Digital Radiography Reject Analysis: Data Collection Methodology, Results, and Recommendations from an In-depth Investigation at Two Hospitals

Foos, David H.; Sehnert, William J.; Reiner, Bruce I.; Siegel, Eliot L.; Segal, Arthur J.; Waldman, David L.

doi:10.1007/s10278-008-9112-5

Cited by 57 publications

(102 citation statements)

References 2 publications

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“…Reject rates, which are defined as the total number of rejected images divided by the total number of images acquired over an established time period, are used by most clinical sites as an integral component of an overall QA program. Reject rates for sites using digital radiography systems are reported to range between 3 % and 10 % [2][3][4].…”

Section: Introductionmentioning

confidence: 99%

Investigation of the Variability in the Assessment of Digital Chest X-ray Image Quality

et al. 2012

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A large database of digital chest radiographs was developed over a 14-month period. Ten radiographic technologists and five radiologists independently evaluated a stratified subset of images from the database for quality deficiencies and decided whether each image should be rejected. The evaluation results showed that the radiographic technologists and radiologists agreed only moderately in their assessments. When compared against each other, radiologist and technologist reader groups were found to have even less agreement than the inter-reader agreement within each group. Radiologists were found to be more accepting of limitedquality studies than technologists. Evidence from the study suggests that the technologists weighted their reject decisions more heavily on objective technical attributes, while the radiologists weighted their decisions more heavily on diagnostic interpretability relative to the image indication. A suite of reject-detection algorithms was independently run on the images in the database. The algorithms detected 4 % of postero-anterior chest exams that were accepted by the technologist who originally captured the image but which would have been rejected by the technologist peer group. When algorithm results were made available to the technologists during the study, there was no improvement in inter-reader agreement in deciding whether to reject an image. The algorithm results do, however, provide new quality information that could be captured within a site-wide, reject-tracking database and leveraged as part of a site-wide QA program.

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Section: Introductionmentioning

confidence: 99%

Investigation of the Variability in the Assessment of Digital Chest X-ray Image Quality

et al. 2012

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“…However, this retakes alone may not indicate overall improved image quality and optimal radiation dose. An acceptable level of contrast and brightness can be obtained through post-processing, even with a noisy image (Foos et al, 2009). It has been proposed that the two biggest quality errors in computed radiography (CR) are related to poor positioning and noisy images.…”

Section: Discussionmentioning

confidence: 99%

“…However, Wu et al (2008), found that retakes with CR were similar to conventional filmscreen techniques; tumours ignored were sized 10-32mm, and 63% of the tumours were carcinomas. A reject analysis of 288.000 CR image records was published by Foos et al, 2009. Of these images collected from two large hospitals whereas chest exams were the most frequently performed examination at both institutions; positioning errors and anatomy cut-offs, followed by improper exposure were reasons for the most frequently occurring overall rejects.…”

Section: Errors In Film-screen Chest Radiographymentioning

confidence: 99%

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Sharpness and noise in digital chest radiographs, assessed by visual rating

Ween

Jakobsen

2015

RadOpen

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Missed lung lesions are one of the most frequent causes of malpractice issues, caused by several reasons; among them suboptimal radiography. When radiographers interpret acquired images of a patient, an acceptance or rejection must be decided. When a retake is required, radiographers need to know how to improve the image quality. Improvements in image quality properties as contrast, sharpness and noise often lead to improved perception, which in turn should enable more information to the observer and also allow computer-assisted detection (CAD) to be more successful. Our aim was to create a scoring system of the principal limiting factors sharpness and noise, in a clinical setting, and to determine whether it is possible to agree on image quality on digital chest radiographs. To enable a variation in rating due to body habits, a three-graded scale for each of sharpness and noise were created. Five different anatomical landmarks in each of patients having body sizes lean, normal and large were evaluated by 27 radiographers; totally 810 scores were given. The results showed a high inter-observer agreement with respect to rating grades of both sharpness and noise, independent of projection, anatomical landmark and body habits. The present study is a first step in the development of a scale for assessing sharpness and noise in digital chest radiography. The method of quality assessment might become more valid with increased use. We propose that this study can be followed up by a systematic mentor-guided training program that links perception of image quality to feedback about the image retake decisions if required.

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“…The ability to identify outliers in practice allows for targeted interventions. There are examples of QC programs using automated collection methods to identify trends in computed tomography (CT), 14 , 15 and in CR tracking rejects and exposure levels over time 16 , 17 , 18 , 19 . AAPM Task Group 151 (6) discusses the appropriate quality assurance elements in a digital radiography program, including analysis of exposure levels.…”

Section: Introductionmentioning

confidence: 99%

Evaluation of digital radiography practice using exposure index tracking

Scott

Zhou

Allahverdian

et al. 2016

J Applied Clin Med Phys

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Some digital radiography (DR) detectors and software allow for remote download of exam statistics, including image reject status, body part, projection, and exposure index (EI). The ability to have automated data collection from multiple DR units is conducive to a quality control (QC) program monitoring institutional radiographic exposures. We have implemented such a QC program with the goal to identify outliers in machine radiation output and opportunities for improvement in radiation dose levels. We studied the QC records of four digital detectors in greater detail on a monthly basis for one year. Although individual patient entrance skin exposure varied, the radiation dose levels to the detectors were made to be consistent via phototimer recalibration. The exposure data stored on each digital detector were periodically downloaded in a spreadsheet format for analysis. EI median and standard deviation were calculated for each protocol (by body part) and EI histograms were created for torso protocols. When histograms of EI values for different units were compared, we observed differences up to 400 in average EI (representing 60% difference in radiation levels to the detector) between units nominally calibrated to the same EI. We identified distinct components of the EI distributions, which in some cases, had mean EI values 300 apart. Peaks were observed at the current calibrated EI, a previously calibrated EI, and an EI representing computed radiography (CR) techniques. Our findings in this ongoing project have allowed us to make useful interventions, from emphasizing the use of phototimers instead of institutional memory of manual techniques to improvements in our phototimer calibration. We believe that this QC program can be implemented at other sites and can reveal problems with radiation levels in the aggregate that are difficult to identify on a case‐by‐case basis.PACS number(s): 87.59.bf

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Digital Radiography Reject Analysis: Data Collection Methodology, Results, and Recommendations from an In-depth Investigation at Two Hospitals

Cited by 57 publications

References 2 publications

Investigation of the Variability in the Assessment of Digital Chest X-ray Image Quality

Investigation of the Variability in the Assessment of Digital Chest X-ray Image Quality

Sharpness and noise in digital chest radiographs, assessed by visual rating

Evaluation of digital radiography practice using exposure index tracking

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