Project Abstract

Abstract
This research study aims to investigate and compare the image quality and radiation dose associated with digital radiography and computed radiography systems for pediatric patients. Radiography plays a crucial role in diagnosing medical conditions, and advancements in technology have led to the development of digital radiography systems that offer potential benefits over traditional computed radiography systems. However, concerns remain regarding radiation dose exposure, particularly in pediatric patients who are more sensitive to ionizing radiation. The research will commence with a comprehensive review of the literature to explore the existing knowledge and studies related to digital radiography and computed radiography systems in pediatric imaging. This review will cover topics such as the principles of digital and computed radiography, image quality parameters, radiation dose considerations, and the unique characteristics of pediatric patients in radiological imaging. Methodology for this research will involve a comparative analysis of image quality and radiation dose measurements obtained from digital radiography and computed radiography systems in a sample of pediatric patients. The study will utilize quantitative methods to objectively assess image quality parameters such as spatial resolution, contrast resolution, and noise levels. Radiation dose measurements will be recorded using dosimeters to quantify the amount of radiation exposure in each imaging modality. Findings from the research will be presented and discussed in detail, highlighting any significant differences in image quality and radiation dose between digital radiography and computed radiography systems for pediatric patients. The implications of these findings on clinical practice and patient care will be explored, considering factors such as diagnostic accuracy, patient safety, and overall efficiency in radiological imaging procedures. The significance of this research lies in its potential to inform healthcare professionals, radiographers, and policymakers about the comparative benefits and limitations of digital radiography and computed radiography systems in pediatric imaging. By enhancing our understanding of image quality and radiation dose considerations, this study aims to contribute valuable insights to the field of radiography and ultimately improve the quality of care for pediatric patients undergoing radiological examinations. In conclusion, this research project seeks to address the gap in knowledge regarding the performance of digital radiography versus computed radiography systems in pediatric imaging. By evaluating image quality and radiation dose metrics, this study aims to provide evidence-based recommendations for optimizing imaging protocols and enhancing patient safety in pediatric radiography.

Project Overview

The project titled "Comparison of image quality and radiation dose in digital radiography versus computed radiography systems for pediatric patients" aims to investigate and compare the performance of digital radiography (DR) and computed radiography (CR) systems in terms of image quality and radiation dose specifically for pediatric patients. Pediatric patients are a unique population group with distinctive anatomical characteristics and sensitivities to radiation exposure. Therefore, it is essential to evaluate and optimize imaging techniques to ensure accurate diagnoses while minimizing radiation risks in this vulnerable group. Digital radiography systems utilize digital detectors to capture X-ray images directly, offering advantages such as real-time image display, image manipulation, and reduced radiation exposure compared to traditional film-based systems. On the other hand, computed radiography systems use photostimulable phosphor plates to capture X-ray images, which are then processed digitally. This study will delve into the comparative analysis of image quality parameters, including spatial resolution, contrast resolution, and noise levels, between digital radiography and computed radiography systems when imaging pediatric patients. The research will also assess radiation dose metrics such as entrance skin dose and effective dose to determine which system provides optimal image quality at the lowest radiation exposure for pediatric imaging procedures. By conducting this research, valuable insights can be gained regarding the performance of DR and CR systems in pediatric radiography, aiding healthcare professionals in making informed decisions when selecting imaging modalities for pediatric patients. The findings of this study have the potential to contribute to the development of guidelines and protocols aimed at optimizing imaging practices for pediatric radiography, ultimately enhancing patient care and safety in pediatric radiology.