in ranges of 0.1 mA to 1.0 mA to find the relationship between voltage and current of the X-ray source and counts per second (CPS). The samples i.e., fat, liver, muscles, paraffin wax, and contrast media were stacked at six different thickness levels in a stair-step chamber made from Plexi-glass. X-ray transmission at six different thicknesses of tissue samples was also examined for five different energy (regions) thresholds (21 keV, 25 keV, 29 keV, 31 keV, and 45 keV) to determine the effect on count per second (CPS). In this study, 12 frames per second is found to be the optimum frame rate per second (FPS) based on the spectral response of an X-ray source and CPS has a linear relationship with X-ray tube current as well. It was also noted that A sample's thickness also affects its X-ray transmission at different energy thresholds. A high sensitivity and linearity of the detectors make them suitable for use in both preclinical and medical applications.