Jeyaraman Naveen, Jeyaraman Madhan, Yadav Sankalp, Ramasubramanian Swaminathan, Balaji Sangeetha, Muthu Sathish, Lekha P Chithra, Patro Bishnu P
Orthopaedics, ACS Medical College and Hospital, Dr. MGR Educational and Research Institute, Chennai, IND.
Clinical Research, Virginia Tech India, Dr. MGR Educational and Research Institute, Chennai, IND.
Cureus. 2024 Jul 10;16(7):e64263. doi: 10.7759/cureus.64263. eCollection 2024 Jul.
Fog computing is a decentralized computing infrastructure that processes data at or near its source, reducing latency and bandwidth usage. This technology is gaining traction in healthcare due to its potential to enhance real-time data processing and decision-making capabilities in critical medical scenarios. A systematic review of existing literature on fog computing in healthcare was conducted. The review included searches in major databases such as PubMed, IEEE Xplore, Scopus, and Google Scholar. The search terms used were "fog computing in healthcare," "real-time diagnostics and fog computing," "continuous patient monitoring fog computing," "predictive analytics fog computing," "interoperability in fog computing healthcare," "scalability issues fog computing healthcare," and "security challenges fog computing healthcare." Articles published between 2010 and 2023 were considered. Inclusion criteria encompassed peer-reviewed articles, conference papers, and review articles focusing on the applications of fog computing in healthcare. Exclusion criteria were articles not available in English, those not related to healthcare applications, and those lacking empirical data. Data extraction focused on the applications of fog computing in real-time diagnostics, continuous monitoring, predictive analytics, and the identified challenges of interoperability, scalability, and security. Fog computing significantly enhances diagnostic capabilities by facilitating real-time data analysis, crucial for urgent diagnostics such as stroke detection, by processing data closer to its source. It also improves monitoring during surgeries by enabling real-time processing of vital signs and physiological parameters, thereby enhancing patient safety. In chronic disease management, continuous data collection and analysis through wearable devices allow for proactive disease management and timely adjustments to treatment plans. Additionally, fog computing supports telemedicine by enabling real-time communication between remote specialists and patients, thereby improving access to specialist care in underserved regions. Fog computing offers transformative potential in healthcare, improving diagnostic precision, patient monitoring, and personalized treatment. Addressing the challenges of interoperability, scalability, and security will be crucial for fully realizing the benefits of fog computing in healthcare, leading to a more connected and efficient healthcare environment.
雾计算是一种去中心化的计算基础设施,可在数据源处或其附近处理数据,从而减少延迟和带宽使用。由于该技术在关键医疗场景中具有增强实时数据处理和决策能力的潜力,因此在医疗保健领域越来越受到关注。我们对医疗保健领域中有关雾计算的现有文献进行了系统综述。该综述包括在主要数据库(如PubMed、IEEE Xplore、Scopus和谷歌学术)中进行检索。使用的检索词为“医疗保健中的雾计算”、“实时诊断与雾计算”、“连续患者监测雾计算”、“预测分析雾计算”、“医疗保健雾计算中的互操作性”、“医疗保健雾计算中的可扩展性问题”以及“医疗保健雾计算中的安全挑战”。考虑了2010年至2023年发表的文章。纳入标准包括同行评审文章、会议论文以及专注于雾计算在医疗保健中应用的综述文章。排除标准为非英文文章、与医疗保健应用无关的文章以及缺乏实证数据的文章。数据提取重点关注雾计算在实时诊断、连续监测、预测分析中的应用,以及所确定的互操作性、可扩展性和安全性挑战。雾计算通过促进实时数据分析显著增强诊断能力,这对于诸如中风检测等紧急诊断至关重要,因为它能在更接近数据源的位置处理数据。它还通过实现生命体征和生理参数的实时处理来改善手术期间的监测,从而提高患者安全性。在慢性病管理中,通过可穿戴设备进行连续数据收集和分析有助于进行主动疾病管理并及时调整治疗计划。此外,雾计算通过实现远程专家与患者之间的实时通信来支持远程医疗,从而改善在服务不足地区获得专科护理的机会。雾计算在医疗保健领域具有变革潜力,可提高诊断精度、患者监测和个性化治疗水平。应对互操作性、可扩展性和安全性挑战对于充分实现雾计算在医疗保健中的益处至关重要,从而打造一个更互联、高效的医疗保健环境。
