Chest X‐ray evaluation training: impact of normal and abnormal image ratio and instructional sequence

Geel, Koos van; Kok, Esther T.; Aldekhayel, Abdullah D; Robben, Simon G. F.; Merriënboer, Jeroen J. G. van

doi:10.1111/medu.13756

Cited by 12 publications

(9 citation statements)

References 27 publications

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“…In this paper, Table 2 was published with errors on the values under the columns ‘Main effect of proportion of normal images’, ‘Main effect of instructional sequence’, and ‘Interaction effect’. The subheading for ‘Practice‐first order (inductive)’ and ‘Instruction‐first order (deductive)’ have also been modified along with the Table caption.…”

Section: Practice Phase Descriptives and 2 × 2 Anova Results For Eachmentioning

confidence: 99%

Corrigendum

2019

Medical Education

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Section: Practice Phase Descriptives and 2 × 2 Anova Results For Eachmentioning

confidence: 99%

Corrigendum

2019

Medical Education

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“…Prior work in image interpretation has focused on the proportions of normal and abnormal radiographs and how this impacts diagnostic sensitivity and specificity trade‐offs. Specifically, higher proportions of abnormal cases optimize sensitivity but compromise specificity and vice versa 41‐43 . A high prevalence of abnormal cases can also overestimate the ability of observers to identify abnormalities and limits the opportunity to identify challenging radiographs without pathology 41 .…”

Section: Discussionmentioning

confidence: 99%

Image interpretation: Learning analytics–informed education opportunities

Thau

Pérez

Pusic

et al. 2021

AEM Education and Training

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Objectives: Using a sample of pediatric chest radiographs (pCXR) taken to rule out pneumonia, we obtained diagnostic interpretations from physicians and used learning analytics to determine the radiographic variables and participant review processes that predicted for an incorrect diagnostic interpretation.Methods: This was a prospective cross-sectional study. A convenience sample of frontline physicians with a range of experience levels interpreted 200 pCXR presented using a customized online radiograph presentation platform. Participants were asked to determine absence or presence (with respective location) of pneumonia. The pCXR were categorized for specific image-based variables potentially associated with interpretation difficulty. We also generated heat maps displaying the locations of diagnostic error among normal pCXR. Finally, we compared image review processes in participants with higher versus lower levels of clinical experience. Results:We enrolled 83 participants (20 medical students, 40 postgraduate trainees, and 23 faculty) and obtained 12,178 case interpretations. Variables that predicted for increased pCXR interpretation difficulty were pneumonia versus no pneumonia (β = 8.7, 95% confidence interval [CI] = 7.4 to 10.0), low versus higher visibility of pneumonia (β = -2.2, 95% CI = -2.7 to -1.7), nonspecific lung pathology (β = 0.9, 95% CI = 0.40 to 1.5), localized versus multifocal pneumonia (β = -0.5, 95% CI = -0.8 to -0.1), and one versus two views (β = 0.9, 95% CI = 0.01 to 1.9). A review of diagnostic errors identified that bony structures, vessels in the perihilar region, peribronchial thickening, and thymus were often mistaken for pneumonia. Participants with lower experience were less accurate when they reviewed one of two available views (p < 0.0001), and accuracy of those with higher experience increased with increased confidence in their response (p < 0.0001). Conclusions:Using learning analytics, we identified actionable learning opportunities for pCXR interpretation, which can be used to allow for a customized weighting of which cases to practice. Furthermore, experienced-novice comparisons revealed image review processes that were associated with greater diagnostic accuracy, providing additional insight into skill development of image interpretation.

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“…Students studying from case libraries containing at least 30% normal radiographs performed better at radiographic interpretation. 34 The ratio of normal to pathological images did not affect learners’ diagnostic accuracy but did affect learners’ sensitivity and specificity. 34,40 Students studying from the 30% normal chest radiograph library had higher sensitivity, while students studying from the 70% normal library had higher specificity.…”

Section: Clinical Learning Environmentmentioning

confidence: 93%

“…34,40 Students studying from the 30% normal chest radiograph library had higher sensitivity, while students studying from the 70% normal library had higher specificity. 34 Practically, this suggests that case libraries for novice learners, where sensitivity is more important, should contain less normal images than those for intermediate/advanced learners, where specificity is more important.…”

Section: Interpreting Imagesmentioning

confidence: 98%

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Undergraduate Radiology Education During the COVID-19 Pandemic: A Review of Teaching and Learning Strategies

et al. 2020

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The Coronavirus disease 2019 (COVID-19) pandemic has altered how medical education is delivered, worldwide. Didactic sessions have transitioned to electronic/online platforms and clinical teaching opportunities are limited. These changes will affect how radiology is taught to medical students at both the pre-clerkship (ie, year 1 and 2) and clinical (ie, year 3 and 4) levels. In the pre-clerkship learning environment, medical students are typically exposed to radiology through didactic lectures, integrated anatomy laboratories, case-based learning, and ultrasound clinical skills sessions. In the clinical learning environment, medical students primarily shadow radiologists and radiology residents and attend radiology resident teaching sessions. These formats of radiology education, which have been the tenets of the specialty, pose significant challenges during the pandemic. This article reviews how undergraduate radiology education is affected by COVID-19 and explores solutions for teaching and learning based on e-learning and blended learning theory.

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Chest X‐ray evaluation training: impact of normal and abnormal image ratio and instructional sequence

Cited by 12 publications

References 27 publications

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Image interpretation: Learning analytics–informed education opportunities

Undergraduate Radiology Education During the COVID-19 Pandemic: A Review of Teaching and Learning Strategies

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