Evaluation of Radiation Dose Reduction during CT Scans Using Oxide Bismuth and Nano-Barium Sulfate Shields

TL;DR

This study evaluates a new fiber sheet shield combining nano-barium sulfate and bismuth oxide for CT scans, demonstrating significant radiation dose reduction while maintaining image quality and offering a thinner, potentially more effective shielding alternative.

Contribution

Introduces a novel dose reduction fiber sheet (DRFS) combining nano-barium sulfate with bismuth oxide, achieving greater radiation dose reduction and thinner design compared to conventional bismuth shields.

Findings

DRFS reduces radiation dose by up to 23% at various kVp settings.

DRFS maintains comparable image quality to conventional shields.

DRFS is approximately 25% thinner than traditional bismuth shields.

Abstract

The purpose of the present study was to evaluate radiation dose reduction and image quality during CT scanning by using a new dose reduction fiber sheet (DRFS) with commercially available bismuth shields. These DRFS were composed of nano-barium sulfate (BaSO4), filling the gaps left by the large oxide bismuth (Bi2O3) particle sizes. The radiation dose was measured five times at directionss of 12 o'clock from the center of the polymethyl methacrylate (PMMA) head phantom to calculate an average value using a CT ionization chamber. The image quality measured CT transverse images of the PMMA head phantom depending on X-ray tube voltages and the type of shielding. Two regions of interest in CT transverse images were chosen from the right and left areas under the surface of the PMMA head phantom and from ion chamber holes located at directions of 12 o'clock from the center of the PMMA head phantom. The results of this study showed that the new DRFS shields could reduce dosages to 15.61%, 23.05%, and 22.71% more in 90 kVp, 120 kVp, and 140 kVp, respectively, than with a conventional bismuth shield of the same thickness, while maintaining image quality. In addition, the DRFS were produced to about 25% more thinness than conventional bismuth. We concluded, therefore, that DRFS can replace the conventional bismuth and may be utilized as a new shield.