Physiology-Aware Rural Ambulance Routing

2017 IEEE International Conference on Healthcare Informatics (ICHI) Pub Date : 2017-06-30 DOI:10.1109/ICHI.2017.27

Mohammad Hosseini, Richard B. Berlin, L. Sha

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引用次数: 3

Abstract

The ultimate objective of medical cyber-physical systems is to enhance the effectiveness of patient care. During emergency patient transport from rural medical facility to center tertiary hospital, real-time monitoring of the patient in the ambulance by a physician expert at the tertiary center is crucial. The physician experts can provide vital assistance to the ambulance EMT personnel. While telemetry healthcare services using mobile networks may enable remote real-time monitoring of transported patients, physiologic measures and tracking are at least as important and requires the existence of high-fidelity communication coverage. However, the wireless networks along the roads especially in rural areas can range from 4G to low-speed 2G, some parts with communication breakage. From a patient care perspective, transport during critical illness can make route selection patient state dependent. Prompt decisions with the relative advantage of a longer more secure bandwidth route versus a shorter, more rapid transport route but with less secure bandwidth must be made. The trade-off between route selection and the quality of wireless communication is an important optimization problem which unfortunately has remained unaddressed by prior work.In this paper, we propose a novel physiology-aware route scheduling approach for emergency ambulance transport of rural patients with acute, high risk diseases in need of continuous remote monitoring. We mathematically model the problem into an NP-hard graph theory problem, and approximate a solution based on a trade-off between communication coverage and shortest path. We profile communication along two major routes in a large rural hospital settings in Illinois, and use the traces to manifest the concept. Further, we design our algorithms and run preliminary experiments for scalability analysis. We believe that our scheduling techniques can become a compelling aid that enables an always-connected remote monitoring system in emergency patient transfer scenarios aimed to prevent morbidity and mortality with early diagnosis and effective treatment.

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意识到生理的农村救护车路线

医疗信息物理系统的最终目标是提高患者护理的有效性。在将紧急病人从农村医疗机构运送到中心三级医院期间，三级中心的医师专家在救护车上对病人进行实时监测至关重要。内科专家可以为急救人员提供至关重要的帮助。虽然使用移动网络的遥测医疗保健服务可以实现对运送患者的远程实时监测，但生理测量和跟踪至少同样重要，并且需要高保真通信覆盖。然而，道路沿线的无线网络，特别是农村地区的无线网络，范围从4G到低速2G，有些部分通信中断。从病人护理的角度来看，危重疾病期间的运输可以使路线选择依赖于病人的状态。必须迅速作出决定，选择一条更长的更安全的带宽路线，还是选择一条更短、更快速的传输路线，但带宽不太安全。路由选择和无线通信质量之间的权衡是一个重要的优化问题，不幸的是，以前的工作没有解决这个问题。在本文中，我们提出了一种新的生理感知路线调度方法，用于需要持续远程监测的农村急性高危疾病患者的紧急救护车运输。我们在数学上将该问题建模为NP-hard图论问题，并基于通信覆盖和最短路径之间的权衡近似解决方案。我们分析了伊利诺斯州一家大型农村医院的两条主要通信路线，并使用这些痕迹来体现这一概念。此外，我们设计了我们的算法并运行了可扩展性分析的初步实验。我们相信，我们的调度技术可以成为一种令人信服的辅助手段，在紧急患者转移场景中实现始终连接的远程监控系统，旨在通过早期诊断和有效治疗预防发病率和死亡率。

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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2017 IEEE International Conference on Healthcare Informatics (ICHI)

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