An interactive patient transfer network and model visualization tool for multidrug-resistant organism prevention strategies

Rany Octaria, Samuel Cincotta, Jessica Healy, Camden Gowler, Prabasaj Paul, Maroya Walters, Rachel Slayton
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Abstract

Background: The CDC’s new Public Health Strategies to Prevent the Spread of Novel and Targeted Multidrug-Resistant Organisms (MDROs) were informed by mathematical models that assessed the impact of implementing preventive strategies directed at a subset of healthcare facilities characterized as influential or highly connected based on their predicted role in the regional spread of MDROs. We developed an interactive tool to communicate mathematical modeling results and visualize the regional patient transfer network for public health departments and healthcare facilities to assist in planning and implementing prevention strategies. Methods: An interactive RShiny application is currently hosted in the CDC network and is accessible to external partners through the Secure Access Management Services (SAMS). Patient transfer volumes (direct and indirect, that is, with up to 30 days in the community between admissions) were estimated from the CMS fee-for-service claims data from 2019. The spread of a carbapenem-resistant Enterobacterales (CRE)–like MDROs within a US state was simulated using a deterministic model with susceptible and infectious compartments in the community and healthcare facilities interconnected through patient transfers. Individuals determined to be infectious through admission screening, point-prevalence surveys (PPSs), or notified from interfacility communication were assigned lower transmissibility if enhanced infection prevention and control practices were in place at a facility. Results: The application consists of 4 interactive tabs. Users can visualize the statewide patient-sharing network for any US state and select territories in the first tab (Fig. 1). A feature allows users to highlight a facility of interest and display downstream or upstream facilities that received or sent transfers from the facility of interest, respectively. A second tab lists influential facilities to aid in prioritizing screening and prevention activities. A third tab lists all facilities in the state in descending order of their dispersal rate (ie, the rate at which patients are shared downstream to other facilities), which can help identify highly connected facilities. In the fourth tab, an interactive graph displays the predicted reduction of MDRO prevalence given a range of intervention scenarios (Fig. 2). Conclusions: Our RShiny application, which can be accessed by public health partners, can assist healthcare facilities and public health departments in planning and tailoring MDRO prevention activity bundles. Disclosures: None
多药耐药生物预防策略的交互式患者转移网络和模型可视化工具
背景:美国疾病控制与预防中心的新公共卫生战略,以防止新型和靶向多药耐药生物(MDROs)的传播,是通过数学模型来评估实施预防战略的影响,这些战略针对具有影响力或高度联系的医疗机构子集,基于它们在MDROs区域传播中的预测作用。我们开发了一个互动工具,用于交流数学建模结果,并将公共卫生部门和医疗机构的区域患者转移网络可视化,以协助规划和实施预防策略。方法:一个交互式RShiny应用程序目前托管在CDC网络中,外部合作伙伴可以通过安全访问管理服务(SAMS)访问它。从2019年的CMS服务收费索赔数据中估计了患者转诊量(直接和间接,即入院之间在社区停留最多30天)。使用确定性模型模拟了美国州内碳青霉烯类耐药肠杆菌(CRE)样mdro的传播,该模型在社区和医疗机构中通过患者转移相互连接的易感室和感染性室。如果在设施中加强感染预防和控制措施,则通过入院筛查、点流行调查(PPSs)或设施间通信通知确定具有传染性的个体被分配为较低的传播力。结果:该应用程序由4个交互式选项卡组成。用户可以可视化美国任何州的全州患者共享网络,并在第一个选项卡中选择地区(图1)。一个功能允许用户突出显示感兴趣的设施,并显示分别从感兴趣的设施接收或发送转移的下游或上游设施。第二个标签列出了有助于确定筛查和预防活动优先次序的有影响力的设施。第三个标签列出了该州所有的医疗机构,按照它们的分散率(即,病人共享到下游其他医疗机构的比率)降序排列,这有助于识别高度连接的医疗机构。在第四个选项卡中,一个交互式图表显示了在一系列干预方案下MDRO患病率的预测降低(图2)。结论:我们的RShiny应用程序可以由公共卫生合作伙伴访问,可以帮助医疗机构和公共卫生部门规划和定制MDRO预防活动包。披露:没有
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