Assessing Radiology Workflow Interruptions in the Era of Electronic Communications: A Human Factors Engineering Approach.

IF 3.8 2区医学 Q1 RADIOLOGY, NUCLEAR MEDICINE & MEDICAL IMAGING

Academic Radiology Pub Date : 2025-04-17 DOI:10.1016/j.acra.2025.03.050

Shanmugapriya Loganathar, Giuseppe V Toia, Meghan G Lubner, Matthew H Lee

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引用次数: 0

Abstract

Rationale and objectives: To identify the frequency and nature of messages, communication topics, and the contextual factors that lead to communication and potentially detrimental workflow interruptions via an electronic communication platform (ECP; WebEx) in a multi-subspecialty academic radiology practice.

Materials and methods: In this retrospective sequential mixed methods quality improvement study, we performed quantitative analysis of WebEx messages from July 2022 to July 2023. Message frequency was determined across three daily timeframes corresponding to radiology coverage shifts. Structural topic modeling (STM) was used to identify common communication topics in WebEx. Semi-structured interviews with technologists and residents were performed to determine the context behind these topics. The Systems Engineering Initiative for Patient Safety (SEIPS) framework was used to analyze contextual factors influencing communication.

Results: A total of 39,448 WebEx messages were analyzed. Timeframes with the highest frequency of messages were 7:30 AM-4:30 PM (4.2 messages/hr [SD 3.4]) and 4:30 PM-9:00 PM (4.2 messages/hr [SD 3.5]). Protocol-related questions were the most frequent topic (13%), followed by clarifications regarding allergy and contrast (7%), and exam appropriateness. 24 contextual factors influencing communication via WebEx were identified, including organizational factors (e.g., psychological safety, perceived workload), task characteristics (e.g., protocol complexity, time pressure), person characteristics (e.g., experience of technologists and residents), and physical environment (e.g., noise).

Conclusion: High electronic message volumes and unnecessary interruptions via low friction ECPs and ad hoc messaging negatively impact radiology workflows and could affect patient safety. Organizational communication protocols could reduce workflow disruption for radiologists and technologists. Optimizing ECP communication protocols by time of day and message type could also improve workflow efficiency, ultimately enhancing patient safety and productivity. Future implementation of targeted interventions using these data is warranted.

Summary: Human factors engineering strategies show that interruptions from high volume electronic communications that potentially have a negative impact on workflow, workload, and patient safety are contextual in nature. This study identifies targets for improved electronic communications in a busy academic radiology practice.

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评估电子通信时代放射工作流程中断：人因工程方法。

基本原理和目标：通过电子通信平台（ECP）确定导致通信和潜在有害工作流程中断的消息、通信主题和上下文因素的频率和性质。WebEx)在多亚专业学术放射学实践。材料和方法：在这项回顾性顺序混合方法质量改进研究中，我们对2022年7月至2023年7月的WebEx信息进行了定量分析。信息频率在三个每日时间框架内确定，对应于放射学覆盖的变化。采用结构主题模型（Structural topic modeling， STM）识别WebEx中常见的通信主题。对技术专家和居民进行了半结构化访谈，以确定这些主题背后的背景。患者安全系统工程倡议（SEIPS）框架被用来分析影响沟通的语境因素。结果：共分析了39,448条WebEx信息。信息频率最高的时间段是7:30 AM-4:30 PM（4.2条/小时[SD 3.4]）和4:30 PM-9:00 PM（4.2条/小时[SD 3.5]）。与方案相关的问题是最常见的话题（13%），其次是关于过敏和对比的澄清（7%），以及检查的适当性。通过WebEx确定了24个影响沟通的上下文因素，包括组织因素（例如，心理安全，感知工作量），任务特征（例如，协议复杂性，时间压力），人员特征（例如，技术人员和居民的经验）和物理环境（例如，噪音）。结论：通过低摩擦ECPs和临时信息传递产生的高电子信息量和不必要的中断对放射学工作流程产生负面影响，并可能影响患者安全。组织通信协议可以减少放射科医生和技术人员的工作流程中断。根据一天中的时间和消息类型优化ECP通信协议也可以提高工作流程效率，最终提高患者的安全性和生产力。未来有必要利用这些数据实施有针对性的干预措施。摘要：人为因素工程策略表明，高容量电子通信的中断可能对工作流程、工作量和患者安全产生负面影响，这在本质上是上下文相关的。本研究确定了在繁忙的学术放射学实践中改进电子通信的目标。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Academic Radiology 医学-核医学

CiteScore

7.60

自引率

10.40%

发文量

432

审稿时长

18 days

期刊介绍： Academic Radiology publishes original reports of clinical and laboratory investigations in diagnostic imaging, the diagnostic use of radioactive isotopes, computed tomography, positron emission tomography, magnetic resonance imaging, ultrasound, digital subtraction angiography, image-guided interventions and related techniques. It also includes brief technical reports describing original observations, techniques, and instrumental developments; state-of-the-art reports on clinical issues, new technology and other topics of current medical importance; meta-analyses; scientific studies and opinions on radiologic education; and letters to the Editor.